diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATenGeneral.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATenGeneral.h new file mode 100644 index 0000000000000000000000000000000000000000..9b787a2163e87c903ce0bd034b424eb1773c644d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATenGeneral.h @@ -0,0 +1,3 @@ +#pragma once + +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATenOpList.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATenOpList.h new file mode 100644 index 0000000000000000000000000000000000000000..1419376a9017db4c7ca788816bd0c9a6d65a82fc --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATenOpList.h @@ -0,0 +1,13 @@ +#pragma once + +#include + +namespace c10 { +struct OperatorName; +} + +namespace at { + +// check if an op is a custom op (i.e. did not come from native_functions.yaml) +TORCH_API bool is_custom_op(const c10::OperatorName& opName); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATen_fwd.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATen_fwd.h new file mode 100644 index 0000000000000000000000000000000000000000..a66523ab183923e1c15862268b1b0260ccfb9e14 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATen_fwd.h @@ -0,0 +1,46 @@ +#pragma once +#include + +// Forward declarations of core ATen types used in dispatch functions +namespace c10 { + +template +class List; +template +class IListRef; +class Stream; +class Scalar; +class SymInt; +class SymIntList; +struct Storage; +struct TensorOptions; +template +class ArrayRef; +template +class OptionalArrayRef; + +} // namespace c10 + +namespace at { + +class Tensor; +class OptionalTensorRef; +struct Dimname; +struct Generator; +using TensorList = c10::ArrayRef; +using ITensorListRef = c10::IListRef; +using IOptTensorListRef = c10::IListRef; +using DimnameList = c10::ArrayRef; +using IntArrayRef = c10::ArrayRef; +using OptionalIntArrayRef = c10::OptionalArrayRef; +using OptionalSymIntArrayRef = c10::OptionalArrayRef; + +using c10::Stream; +using c10::Storage; +using c10::QScheme; +using c10::Scalar; +using c10::SymInt; +using c10::SymIntList; +using c10::TensorOptions; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATen_pch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATen_pch.h new file mode 100644 index 0000000000000000000000000000000000000000..f10c191a4c1fc60a720ce8b2174ea6fa4f8a18df --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ATen_pch.h @@ -0,0 +1,166 @@ +// This global header must not depend on native_functions.yaml or +// incremental builds will be next to useless +#pragma push_macro("TORCH_ASSERT_NO_OPERATORS") +#define TORCH_ASSERT_NO_OPERATORS + +// This macro doesn't work if defined after the first time inttypes.h +// is included, so won't work anywhere if not defined here. +#ifndef __STDC_FORMAT_MACROS +#define __STDC_FORMAT_MACROS +#endif +#include + +// This list of headers was generated using a script that finds +// high-impact headers and then manually tweaked to remove OS specific +// or duplicate headers (e.g. and ) and to remove +// "impl" headers (e.g BFloat16-inl.h or complex_math.h in c10). + +// To generate the initial list: +// 1. Build pytorch from scratch with all build caching disabled +// 2. Generate a build trace with ninjatracing (https://github.com/nico/ninjatracing) +// $ ninjatracing /path/to/pytorch/build/.ninja_log > trace_all.json +// 3. Run pch_gen.py from https://github.com/peterbell10/build_analysis/ +// $ python pch_gen.py --threshold .80 --target torch_cpu --build_dir /path/to/pytorch/build --trace trace_all.json +// Where the threshold can be tweaked until c10 and some of ATen +// core are included but TORCH_ASSERT_NO_OPERATORS still passes. + +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#pragma pop_macro("TORCH_ASSERT_NO_OPERATORS") diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Array.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Array.h new file mode 100644 index 0000000000000000000000000000000000000000..5f3f7bc9d48747c656ce3c9c60fccce86afafc6c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Array.h @@ -0,0 +1,48 @@ +#pragma once + +// A fixed-size array type usable from both host and +// device code. + +#include +#include + +namespace at::detail { + +template +struct Array { + // NOLINTNEXTLINE(*c-array*) + T data[size_]; + + C10_HOST_DEVICE T operator[](int i) const { + return data[i]; + } + C10_HOST_DEVICE T& operator[](int i) { + return data[i]; + } +#if defined(USE_ROCM) + C10_HOST_DEVICE Array() = default; + C10_HOST_DEVICE Array(const Array&) = default; + C10_HOST_DEVICE Array& operator=(const Array&) = default; + C10_HOST_DEVICE Array(Array&&) = default; + C10_HOST_DEVICE Array& operator=(Array&&) = default; + C10_HOST_DEVICE ~Array() = default; +#else + Array() = default; + Array(const Array&) = default; + Array& operator=(const Array&) = default; + Array(Array&&) noexcept = default; + Array& operator=(Array&&) noexcept = default; + ~Array() = default; +#endif + static constexpr int size() { + return size_; + } + // Fill the array with x. + C10_HOST_DEVICE Array(T x) { + for (int i = 0; i < size_; i++) { + data[i] = x; + } + } +}; + +} // namespace at::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Backtrace.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Backtrace.h new file mode 100644 index 0000000000000000000000000000000000000000..ac728968750297227c1be4aa3e444557c1899b03 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Backtrace.h @@ -0,0 +1,2 @@ +#include +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/CachingHostAllocator.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/CachingHostAllocator.h new file mode 100644 index 0000000000000000000000000000000000000000..76981dff46b895cd60eedb78058013a7cfeb13a4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/CachingHostAllocator.h @@ -0,0 +1,665 @@ +#include +#include +#include +#include +#include + +#include +#include + +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Wunused-parameter") +namespace at { + +using c10::CachingAllocator::Stat; +using c10::CachingAllocator::DurationStat; + +/** + * HostBlock is typically a fundamental memory block used in pinned memory. It + * is likely related to Event and Stream of device runtime. It is probably a + * base struct or interface that can be inherited and extended by each backend. + */ +template +struct HostBlock { + // constructor for search key + HostBlock(size_t size) : size_(size) {} + + HostBlock(size_t size, void* ptr) : size_(size), ptr_(ptr) {} + + std::mutex mutex_; + size_t size_{0}; // block size in bytes + void* ptr_{nullptr}; // memory address + bool allocated_{false}; // in-use flag + size_t event_count_{0}; // number of related events + ska::flat_hash_set streams_; // streams on which the block was used +}; + +template +struct alignas(64) FreeBlockList { + std::mutex mutex_; + std::deque list_; +}; + +namespace { + // Max cached block sizes: (1 << MAX_SIZE_INDEX) bytes + // NOLINTNEXTLINE(misc-definitions-in-headers) + constexpr size_t MAX_SIZE_INDEX = 64; +} + +// Struct containing memory allocator summary statistics for host. +struct HostStats { + // COUNT: allocations requested by client code. Note that active + // count can be extracted by looking at current allocations + Stat allocation; + // COUNT: number of allocated segments from host memory allocation. + Stat segment; + + // SUM: bytes allocated by this memory alocator. Note that active bytes + // can be extracted by looking at current bytes allocated + Stat allocated_bytes; + // SUM: bytes reserved by this memory allocator (both free and used) + Stat reserved_bytes; + + // SUM: time spent in cudaHostAlloc/cudaHostRegister in microseconds + DurationStat host_alloc_time; + + // SUM: time spent in cudaHostFree/cudaHostUnregister in microseconds + DurationStat host_free_time; + + // COUNT: number of times cudaHostAlloc/cudaHostRegister was called because + // the request could not be satisfied from existing free blocks. + int64_t num_host_alloc = 0; // This is derived from segment or timing + + // COUNT: number of times cudaHostFree/cudaHostUnregister was called. + int64_t num_host_free = 0; // This is derived from segment or timing +}; + +// Struct containing memory allocator summary statistics for host, as they +// are staged for reporting. This is a temporary struct that is used to +// avoid locking the allocator while collecting stats. +struct alignas(64) HostStatsStaged { + std::mutex timing_mutex_; + // COUNT: allocations requested by client code resulting in a new segment/block allocation + // LOCK: access to this stat is protected by the allocator's blocks_mutex_ + Stat allocation; + // SUM: bytes within active memory blocks, including blocks that are + // currently in the free list. + // LOCK: access to this stat is protected by the allocator's blocks_mutex_ + Stat allocated_bytes; + // COUNT: number of allocations per bucket + // LOCK: access to this stat is protected by the per bucket free_list_[index].mutex_ + std::vector allocation_bucket_stats = std::vector(MAX_SIZE_INDEX); + // SUM: bytes of allocation per bucket + // LOCK: access to this stat is protected by the per bucket free_list_[index].mutex_ + std::vector allocated_bytes_bucket_stats = std::vector(MAX_SIZE_INDEX); + // SUM: time spent in cudaHostAlloc/cudaHostRegister + // LOCK: access to this stat is protected by the timing_mutex_ + DurationStat host_alloc_time; + // SUM: time spent in cudaHostFree/cudaHostUnregister + // LOCK: access to this stat is protected by the timing_mutex_ + DurationStat host_free_time; +}; + +/** + * Note [HostAllocator design] + * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + * We have three key data structures - the free list which stores blocks that + * are not currently used, the block list which stores all blocks that have been + * allocated, and the event queue which stores runtime events and their + * corresponding blocks. + * + * Each of these are protected by a separate mutex. The key design principles + * are to 1) only hold each mutex for the minimal amount of time possible, 2) + * never do any possible expensive operations (such as CUDA runtime API calls) + * while holding the lock. + * + * There are four public methods: allocate, free, record_event and empty_cache. + * 1) In the allocate path, we first check to see if we can service our + * request from this free list, and otherwise we create a new block with + * allocate_host_memory. + * 2) In the free path, we insert events (if required) into the event queue, + * and if possible insert our block back into the free list. In allocate, we + * first eagerly query events until we find one that is not ready, and insert + * the corresponding block onto the free list if all the events recorded for a + * block are ready. + * 3) In the record_event path, we simply insert the given stream into the set + * of streams tracked by the specified block. This set of streams is then + * consumed in the free path. + * 4) In the empty_cache path, we flush any available blocks into the free + * list. Remove all element of free list, then remove them from block list and + * release the associated pinned memory allocation via free_block. + * + * We generalize the caching host allocator into two parts: interface and + * implementation. For any new backend looking to integrate with host allocator + * and reuse caching mechanism, these two parts are necessary to be specialized. + * + * For the implementation, we provide a CachingHostAllocatorImpl struct + * to abstract the caching mechanism. Any backend needs to provide a customized + * implementation by specializing its own public functions and the related + * runtime functions. Its template parameter S represents runtime Stream, E + * denotes runtime Event, B indicates the fundamental memory block. + * + * For the interface, we provide a CachingHostAllocatorInterface struct as an + * interface. Any backend needs to derive its own host allocator from this + * interface. Its template parameter T refers to an implementation that + * inherited from CachingHostAllocatorImpl. + * + * So this design can share the caching mechanism across each backend, and + * provide flexibility to each backend. A backend can choose to follow this + * implementation or reuse them by extending and overriding them as necessary. + * Taking CUDA as an example, it specializes runtime related functions to reuse + * the caching mechanism. Additionally, it extends the allocator's functionality + * by adding the allocWithCudaHostRegister function to support page-locking the + * memory range used by CUDA. Of course, you can also refer to + * XPUCachingHostAllocator, which is a host caching allocator supported on XPU + * backend, to implement a basic host caching allocator. + * + * Some of the invariants here are less strict than they could be - for example, + * we do not enforce that free(Block* block) => block->event_count == 0. This is + * for compatibility reasons, and we can explore enforcing these in subsequent + * versions. + * + * Note that this caching host allocator does not split larger allocations into + * smaller blocks, unlike the caching device allocator. + * + * In order to gather statistics about caching host allocator while minimally + * impacting performance, we use a HostStatsStaged struct to stage the stats + * before reporting them. This is done to avoid adding new locks to the allocator. + * Collecting stats is carefully done under existing locks, and then the staged + * stats are converted to the final stats when getStats is called. At that time + * we hold the same locks as empty_cache, to ensure the fidelity of the stats. + */ + +template < + typename S, + typename E, + typename B = HostBlock> +struct CachingHostAllocatorImpl { + virtual ~CachingHostAllocatorImpl() = default; + + public: + // return data_ptr and block pair. + virtual std::pair allocate(size_t size) { + if (size == 0) { + return {nullptr, nullptr}; + } + + // If we are using background threads, we can process events in the + // background. + if (!pinned_use_background_threads()) { + process_events(); + } + + // Round up the allocation to the nearest power of two to improve reuse. + // These power of two sizes are also used to index into the free list. + size_t roundSize = c10::llvm::PowerOf2Ceil(size); + + // First, try to allocate from the free list + auto* block = get_free_block(roundSize); + if (block) { + return {block->ptr_, reinterpret_cast(block)}; + } + + // Check in the recently freed blocks with pending events to see if we + // can reuse them. Call get_free_block again after processing events + if (pinned_use_background_threads()) { + process_events_for_specific_size(roundSize); + block = get_free_block(roundSize); + if (block) { + return {block->ptr_, reinterpret_cast(block)}; + } + + // Launch the background thread and process events in a loop. + static bool background_thread_flag [[maybe_unused]] = [this] { + getBackgroundThreadPool()->run([&]() { + while (true) { + process_events(); + std::this_thread::sleep_for(std::chrono::microseconds(100)); + } + }); + return true; + }(); + } + + // Slow path: if we can't allocate from the cached free list, we need + // to create a new block. + void* ptr = nullptr; + allocate_host_memory(roundSize, &ptr); + + // Then, create a new block. + block = new B(roundSize, ptr); + block->allocated_ = true; + + add_allocated_block(block); + return {block->ptr_, reinterpret_cast(block)}; + } + + virtual void free(void* ctx) { + if (!ctx) { + return; + } + + // Note: we can assume that free is correctly paired with alloc, and thus we + // do not need to look up the ctx in blocks_. + auto* block = reinterpret_cast(ctx); + + std::optional> events; + { + std::lock_guard g(block->mutex_); + block->allocated_ = false; + if (block->streams_.empty()) { + TORCH_INTERNAL_ASSERT(block->event_count_ == 0); + } else { + events = std::vector(); + events->reserve(block->streams_.size()); + for (auto stream : block->streams_) { + record_stream(events, stream); + } + block->event_count_ += events->size(); + block->streams_.clear(); + } + } + + if (!events) { + auto index = size_index(block->size_); + std::lock_guard g(free_list_[index].mutex_); + free_list_[index].list_.push_back(block); + stats_.allocation_bucket_stats[index].decrease(1); + stats_.allocated_bytes_bucket_stats[index].decrease(block->size_); + } else { + // restore these events that record by used streams. + std::lock_guard g(events_mutex_); + for (auto&& event : *events) { + events_.emplace_front(std::move(event), block); + } + } + } + + virtual bool record_event(void* ptr, void* ctx, S stream) { + auto* block = reinterpret_cast(ctx); + + // Note: we need to check if the passed-in `ctx` is valid. This is because + // `record_event` (via `CachingHostAllocator_recordEvent`) can be invoked on + // an arbitrary tensor, and is not guaranteed to correspond to a pinned + // memory allocation. Therefore, we need to check that `ctx` is valid before + // proceeding. + { + std::lock_guard g(blocks_mutex_); + if (blocks_.find(block) != blocks_.end()) { + // Now we know this object is safe to access. + std::lock_guard gb(block->mutex_); + TORCH_INTERNAL_ASSERT(block->allocated_); + block->streams_.insert(stream); + return true; + } + auto it = ptr_to_block_.find(ptr); + if (it != ptr_to_block_.end()) { + block = it->second; + std::lock_guard g(block->mutex_); + TORCH_INTERNAL_ASSERT(block->allocated_); + block->streams_.insert(stream); + return true; + } + } + + return false; + } + + virtual void empty_cache() { + // Flush any available blocks into the free_list. + process_events(); + + // Remove all elements from the free list, remove them from the blocks + // list, and free the associated pinned memory allocation. This requires + // concurrently holding both the free list mutexes and the blocks mutex, and + // is the only function that concurrently holds multiple mutexes. + for (size_t i = 0; i < free_list_.size(); ++i) { + std::lock(free_list_[i].mutex_, blocks_mutex_); + std::lock_guard gf(free_list_[i].mutex_, std::adopt_lock); + std::lock_guard gb(blocks_mutex_, std::adopt_lock); + + std::vector blocks_to_remove(free_list_[i].list_.begin(), free_list_[i].list_.end()); + free_list_[i].list_.clear(); + + for (auto* block : blocks_to_remove) { + blocks_.erase(block); + ptr_to_block_.erase(block->ptr_); + stats_.allocation.decrease(1); + stats_.allocated_bytes.decrease(block->size_); + free_block(block); + delete block; + } + } + } + + inline size_t size_index(size_t size) { + return c10::llvm::Log2_64_Ceil(size); + } + + virtual bool pinned_use_background_threads() { + return false; + } + + virtual void copy_data(void* dest [[maybe_unused]], const void* src [[maybe_unused]], std::size_t count [[maybe_unused]]) const { + TORCH_CHECK_NOT_IMPLEMENTED(false, "Not implemented for copy_data"); + } + + HostStats getStats() { + HostStats stats; + + // To keep getStats lightweight we do *not* flush any available blocks + // into the free_list. This may skew the stats a bit. + + auto add_bucket_stats = [](Stat& accumulator, const Stat& other) { + accumulator.allocated += other.allocated; + accumulator.current += other.current; + accumulator.freed += other.freed; + // Since peaks are measured per bucket independently, we add them up + // to estimate the total peak. This is not strictly correct, but it is + // the best approximation we can get after the fact. + accumulator.peak += other.peak; + }; + + // Accurate reading of memory stats requires concurrently holding both the + // free list mutexes and the blocks mutex. Previously, this was only done in + // empty_cache function. + for (size_t i = 0; i < free_list_.size(); ++i) { + std::lock(free_list_[i].mutex_, blocks_mutex_); + std::lock_guard gf(free_list_[i].mutex_, std::adopt_lock); + std::lock_guard gb(blocks_mutex_, std::adopt_lock); + + // We collect the slow-path stats only once, since they are not collected + // per bucket (we pick index 0 arbitrarily). These are also all the host + // allocations, not taking into account caching and free lists. + if (i == 0) { + stats.segment = stats_.allocation; + stats.reserved_bytes = stats_.allocated_bytes; + stats.num_host_alloc = stats.segment.allocated; + stats.num_host_free = stats.segment.freed; + } + + // Bucket stats need to be merged with the slow-path stats. We do this in + // a best effort manner, since we can't really replay the cached events per bucket. + add_bucket_stats(stats.allocation, stats_.allocation_bucket_stats[i]); + add_bucket_stats(stats.allocated_bytes, stats_.allocated_bytes_bucket_stats[i]); + } + + // Get the timing stats + { + std::lock_guard g(stats_.timing_mutex_); + + stats.host_alloc_time = stats_.host_alloc_time; + stats.host_free_time = stats_.host_free_time; + } + + return stats; + } + + void resetAccumulatedStats() { + // Reseting accumulated memory stats requires concurrently holding both the + // free list mutexes and the blocks mutex. Previously, this was only done in + // empty_cache function. + for (size_t i = 0; i < free_list_.size(); ++i) { + std::lock(free_list_[i].mutex_, blocks_mutex_); + std::lock_guard gf(free_list_[i].mutex_, std::adopt_lock); + std::lock_guard gb(blocks_mutex_, std::adopt_lock); + + if (i == 0) { + stats_.allocation.reset_accumulated(); + stats_.allocated_bytes.reset_accumulated(); + } + stats_.allocation_bucket_stats[i].reset_accumulated(); + stats_.allocated_bytes_bucket_stats[i].reset_accumulated(); + } + + // Also reset timing stats + { + std::lock_guard g(stats_.timing_mutex_); + stats_.host_alloc_time.reset_accumulated(); + stats_.host_free_time.reset_accumulated(); + } + } + + void resetPeakStats() { + // Reseting peak memory stats requires concurrently holding both the + // free list mutexes and the blocks mutex. Previously, this was only done in + // empty_cache function. + for (size_t i = 0; i < free_list_.size(); ++i) { + std::lock(free_list_[i].mutex_, blocks_mutex_); + std::lock_guard gf(free_list_[i].mutex_, std::adopt_lock); + std::lock_guard gb(blocks_mutex_, std::adopt_lock); + + if (i == 0) { + stats_.allocation.reset_peak(); + stats_.allocated_bytes.reset_peak(); + } + stats_.allocation_bucket_stats[i].reset_peak(); + stats_.allocated_bytes_bucket_stats[i].reset_peak(); + } + + // Also reset timing stats + { + std::lock_guard g(stats_.timing_mutex_); + stats_.host_alloc_time.reset_peak(); + stats_.host_free_time.reset_peak(); + } + } + + private: + virtual void add_allocated_block(B* block) { + std::lock_guard g(blocks_mutex_); + blocks_.insert(block); + stats_.allocation.increase(1); + stats_.allocated_bytes.increase(block->size_); + ptr_to_block_.insert({block->ptr_, block}); + + // Unfortunately, we have to, on the slow path, quickly + // lock the bucket to record the allocation. This should + // be a rare event once the cache is warmed up. + auto size = block->size_; + auto index = size_index(size); + { + std::lock_guard g(free_list_[index].mutex_); + stats_.allocation_bucket_stats[index].increase(1); + stats_.allocated_bytes_bucket_stats[index].increase(size); + } + } + + virtual B* get_free_block(size_t size) { + auto index = size_index(size); + std::lock_guard g(free_list_[index].mutex_); + if (free_list_[index].list_.size() > 0) { + B* block = free_list_[index].list_.back(); + free_list_[index].list_.pop_back(); + block->allocated_ = true; + stats_.allocation_bucket_stats[index].increase(1); + stats_.allocated_bytes_bucket_stats[index].increase(size); + return block; + } + return nullptr; + } + + virtual void process_events() { + // process all events until the last unready event, not for specific size. + process_events_for_specific_size(-1); + } + + // If size is -1, process all events from backwards until the last unready + // event. Otherwise, process events for a specific size and on first ready block + // is found, add it to the free list and return. + virtual void process_events_for_specific_size(int64_t size) { + size_t event_count = 0; + size_t max_events = 0; + { + std::lock_guard g(events_mutex_); + max_events = events_.size(); + } + + while (true) { + // Avoid calling cudaEventDestroy while holding a mutex, so move + // intermediate events out of the lock into this object. + // process the last event + std::optional> processed; + { + std::lock_guard g(events_mutex_); + if (!events_.empty()) { + processed = std::move(events_.back()); + events_.pop_back(); + } + } + + if (!processed) { + return; + } + + if (size != -1) { + if (event_count++ > max_events) { + { + std::lock_guard g(events_mutex_); + events_.push_front(std::move(*processed)); + } + return; + } + if (size != (int64_t)processed->second->size_) { + // if we are processing a specific size, and the size of the block + // doesn't match, we can't use it. + { + std::lock_guard g(events_mutex_); + events_.push_front(std::move(*processed)); + } + continue; + } + } + + // otherwise, query the event + { + // now, see if we can handle this element + auto& event = processed->first; + if (!query_event(event)) { + // push the event onto the back if it's not ready. + { + std::lock_guard g(events_mutex_); + if (size == -1) { + events_.push_back(std::move(*processed)); + return; + } else { + events_.push_front(std::move(*processed)); + continue; + } + } + } + } + + // Process the events. + TORCH_INTERNAL_ASSERT(processed); + auto* block = processed->second; + bool available = false; + { + std::lock_guard g(block->mutex_); + TORCH_INTERNAL_ASSERT(!block->allocated_) + block->event_count_--; + if (block->event_count_ == 0) { + available = true; + } + } + + if (available) { + auto index = size_index(block->size_); + std::lock_guard g(free_list_[index].mutex_); + free_list_[index].list_.push_back(block); + stats_.allocation_bucket_stats[index].decrease(1); + stats_.allocated_bytes_bucket_stats[index].decrease(size); + if (size != -1) { + return; + } + } + } + } + + TaskThreadPool* getBackgroundThreadPool() { + static TaskThreadPool* pool = new TaskThreadPool(1); + return pool; + } + + /* These following functions are runtime-related. */ + + // Allocate page-locked memory on the host. + virtual void allocate_host_memory(size_t size, void** ptr) { + TORCH_CHECK_NOT_IMPLEMENTED( + false, "Not implemented for allocate_host_memory"); + } + + // Free block and release the pointer contained in block. + virtual void free_block(B* block) { + TORCH_CHECK_NOT_IMPLEMENTED(false, "Not implemented for free_block"); + } + + // Record an event on stream and store event into events. + virtual void record_stream(std::optional>& events, S stream) { + TORCH_CHECK_NOT_IMPLEMENTED(false, "Not implemented for record_stream"); + } + + // Query event if it is completed. + virtual bool query_event(E& event) { + TORCH_CHECK_NOT_IMPLEMENTED(false, "Not implemented for query_event"); + } + + alignas(64) std::mutex blocks_mutex_; + ska::flat_hash_set blocks_; // block list + ska::flat_hash_map ptr_to_block_; + + // We keep free list as a vector of free lists, one for each power of two + // size. This allows us to quickly find a free block of the right size. + // We use deque to store per size free list and guard the list with its own + // mutex. + alignas(64) std::vector> free_list_ = + std::vector>(MAX_SIZE_INDEX); + + alignas(64) std::mutex events_mutex_; + std::deque> events_; // event queue paired with block +protected: + alignas(64) HostStatsStaged stats_; +}; + +template +struct CachingHostAllocatorInterface : public at::Allocator { + CachingHostAllocatorInterface() : impl_(std::make_unique()) {} + + at::DataPtr allocate(size_t size) override { + TORCH_CHECK_NOT_IMPLEMENTED(false, "Not implemented for allocate"); + } + + void free(void* ctx) { + impl_->free(ctx); + } + + template + bool record_event(void* ptr, void* ctx, S stream) { + return impl_->record_event(ptr, ctx, stream); + } + + void empty_cache() { + impl_->empty_cache(); + } + + void copy_data(void* dest, const void* src, std::size_t count) + const override { + impl_->copy_data(dest, src, count); + } + + HostStats getStats() { + return impl_->getStats(); + } + + void resetAccumulatedStats() { + impl_->resetAccumulatedStats(); + } + + void resetPeakStats() { + impl_->resetPeakStats(); + } + + std::unique_ptr impl_; +}; + +} // namespace at +C10_DIAGNOSTIC_POP() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/CheckMemoryFormat.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/CheckMemoryFormat.h new file mode 100644 index 0000000000000000000000000000000000000000..860eec8e7a1f9399467e8db0ee9356468cd0f5b3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/CheckMemoryFormat.h @@ -0,0 +1,24 @@ +#include + +namespace c10::impl { + +inline std::optional +check_tensor_options_and_extract_memory_format( + const TensorOptions& options, + std::optional memory_format) { + TORCH_CHECK( + options.requires_grad_opt() != true, + "Operators taking TensorOptions cannot take a TensorOptions with " + "options.requires_grad set as true. This isn't implemented yet."); + TORCH_CHECK( + !(options.has_memory_format() && memory_format.has_value()), + "Cannot set memory_format both in TensorOptions and explicit argument; please delete " + "the redundant setter."); + if (memory_format.has_value()) { + return memory_format; + } else { + return options.memory_format_opt(); + } +} + +} // namespace impl namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DeprecatedTypeProperties.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DeprecatedTypeProperties.h new file mode 100644 index 0000000000000000000000000000000000000000..a945761e8ff97223d47456f1514bb18a3f4ac8bc --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DeprecatedTypeProperties.h @@ -0,0 +1,139 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include + + +namespace at { + +class Tensor; + +// This class specifies a Backend and a ScalarType. Currently, it primarily +// serves as a replacement return value for Tensor::type(). Previously, +// Tensor::type() returned Type&, but we are changing Type to not be +// dtype-specific. +class TORCH_API DeprecatedTypeProperties { + public: + DeprecatedTypeProperties(Backend backend, ScalarType scalar_type) + : backend_(backend), scalar_type_(scalar_type) {} + + Backend backend() const { + return backend_; + } + + Layout layout() const { + return layout_from_backend(backend_); + } + + bool is_sparse() const { + return layout_from_backend(backend()) == kSparse; + } + + bool is_sparse_csr() const { + return layout_from_backend(backend()) == kSparseCsr; + } + + c10::DeviceType device_type() const { + return backendToDeviceType(backend_); + } + + bool is_cuda() const { + return backendToDeviceType(backend_) == kCUDA; + } + + ScalarType scalarType() const { + return scalar_type_; + } + + caffe2::TypeMeta typeMeta() const { + return scalarTypeToTypeMeta(scalar_type_); + } + + bool operator==(const DeprecatedTypeProperties& other) const { + return backend_ == other.backend() && scalar_type_ == other.scalarType(); + } + + bool operator!=(const DeprecatedTypeProperties& other) const { + return !(*this == other); + } + + std::string toString() const { + std::string base_str; + if (backend_ == Backend::Undefined || scalar_type_ == ScalarType::Undefined) { + base_str = "UndefinedType"; + } else { + base_str = std::string(at::toString(backend_)) + at::toString(scalar_type_) + "Type"; + } + return base_str; + } + + DeprecatedTypeProperties & toBackend(Backend b) const { + return globalDeprecatedTypePropertiesRegistry().getDeprecatedTypeProperties( + b, scalar_type_); + } + + DeprecatedTypeProperties & toScalarType(ScalarType s) const { + return globalDeprecatedTypePropertiesRegistry().getDeprecatedTypeProperties( + backend_, s); + } + + DeprecatedTypeProperties & cpu() const { + return toBackend(Backend::CPU); + } + + DeprecatedTypeProperties & cuda() const { + return toBackend(Backend::CUDA); + } + + DeprecatedTypeProperties & hip() const { + return toBackend(Backend::HIP); + } + + DeprecatedTypeProperties & privateUser1() const { + return toBackend(Backend::PrivateUse1); + } + + /// Constructs the `TensorOptions` from a type and a `device_index`. + TensorOptions options(int16_t device_index = -1) const { + return TensorOptions().dtype(typeMeta()) + .device(device_type(), static_cast(device_index)) + .layout(layout()); + } + + /// Constructs the `TensorOptions` from a type and a Device. Asserts that + /// the device type matches the device type of the type. + TensorOptions options(std::optional device_opt) const { + if (!device_opt.has_value()) { + return options(-1); + } else { + Device device = device_opt.value(); + AT_ASSERT(device.type() == device_type()); + return options(device.index()); + } + } + + operator TensorOptions() const { + return options(); + } + + int64_t id() const { + return static_cast(backend()) * + static_cast(ScalarType::NumOptions) + + static_cast(scalarType()); + } + + Tensor unsafeTensorFromTH(void * th_pointer, bool retain) const; + Storage unsafeStorageFromTH(void * th_pointer, bool retain) const; + Tensor copy(const Tensor & src, bool non_blocking=false, std::optional to_device={}) const; + + private: + Backend backend_; + ScalarType scalar_type_; +}; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DeprecatedTypePropertiesRegistry.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DeprecatedTypePropertiesRegistry.h new file mode 100644 index 0000000000000000000000000000000000000000..78f0cfdfa553050d4437e2873f2ff906627a54c4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DeprecatedTypePropertiesRegistry.h @@ -0,0 +1,33 @@ +#pragma once + +// In order to preserve bc, we make DeprecatedTypeProperties instances unique +// just like they are for Type. + +#include +#include +#include + +namespace at { + +class DeprecatedTypeProperties; + +struct TORCH_API DeprecatedTypePropertiesDeleter { + void operator()(DeprecatedTypeProperties * ptr); +}; + +class TORCH_API DeprecatedTypePropertiesRegistry { + public: + DeprecatedTypePropertiesRegistry(); + + DeprecatedTypeProperties& getDeprecatedTypeProperties(Backend p, ScalarType s) const; + +private: + // NOLINTNEXTLINE(*c-array*) + std::unique_ptr registry + [static_cast(Backend::NumOptions)] + [static_cast(ScalarType::NumOptions)]; +}; + +TORCH_API DeprecatedTypePropertiesRegistry& globalDeprecatedTypePropertiesRegistry(); + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Dict.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Dict.h new file mode 100644 index 0000000000000000000000000000000000000000..d187d7b7c116998d094f54bece3df9601a8fd16f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Dict.h @@ -0,0 +1,399 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace c10 { +struct IValue; +template class Dict; +struct Type; + +namespace impl { + +using valid_dict_key_types = guts::typelist::typelist< + int64_t, + std::string, + double, + c10::complex, + bool, + at::Tensor +>; +} + +namespace detail { + +struct DictKeyHash { + size_t operator()(const IValue& ivalue) const; +}; + +struct DictKeyEqualTo { + bool operator()(const IValue& lhs, const IValue& rhs) const; +}; + +struct DictImpl final : public c10::intrusive_ptr_target { + using dict_map_type = ska_ordered::order_preserving_flat_hash_map; + struct DictElementTypes final { + TypePtr keyType; + TypePtr valueType; + }; + + explicit DictImpl(dict_map_type dict_, DictElementTypes elementTypes_) + : dict(std::move(dict_)) + , elementTypes(std::move(elementTypes_)) {} + dict_map_type dict; + + DictElementTypes elementTypes; + + intrusive_ptr copy() const; + friend TORCH_API bool operator==(const DictImpl& lhs, const DictImpl& rhs); +}; + +} + +namespace impl { +template class DictIterator; + +/** + * A reference to an entry in the Dict. + * Use the `key()` and `value()` methods to read the element. + */ +template +class DictEntryRef final { +public: + explicit DictEntryRef(Iterator iterator) + : iterator_(std::move(iterator)) {} + + decltype(auto) key() const { + return iterator_->first.template to(); + } + + decltype(auto) value() const { + return iterator_->second.template to(); + } + + template + void setValue(Value_&& value) const { + static_assert(std::is_constructible_v, "Wrong type for the value argument of setValue()"); + iterator_->second = Value(std::forward(value)); + } + ~DictEntryRef() = default; + +private: + // allow copying and moving, but only our friends (i.e. the Dict class) can do + // it. Copying/moving this reference wrapper would be too ambiguous to allow it + // in the public API. + DictEntryRef(const DictEntryRef&) = default; + DictEntryRef& operator=(const DictEntryRef&) = default; + DictEntryRef(DictEntryRef&&) noexcept = default; + DictEntryRef& operator=(DictEntryRef&& rhs) & noexcept = default; + + Iterator iterator_; + friend class DictIterator; + friend class Dict; +}; + +// this wraps map_type::iterator to make sure user code can't rely +// on it being the type of the underlying map. +template +class DictIterator final { +public: + // C++17 friendly std::iterator implementation + using iterator_category = std::forward_iterator_tag; + using value_type = DictEntryRef; + using difference_type = std::ptrdiff_t; + using pointer = value_type*; + using reference = value_type&; + + explicit DictIterator() = default; + ~DictIterator() = default; + + DictIterator(const DictIterator& rhs): entryRef_(rhs.entryRef_) {} + DictIterator(DictIterator&& rhs) noexcept: entryRef_(std::move(rhs.entryRef_)) {} + DictIterator& operator=(const DictIterator& rhs) { + entryRef_ = rhs.entryRef_; + return *this; + } + DictIterator& operator=(DictIterator&& rhs) noexcept { + entryRef_ = std::move(rhs.entryRef_); + return *this; + } + + DictIterator& operator++() { + ++entryRef_.iterator_; + return *this; + } + + DictIterator operator++(int) { + DictIterator copy(*this); + ++*this; + return copy; + } + + const DictEntryRef& operator*() const { + return entryRef_; + } + + const DictEntryRef* operator->() const { + return &entryRef_; + } + + friend difference_type operator-(const DictIterator& lhs, const DictIterator& rhs) { + return lhs.entryRef_.iterator_ - rhs.entryRef_.iterator_; + } + +private: + explicit DictIterator(Iterator iterator): entryRef_(std::move(iterator)) {} + + const Iterator& get_iterator_() const { + return entryRef_.iterator_; + } + + friend bool operator==(const DictIterator& lhs, const DictIterator& rhs) { + return lhs.get_iterator_() == rhs.get_iterator_(); + } + + friend bool operator!=(const DictIterator& lhs, const DictIterator& rhs) { + return lhs.get_iterator_() != rhs.get_iterator_(); + } + + friend bool operator<(const DictIterator& lhs, const DictIterator& rhs) { + return lhs.get_iterator_() < rhs.get_iterator_(); + } + + friend bool operator<=(const DictIterator& lhs, const DictIterator& rhs) { + return lhs.get_iterator_() <= rhs.get_iterator_(); + } + + friend bool operator>(const DictIterator& lhs, const DictIterator& rhs) { + return lhs.get_iterator_() > rhs.get_iterator_(); + } + + friend bool operator>=(const DictIterator& lhs, const DictIterator& rhs) { + return lhs.get_iterator_() >= rhs.get_iterator_(); + } + + DictEntryRef entryRef_; + + friend class DictIterator; + friend class Dict; +}; + +template Dict toTypedDict(Dict dict); +template Dict toGenericDict(Dict dict); +} + +/** + * An object of this class stores a map from Key to Value. + * + * This is a pointer type. After a copy, both Dicts + * will share the same storage: + * + * > Dict a; + * > Dict b = a; + * > b.insert(3, "three"); + * > ASSERT("three" == a.at(3)); + * + * We use this class in the PyTorch kernel API because that + * allows us to do optimizations and switch out the underlying + * map implementation without breaking backwards compatibility + * for the kernel API. + */ +template +// NOLINTNEXTLINE(cppcoreguidelines-special-member-functions) +class Dict final { +private: + static_assert((std::is_same_v && std::is_same_v) || guts::typelist::contains::value, "Invalid Key type for Dict. We only support int64_t, double, bool, and string."); + + // impl_ stores the underlying map as a ska_ordered::order_preserving_flat_hash_map. + // We intentionally don't offer conversion from/to + // order_preserving_flat_hash_map, return references to it or something like that, + // because such operations would get expensive if we switch out + // the actual map implementation. + // This is an intrusive_ptr because Dict is a pointer type. + // Invariant: This will never be a nullptr, there will always be a valid + // DictImpl. + c10::intrusive_ptr impl_; + + explicit Dict(c10::intrusive_ptr&& impl); + friend struct IValue; + template friend Dict impl::toTypedDict(Dict); + template friend Dict impl::toGenericDict(Dict); + +public: + using key_type = Key; + using mapped_type = Value; + using size_type = typename detail::DictImpl::dict_map_type::size_type; + using iterator = impl::DictIterator; + + /** + * Creates an empty dict. + */ + explicit Dict(); + + /** + * Create a generic dict with runtime type information. + * This only works for c10::impl::GenericDict and is not part of the public API + * but only supposed to be used internally by PyTorch. + */ + explicit Dict(TypePtr keyType, TypePtr valueType); + + ~Dict() = default; + + Dict(const Dict&) = default; + Dict& operator=(const Dict&) = default; + + /** + * Create a new Dict pointing to a deep copy of the same data. + * The Dict returned is a new dict with separate storage. + * Changes in it are not reflected in the original dict or vice versa. + */ + Dict copy() const; + + /** + * Returns an iterator to the first element of the container. + * If the container is empty, the returned iterator will be equal to end(). + */ + iterator begin() const; + + /** + * Returns an iterator to the element following the last element of the container. + * This element acts as a placeholder; attempting to access it results in undefined behavior. + */ + iterator end() const; + + /** + * Checks if the container has no elements. + */ + bool empty() const; + + /** + * Returns the number of elements in the container. + */ + size_type size() const; + + /** + * Erases all elements from the container. After this call, size() returns zero. + * Invalidates any references, pointers, or iterators referring to contained elements. May also invalidate past-the-end iterators. + */ + void clear() const; + + /** + * Inserts element(s) into the container, if the container doesn't already contain an element with an equivalent key. + * May invalidate any references, pointers, or iterators referring to contained elements. + * + * @return A pair consisting of an iterator to the inserted element (or to the element that prevented the insertion) and a bool denoting whether the insertion took place. + */ + template + std::pair insert(Key_&& key, Value_&& value) const; + + /** + * If an element with the given key already exists, it is overwritten with the given value. + * Otherwise, a new element with the given key and value are inserted. + * May invalidate any references, pointers, or iterators referring to contained elements. + * + * @return The bool component is true if the insertion took place and false if the assignment took place. The iterator component is pointing at the element that was inserted or updated. + */ + template + std::pair insert_or_assign(Key_&& key, Value_&& value) const; + + /** + * Removes the element pointed to by iter. + * May invalidate any references, pointers, or iterators referring to contained elements. + * The iterator iter must be valid and dereferenceable. Thus the end() iterator (which is valid, but is not dereferenceable) cannot be used as a value for iter. + */ + void erase(iterator iter) const; + + /** + * Removes the element with the given key, if it exists. + * May invalidate any references, pointers, or iterators referring to contained elements. + * + * @return The number of elements removed. This is either '1' if an element with the key existed, or '0' if it didn't. + */ + [[nodiscard]] size_t erase(const Key& key) const; + + /** + * Returns the mapped value of the element with key equivalent to key. + * If no such element exists, an exception of type std::out_of_range is thrown. + */ + Value at(const Key& key) const; + + /** + * Finds an element with key equivalent to key. + * + * @return Iterator to an element with key equivalent to key. + * If no such element is found, past-the-end (see end()) iterator is returned. + */ + iterator find(const Key& key) const; + + /** + * Checks if there is an element with key equivalent to key in the container. + * + * @return true if there is such an element, otherwise false. + */ + bool contains(const Key& key) const; + + /** + * Increase the capacity so that at least count elements can be stored without + * having to reallocate or rehash. + */ + void reserve(size_type count) const; + + /** + * Value equality comparison. This function implements Python-like semantics for + * equality: two dicts with the same identity (e.g. same pointer) trivially + * compare equal, otherwise each element is compared for equality. + */ + template + friend bool operator==( + const Dict& lhs, + const Dict& rhs); + template + friend bool operator!=( + const Dict& lhs, + const Dict& rhs); + + /** + * Identity comparison. Returns true if and only if `rhs` represents the same + * Dict object as `this`. + */ + bool is(const Dict& rhs) const; + + // private API for now because the return type will change to TypePtr + // instead of std::optional once types are mandatory. + TypePtr keyType() const; + TypePtr valueType() const; + + // [unsafe set type] + // These functions mutate the tagged type of this dictionary in place. + // There is no checking that the members of the dictionary are instances + // of the new types, nor is there a check that other IValues which + // hold references to this dictionary have the right static type. + // This functionality is used only in the unpickler, where at + // creation type the real type of the dictionary is unknown, but + // then later recovered from the static type information of the + // unpickled object. + void unsafeSetKeyType(TypePtr t); + void unsafeSetValueType(TypePtr t); +}; + +namespace impl { +// GenericDict is how IValue stores dicts. It is, however, not part of the +// public API. Kernels should use Dicts with concrete Key, Value types instead +// (maybe except for some internal prim ops). +using GenericDict = Dict; + +} +} + +namespace torch { + template using Dict = c10::Dict; +} + +#include // IWYU pragma: keep diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Dict_inl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Dict_inl.h new file mode 100644 index 0000000000000000000000000000000000000000..6261af5fb66a3e29c0faa897a029e8678f8356ca --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Dict_inl.h @@ -0,0 +1,209 @@ +#pragma once + +#include +#include + +namespace c10 { +namespace detail { +inline bool DictKeyEqualTo::operator()(const IValue& lhs, const IValue& rhs) const { + if (lhs.isTensor() && rhs.isTensor()) { + // for tensors, we compare only by identity (following how it's done in Python). + return lhs.is(rhs); + } + // Otherwise, we first compare by identity for efficiency, then by value (see: + // [container equality]) + return _fastEqualsForContainer(lhs, rhs); +} +} + +template decltype(auto) getTypePtr(); +std::string toString(const Type& type); + +namespace impl { + +template +Dict toTypedDict(GenericDict dict) { + TORCH_INTERNAL_ASSERT(*getTypePtr() == *dict.impl_->elementTypes.keyType, "Tried to cast a Dict<", toString(*dict.impl_->elementTypes.keyType), ", ", toString(*dict.impl_->elementTypes.valueType) ,"> to a Dict<", toString(*getTypePtr()), ", ", toString(*getTypePtr()), ">. Key types mismatch."); + TORCH_INTERNAL_ASSERT(*getTypePtr() == *dict.impl_->elementTypes.valueType, "Tried to cast a Dict<", toString(*dict.impl_->elementTypes.keyType), ", ", toString(*dict.impl_->elementTypes.valueType) ,"> to a Dict<", toString(*getTypePtr()), ", ", toString(*getTypePtr()), ">. Value types mismatch."); + + return Dict(std::move(dict.impl_)); +} + +template +GenericDict toGenericDict(Dict dict) { + return GenericDict(std::move(dict.impl_)); +} +} + +namespace detail { + +inline size_t DictKeyHash::operator()(const IValue& ivalue) const { + if (ivalue.isInt()) { + return std::hash()(ivalue.toInt()); + } else if (ivalue.isString()) { + return std::hash()(ivalue.toStringView()); + } else if (ivalue.isDouble()) { + return std::hash()(ivalue.toDouble()); + } else if (ivalue.isComplexDouble()) { + return c10::hash>()(ivalue.toComplexDouble()); + } else if (ivalue.isBool()) { + return std::hash()(ivalue.toBool()); + } else if (ivalue.isTensor()) { + return std::hash()(ivalue.toTensor().unsafeGetTensorImpl()); + } else if (ivalue.isDevice()) { + return std::hash()(ivalue.toDevice()); + } else { + throw std::runtime_error( + "Can't hash IValues with tag '" + ivalue.tagKind() + "'"); + } +} + +inline intrusive_ptr DictImpl::copy() const { + return make_intrusive(dict, elementTypes); +} + +} + +template +Dict::Dict() + :Dict(make_intrusive( + detail::DictImpl::dict_map_type(), + detail::DictImpl::DictElementTypes{getTypePtr(), getTypePtr()})) { + static_assert(!std::is_same_v, "This constructor is not valid for Dict. Please use c10::impl::GenericDict(keyType, valueType) instead."); + static_assert(!std::is_same_v, "This constructor is not valid for Dict<_, IValue>. Please use c10::impl::GenericDict(keyType, valueType) instead."); +} + +template +Dict::Dict(TypePtr keyType, TypePtr valueType) +: Dict(make_intrusive( + detail::DictImpl::dict_map_type(), + detail::DictImpl::DictElementTypes {std::move(keyType), std::move(valueType)})) { + static_assert(std::is_same_v, "This constructor is only valid for c10::impl::GenericDict."); + static_assert(std::is_same_v, "This constructor is only valid for c10::impl::GenericDict."); +} + +template +Dict::Dict(c10::intrusive_ptr&& impl): impl_(std::move(impl)) {} + +template +Dict Dict::copy() const { + return Dict(impl_->copy()); +} + +template +typename Dict::iterator Dict::begin() const { + return iterator{impl_->dict.begin()}; +} + +template +typename Dict::iterator Dict::end() const { + return iterator{impl_->dict.end()}; +} + +template +bool Dict::empty() const { + return impl_->dict.empty(); +} + +template +typename Dict::size_type Dict::size() const { + return impl_->dict.size(); +} + +template +void Dict::clear() const { + impl_->dict.clear(); +} + +template +template +std::pair::iterator, bool> Dict::insert(Key_&& key, Value_&& value) const { + static_assert(std::is_constructible_v, "Wrong type for the key argument of Dict::insert"); + static_assert(std::is_constructible_v, "Wrong type for the value argument of Dict::insert"); + auto inserted = impl_->dict.emplace( + Key(std::forward(key)), + Value(std::forward(value))); + return {iterator{inserted.first}, inserted.second}; +} + +template +template +std::pair::iterator, bool> Dict::insert_or_assign(Key_&& key, Value_&& value) const { + static_assert(std::is_constructible_v, "Wrong type for the key argument of Dict::insert_or_assign"); + static_assert(std::is_constructible_v, "Wrong type for the value argument of Dict::insert_or_assign"); + auto inserted = impl_->dict.insert_or_assign( + Key(std::forward(key)), + Value(std::forward(value))); + return {iterator{inserted.first}, inserted.second}; +} + +template +void Dict::erase(iterator iter) const { + impl_->dict.erase(iter.entryRef_.iterator_); +} + +template +[[nodiscard]] size_t Dict::erase(const Key& key) const { + return impl_->dict.erase(key); +} + +template +Value Dict::at(const Key& key) const { + return impl_->dict.at(key).template to(); +} + +template +typename Dict::iterator Dict::find(const Key& key) const { + return iterator{impl_->dict.find(key)}; +} + +template +bool Dict::contains(const Key& key) const { + return end() != find(key); +} + +template +void Dict::reserve(size_type count) const { + impl_->dict.reserve(count); +} + +template +TypePtr Dict::keyType() const { + return impl_->elementTypes.keyType; +} + +template +TypePtr Dict::valueType() const { + return impl_->elementTypes.valueType; +} +template +void Dict::unsafeSetKeyType(TypePtr t) { + impl_->elementTypes.keyType = std::move(t); +} + +template +void Dict::unsafeSetValueType(TypePtr t) { + impl_->elementTypes.valueType = std::move(t); +} + +template +bool operator==(const Dict& lhs, const Dict& rhs) { + // Dicts with the same identity trivially compare equal. + if (lhs.impl_ == rhs.impl_) { + return true; + } + + // Otherwise compare the values + return *lhs.impl_ == *rhs.impl_; +} + +template +bool operator!=(const Dict& lhs, const Dict& rhs) { + return !(lhs == rhs); +} + +template +bool Dict::is(const Dict& rhs) const { + return this->impl_ == rhs.impl_; +} +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DimVector.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DimVector.h new file mode 100644 index 0000000000000000000000000000000000000000..576b9e142ebf17d048262763c888845a7d0386e8 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DimVector.h @@ -0,0 +1,13 @@ +#pragma once +#include + +namespace at { + +// Re-declaring 'DimVector' type and size inside 'at' namespace. +// This is done to avoid modifying every use into their 'c10' +// equivalent. + +using c10::kDimVectorStaticSize; +using c10::DimVector; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Dimname.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Dimname.h new file mode 100644 index 0000000000000000000000000000000000000000..e5bb3c13922866931a59bd49b7f96cdbac81fc5d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Dimname.h @@ -0,0 +1,48 @@ +#pragma once + +#include +#include +#include +#include + +namespace at { + +enum class NameType: uint8_t { BASIC, WILDCARD }; + +struct TORCH_API Dimname { + static Dimname fromSymbol(Symbol name); + static Dimname wildcard(); + static bool isValidName(const std::string& name); + + NameType type() const { return type_; } + Symbol symbol() const { return name_; } + + bool isBasic() const { return type_ == NameType::BASIC; } + bool isWildcard() const { return type_ == NameType::WILDCARD; } + + bool matches(Dimname other) const; + std::optional unify(Dimname other) const; + + private: + Dimname(Symbol name) + : name_(name), type_(NameType::BASIC) {} + Dimname(Symbol name, NameType type) + : name_(name), type_(type) {} + + Symbol name_; + NameType type_; +}; + +using DimnameList = c10::ArrayRef; + +TORCH_API std::ostream& operator<<(std::ostream& out, const Dimname& dimname); + +inline bool operator==(const Dimname& lhs, const Dimname& rhs) { + return lhs.symbol() == rhs.symbol(); +} + +inline bool operator!=(const Dimname& lhs, const Dimname& rhs) { + return !(lhs == rhs); +} + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DistributionsHelper.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DistributionsHelper.h new file mode 100644 index 0000000000000000000000000000000000000000..bbf8c648fca505c1d59276b050f8903978ac6555 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/DistributionsHelper.h @@ -0,0 +1,332 @@ +#pragma once + +#include +#include +#include +#include +#include + +#include +#include +#include +#include + +/** + * Distributions kernel adapted from THRandom.cpp + * The kernels try to follow std::random distributions signature + * For instance: in ATen + * auto gen = at::detail::createCPUGenerator(); + * at::uniform_real_distribution uniform(0, 1); + * auto sample = uniform(gen.get()); + * + * vs std::random + * + * std::mt19937 gen; + * std::uniform_real_distribution uniform(0, 1); + * auto sample = uniform(gen); + */ + + +namespace at { +namespace { + +/** + * Samples a discrete uniform distribution in the range [base, base+range) of type T + */ +template +struct uniform_int_from_to_distribution { + + C10_HOST_DEVICE inline uniform_int_from_to_distribution(uint64_t range, int64_t base) : range_(range), base_(base) {} + + template + C10_HOST_DEVICE inline T operator()(RNG generator) { +#ifdef FBCODE_CAFFE2 + if (( + std::is_same_v || + std::is_same_v || + std::is_same_v || + std::is_same_v) && range_ >= 1ULL << 32) +#else + if (range_ >= 1ULL << 28) // allow approx 5% skew in uniform int generation using % +#endif + { + return transformation::uniform_int_from_to(generator->random64(), range_, base_); + } else { + return transformation::uniform_int_from_to(generator->random(), range_, base_); + } + } + + private: + uint64_t range_; + int64_t base_; +}; + +/** + * Samples a discrete uniform distribution in the range [min_value(int64_t), max_value(int64_t)] + */ +template +struct uniform_int_full_range_distribution { + + template + C10_HOST_DEVICE inline T operator()(RNG generator) { + return transformation::uniform_int_full_range(generator->random64()); + } + +}; + +/** + * Samples a discrete uniform distribution in the range [0, max_value(T)] for integral types + * and [0, 2^mantissa] for floating-point types. + */ +template +struct uniform_int_distribution { + + template + C10_HOST_DEVICE inline T operator()(RNG generator) { + if constexpr (std::is_same_v || std::is_same_v) { + return transformation::uniform_int(generator->random64()); + } else { + return transformation::uniform_int(generator->random()); + } + } + +}; + +/** + * Samples a uniform distribution in the range [from, to) of type T + */ +template +struct uniform_real_distribution { + + C10_HOST_DEVICE inline uniform_real_distribution(T from, T to) : from_(from), to_(to) { + TORCH_CHECK_IF_NOT_ON_CUDA(from <= to); + TORCH_CHECK_IF_NOT_ON_CUDA(to - from <= std::numeric_limits::max()); + } + + template + C10_HOST_DEVICE inline dist_acctype operator()(RNG generator){ + if constexpr (std::is_same_v) { + return transformation::uniform_real(generator->random64(), from_, to_); + } else { + return transformation::uniform_real(generator->random(), from_, to_); + } + } + + private: + T from_; + T to_; +}; + +// The SFINAE checks introduced in #39816 looks overcomplicated and must revisited +// https://github.com/pytorch/pytorch/issues/40052 +#define DISTRIBUTION_HELPER_GENERATE_HAS_MEMBER(member) \ +template \ +struct has_member_##member \ +{ \ + typedef char yes; \ + typedef long no; \ + template static yes test(decltype(&U::member)); \ + template static no test(...); \ + static constexpr bool value = sizeof(test(0)) == sizeof(yes); \ +} + +DISTRIBUTION_HELPER_GENERATE_HAS_MEMBER(next_double_normal_sample); +DISTRIBUTION_HELPER_GENERATE_HAS_MEMBER(set_next_double_normal_sample); +DISTRIBUTION_HELPER_GENERATE_HAS_MEMBER(next_float_normal_sample); +DISTRIBUTION_HELPER_GENERATE_HAS_MEMBER(set_next_float_normal_sample); + +#define DISTRIBUTION_HELPER_GENERATE_NEXT_NORMAL_METHODS(TYPE) \ + \ +template ::value && \ + has_member_set_next_##TYPE##_normal_sample::value \ + ), int> = 0> \ +C10_HOST_DEVICE inline bool maybe_get_next_##TYPE##_normal_sample(RNG* generator, ret_type* ret) { \ + if (generator->next_##TYPE##_normal_sample()) { \ + *ret = *(generator->next_##TYPE##_normal_sample()); \ + generator->set_next_##TYPE##_normal_sample(std::optional()); \ + return true; \ + } \ + return false; \ +} \ + \ +template ::value || \ + !has_member_set_next_##TYPE##_normal_sample::value \ + ), int> = 0> \ +C10_HOST_DEVICE inline bool maybe_get_next_##TYPE##_normal_sample(RNG* /*generator*/, ret_type* /*ret*/) { \ + return false; \ +} \ + \ +template ::value \ + ), int> = 0> \ +C10_HOST_DEVICE inline void maybe_set_next_##TYPE##_normal_sample(RNG* generator, ret_type cache) { \ + generator->set_next_##TYPE##_normal_sample(cache); \ +} \ + \ +template ::value \ + ), int> = 0> \ +C10_HOST_DEVICE inline void maybe_set_next_##TYPE##_normal_sample(RNG* /*generator*/, ret_type /*cache*/) { \ +} + +DISTRIBUTION_HELPER_GENERATE_NEXT_NORMAL_METHODS(double) +DISTRIBUTION_HELPER_GENERATE_NEXT_NORMAL_METHODS(float) + +/** + * Samples a normal distribution using the Box-Muller method + * Takes mean and standard deviation as inputs + * Note that Box-muller method returns two samples at a time. + * Hence, we cache the "next" sample in the CPUGeneratorImpl class. + */ +template +struct normal_distribution { + + C10_HOST_DEVICE inline normal_distribution(T mean_in, T stdv_in) : mean(mean_in), stdv(stdv_in) { + TORCH_CHECK_IF_NOT_ON_CUDA(stdv_in >= 0, "stdv_in must be positive: ", stdv_in); + } + + template + C10_HOST_DEVICE inline dist_acctype operator()(RNG generator){ + dist_acctype ret; + // return cached values if available + if constexpr (std::is_same_v) { + if (maybe_get_next_double_normal_sample(generator, &ret)) { + return transformation::normal(ret, mean, stdv); + } + } else { + if (maybe_get_next_float_normal_sample(generator, &ret)) { + return transformation::normal(ret, mean, stdv); + } + } + // otherwise generate new normal values + uniform_real_distribution uniform(0.0, 1.0); + const dist_acctype u1 = uniform(generator); + const dist_acctype u2 = uniform(generator); + const dist_acctype r = ::sqrt(static_cast(-2.0) * ::log1p(-u2)); + const dist_acctype theta = static_cast(2.0) * c10::pi * u1; + if constexpr (std::is_same_v) { + maybe_set_next_double_normal_sample(generator, r * ::sin(theta)); + } else { + maybe_set_next_float_normal_sample(generator, r * ::sin(theta)); + } + ret = r * ::cos(theta); + return transformation::normal(ret, mean, stdv); + } + + private: + T mean; + T stdv; +}; + +template +struct DiscreteDistributionType { using type = float; }; + +template <> struct DiscreteDistributionType { using type = double; }; + +/** + * Samples a bernoulli distribution given a probability input + */ +template +struct bernoulli_distribution { + + C10_HOST_DEVICE inline bernoulli_distribution(T p_in) : p(p_in) { + TORCH_CHECK_IF_NOT_ON_CUDA(p_in >= 0 && p_in <= 1); + } + + template + C10_HOST_DEVICE inline T operator()(RNG generator) { + uniform_real_distribution uniform(0.0, 1.0); + return transformation::bernoulli(uniform(generator), p); + } + + private: + T p; +}; + +/** + * Samples a geometric distribution given a probability input + */ +template +struct geometric_distribution { + + C10_HOST_DEVICE inline geometric_distribution(T p_in) : p(p_in) { + TORCH_CHECK_IF_NOT_ON_CUDA(p_in > 0 && p_in < 1); + } + + template + C10_HOST_DEVICE inline T operator()(RNG generator) { + uniform_real_distribution uniform(0.0, 1.0); + return transformation::geometric(uniform(generator), p); + } + + private: + T p; +}; + +/** + * Samples an exponential distribution given a lambda input + */ +template +struct exponential_distribution { + + C10_HOST_DEVICE inline exponential_distribution(T lambda_in) : lambda(lambda_in) {} + + template + C10_HOST_DEVICE inline T operator()(RNG generator) { + uniform_real_distribution uniform(0.0, 1.0); + return transformation::exponential(uniform(generator), lambda); + } + + private: + T lambda; +}; + +/** + * Samples a cauchy distribution given median and sigma as inputs + */ +template +struct cauchy_distribution { + + C10_HOST_DEVICE inline cauchy_distribution(T median_in, T sigma_in) : median(median_in), sigma(sigma_in) {} + + template + C10_HOST_DEVICE inline T operator()(RNG generator) { + uniform_real_distribution uniform(0.0, 1.0); + return transformation::cauchy(uniform(generator), median, sigma); + } + + private: + T median; + T sigma; +}; + +/** + * Samples a lognormal distribution + * Takes mean and standard deviation as inputs + * Outputs two samples at a time + */ +template +struct lognormal_distribution { + + C10_HOST_DEVICE inline lognormal_distribution(T mean_in, T stdv_in) : mean(mean_in), stdv(stdv_in) { + TORCH_CHECK_IF_NOT_ON_CUDA(stdv_in > 0); + } + + template + C10_HOST_DEVICE inline T operator()(RNG generator){ + normal_distribution normal(mean, stdv); + return transformation::log_normal(normal(generator)); + } + + private: + T mean; + T stdv; +}; +} +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Formatting.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Formatting.h new file mode 100644 index 0000000000000000000000000000000000000000..db3d461915bde6b5aebd0ff0b65b36de386c730a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Formatting.h @@ -0,0 +1,25 @@ +#pragma once + +#include +#include + +#include +#include + +namespace c10 { +TORCH_API std::ostream& operator<<(std::ostream& out, Backend b); +TORCH_API std::ostream& operator<<(std::ostream & out, const Scalar& s); +TORCH_API std::string toString(const Scalar& s); +} +namespace at { + +TORCH_API std::ostream& operator<<(std::ostream& out, const DeprecatedTypeProperties& t); +TORCH_API std::ostream& print( + std::ostream& stream, + const Tensor& tensor, + int64_t linesize); +inline std::ostream& operator<<(std::ostream & out, const Tensor & t) { + return print(out,t,80); +} +TORCH_API void print(const Tensor & t, int64_t linesize=80); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Generator.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Generator.h new file mode 100644 index 0000000000000000000000000000000000000000..297b805f407b15db6d1e7a10ea199f3559fc9f63 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Generator.h @@ -0,0 +1,191 @@ +#pragma once + +#include +#include +#include +#include + +#include +#include +#include +#include + +// For the record I don't think this is a correct pimpl idiom. +// Including Impl header in interface header defeats the purpose +// because you can't change Impl private members without forcing +// everything that included the interface to rebuild. +// Impl should be forward-declared in the interface header instead. +#include + +/** + * Note [Generator] + * ~~~~~~~~~~~~~~~~ + * A Pseudo Random Number Generator (PRNG) is an engine that uses an algorithm to + * generate a seemingly random sequence of numbers, that may be later be used in creating + * a random distribution. Such an engine almost always maintains a state and requires a + * seed to start off the creation of random numbers. Often times, users have + * found it beneficial to be able to explicitly create, retain, and destroy + * PRNG states and also be able to have control over the seed value. + * + * A Generator in ATen gives users the ability to read, write and modify a PRNG engine. + * For instance, it does so by letting users seed a PRNG engine, fork the state of the + * engine, etc. + * + * By default, there is one generator per device, and a device's generator is + * lazily created. A user can use the torch.Generator() api to create their own generator. + */ + +/** + * Note [Acquire lock when using random generators] + * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + * Generator and its derived classes are NOT thread-safe. Please note that most of the + * places where we have inserted locking for generators are historically based, and we + * haven't actually checked that everything is truly thread safe (and it probably isn't). + * Please use the public mutex_ when using any methods from these classes, except for the + * read-only methods. You can learn about the usage by looking into the unittests + * (aten/src/ATen/cpu_generator_test.cpp) and other places where we have used lock_guard. + * + * TODO: Look into changing the threading semantics of Generators in ATen (e.g., making + * them non-thread safe and instead making the generator state splittable, to accommodate + * forks into other threads). + */ + +namespace at { + +class Tensor; + +struct TORCH_API Generator { + Generator() = default; + + explicit Generator(c10::intrusive_ptr gen_impl) + : impl_(std::move(gen_impl)) { + if (impl_.get() == nullptr) { + throw std::runtime_error("GeneratorImpl with nullptr is not supported"); + } + } + + bool operator==(const Generator& rhs) const { + return this->impl_ == rhs.impl_; + } + + bool operator!=(const Generator& rhs) const { + return !((*this) == rhs); + } + + bool defined() const { + return static_cast(impl_); + } + + c10::GeneratorImpl* unsafeGetGeneratorImpl() const { + return impl_.get(); + } + + c10::GeneratorImpl* unsafeReleaseGeneratorImpl() { + return impl_.release(); + } + + const c10::intrusive_ptr& getIntrusivePtr() const { + return impl_; + } + + void set_current_seed(uint64_t seed) { impl_->set_current_seed(seed); } + // Sets the offset of Generator state to the desired offset. This is currently + // supported for only Philox based Generators, i.e., CUDA and MPS. + void set_offset(uint64_t offset) { impl_->set_offset(offset); } + + // Returns the offset of Generator state. This is currently supported for only + // Philox based Generators, i.e., CUDA and MPS. + uint64_t get_offset() const { return impl_->get_offset(); } + + uint64_t current_seed() const { return impl_->current_seed(); } + + uint64_t seed() { return impl_->seed(); } + + // Implementation not inlined to prevent cycle reference between + // `ATen/core/Generator.h` and `ATen/core/Tensor.h` + void set_state(const at::Tensor& new_state); + + at::Tensor get_state() const; + + void graphsafe_set_state(const Generator& new_state); + + Generator graphsafe_get_state() const; + + std::mutex& mutex() { + return impl_->mutex_; + } + + DispatchKeySet key_set() const { + return impl_->key_set(); + } + + Device device() const { return impl_->device(); } + + inline void set_pyobj(PyObject* pyobj) const noexcept { + impl_->set_pyobj(pyobj); + } + + inline PyObject* pyobj() const noexcept { + return impl_->pyobj(); + } + + template + T* get() const { return static_cast(impl_.get()); } + + Generator clone() const { + return Generator(impl_->clone()); + } + + private: + c10::intrusive_ptr impl_; +}; + +template +Generator make_generator(Args&&... args) { + return Generator(c10::make_intrusive(std::forward(args)...)); +} + +/** + * Utility function to static cast input Generator* to + * the backend generator type (CPU/CUDAGeneratorImpl etc.) + */ +template +inline T * check_generator(std::optional gen) { + TORCH_CHECK(gen.has_value(), "Expected Generator but received nullopt"); + TORCH_CHECK(gen->defined(), "Generator with undefined implementation is not allowed"); + TORCH_CHECK(T::device_type() == gen->device().type(), "Expected a '", T::device_type(), "' device type for generator but found '", gen->device().type(), "'"); + return gen->get(); +} + +/** + * Utility function used in tensor implementations, which + * supplies the default generator to tensors, if an input generator + * is not supplied. The input Generator* is also static casted to + * the backend generator type (CPU/CUDAGeneratorImpl etc.) + */ +template +inline T* get_generator_or_default(const std::optional& gen, const Generator& default_gen) { + return gen.has_value() && gen->defined() ? check_generator(gen) : check_generator(default_gen); +} + +namespace detail { + +/** + * Helper function for checking the validity of new random generator + * state. Right now following conditions are checked: + * + * - The new state tensor must be a torch.ByteTensor + * - Data of the new state tensor must be contiguous + */ +inline void check_rng_state(const c10::TensorImpl& new_state) { + TORCH_CHECK_TYPE( + new_state.layout() == kStrided && new_state.device().type() == kCPU && new_state.dtype() == kByte, + "RNG state must be a torch.ByteTensor" + ); + + TORCH_CHECK(new_state.is_contiguous(), "RNG state must be contiguous"); +} + +} // namespace detail + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/GeneratorForPrivateuseone.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/GeneratorForPrivateuseone.h new file mode 100644 index 0000000000000000000000000000000000000000..a4879a1f5f5c78b65e353d342c7eeff6e2dac259 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/GeneratorForPrivateuseone.h @@ -0,0 +1,39 @@ +#pragma once + +#include +#include + +namespace at { + +using GeneratorFuncType = std::function; + +TORCH_API std::optional& GetGeneratorPrivate(); + +class TORCH_API _GeneratorRegister { + public: + explicit _GeneratorRegister(const GeneratorFuncType& func); +}; + +TORCH_API at::Generator GetGeneratorForPrivateuse1( + c10::DeviceIndex device_index); + +/** + * This is used to register Generator to PyTorch for `privateuse1` key. + * + * Usage: REGISTER_GENERATOR_PRIVATEUSE1(MakeGeneratorForPrivateuse1) + * + * class CustomGeneratorImpl : public c10::GeneratorImpl { + * CustomGeneratorImpl(DeviceIndex device_index = -1); + * explicit ~CustomGeneratorImpl() override = default; + * ... + * }; + * + * at::Generator MakeGeneratorForPrivateuse1(c10::DeviceIndex id) { + * return at::make_generator(id); + * } + */ + +#define REGISTER_GENERATOR_PRIVATEUSE1(GeneratorPrivate) \ + static auto temp##GeneratorPrivate = at::_GeneratorRegister(GeneratorPrivate); + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/IListRef.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/IListRef.h new file mode 100644 index 0000000000000000000000000000000000000000..aa90faf838786cf23b1e82087ca70c6ce28669eb --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/IListRef.h @@ -0,0 +1,631 @@ +#pragma once + +#include +#include +#include + +#include +#include +#include +#include + +/* + * [Note: IListRef] + * Wrapper around different API containers (e.g. boxed and unboxed). + * + * What is it? + * =========== + * It is a tagged union of both boxed and unboxed API containers. + * Working implementations: + * + * - `IListRef` + * - `IListRef` + * + * Note that `IListRef` is a view type. Meaning that it won't own the + * tensors it holds. It's intended to be used only as argument parameters. + * Specifically, where these 2 worlds overlap. + * + * What is this for? + * ================= + * Historically, PyTorch has maintained 2 different APIs: the unboxed + * (called from C++ API and Python eager mode) and boxed APIs (called + * from the TorchScript JIT, mobile interpreter, and boxed fallbacks). + * + * Calling unboxed kernels from the boxed "world" and vice-versa may + * result in non-negligible overhead. Lists are one of those types: + * + * - Boxed world: `c10::List` + * - Unboxed world: `c10::ArrayRef` + * + * In this context, `c10::IListRef` solves this problem by wrapping those + * 2 container types, so that we don't need to convert from one to + * the other. + * + * (see https://github.com/pytorch/pytorch/issues/66328) + * + * What does it do? + * ================ + * This container wraps around the different tagged containers + * (currently, only boxed and unboxed), without incurring in extra + * overhead for converting from one to another. It does so while + * exposing usual container methods, which dispatch to corresponding + * implementations. + * + * While it works with different container types, it introduces + * overhead for repeatedly calling member functions (since those will + * get dispatched, again). Therefore, you should only use it to iterate + * through the list up to one time. If you need to do more complex things, + * call `materialize()` first. + * + * Adding support for a new Tag + * ============================ + * Suppose we want to add a new tag: `Chest`. Here are the steps + * we would have to go through: + * + * 1. Add a line for it in the macro `TORCH_ILISTREF_FORALL_TAGS`. + * + * #define TORCH_ILISTREF_FORALL_TAGS(_, ...) \ + * ... + * _(Chest, ##__VA_ARGS__) + * + * 2. Add type aliases, union members, and constructors. + * + * template + * class IListRef { + * ... + * using chest_type = + * typename detail::IListRefTagImpl::list_type; + * ... + * IListRef(...) : tag_(IListRefTag::Chest) { + * ... + * } + * ... + * union Payload { + * ... + * chest_type chest; + * ... + * }; + * ... + * }; + * + * 3. Add a default implementation for it (in 'IListRef_inl.h'). It's + * preferable to make the default implementation work for `T = Tensor` + * (both `Unboxed` and `Boxed` do it). + * + * template + * class IListRefTagImplBase { + * public: + * using elem_type = ListElemT; + * using list_type = ChestContainer; + * + * static const list_type& unwrap(const IListRef& ilist) { ... } + * + * static typename list_type::const_iterator& unwrap( + * IListRefIterator& it) { ... } + * + * static const typename list_type::const_iterator& unwrap( + * const IListRefIterator& it) { ... } + * + * static IListRefConstRef iterator_get( + * const typename list_type::const_iterator& it) { ... } + * } + * + * 4. Add an specialization for each of the already supported types. + * Finally, for consistency, add them to the tracking list. + * (see [Note: IListRefTagImpl Specializations]) + * + * template <> + * class IListRefTagImpl + * : public IListRefTagImplBase {}; + * + * Adding support for a new Type + * ============================= + * Suppose we want to add support for a new type: `Matrix`. + * Here are the steps we would have to go through: + * + * 1. Add an specialization for each of the existing tags. + * For consistency, add them to the tracking list. + * (see [Note: IListRefTagImpl Specializations]) + * + * template <> + * class IListRefTagImpl + * : public IListRefTagImplBase {}; + * + * template <> + * class IListRefTagImpl + * : public IListRefTagImplBase {}; + * + * Common Problems + * =============== + * 1. One of `IListRef(Iterator)` methods are failing to compile. + * + * That may be happening because the container type you added + * is not compatible with the code written for that method. If + * that's true, then you might have to transform that code into + * a static method call (see `List::operator[]` method). + * + * 2. Can't make `IListRefIterator::operator*` return a const-reference. + * + * First, keep in mind that we assume that boxed containers will + * have to deal with `IValue` (e.g. `c10::List`). In this context, + * what may be happening is that `IValue` doesn't store internally + * your type `T`. Instead, it constructs a type new `T` everytime + * you try to get `T` for it (see `IListRef`). + */ + +namespace c10 { +template +class IListRef; + +/* + * Applies arbitrary macros to each `IListRefTag`. + */ +#define TORCH_ILISTREF_FORALL_TAGS(_, ...) \ + _(Unboxed, ##__VA_ARGS__) \ + _(Boxed, ##__VA_ARGS__) \ + _(Materialized, ##__VA_ARGS__) + +/* + * Defines a "switch-case" for `TAG`. Inside, it executes `BODY`, + * while bringing to scope: + * + * - `ImplT`: the implementation class for `TAG` + * - `this_`: the result of unwrapping `this` + */ +#define TORCH_ILISTREF_UNWRAP_CASE(TAG, BODY) \ + case c10::IListRefTag::TAG: { \ + using ImplT = c10::detail::IListRefTagImpl; \ + auto& this_ = ImplT::unwrap(*this); \ + BODY \ + } break; + +/* + * Dispatches the unwrap call, depending on `TAG`, followed by + * the execution of `BODY`. It aborts if `TAG` is not a `IListRefTag`. + * + * This macro is useful because it allows us to handle different + * types (that correspond to different tags) to be implemented + * only once. We can do it even when the implementation of the + * different tags aren't syntatically the same, by dispatching + * it to a function (e.g. `ImplT::(this_)`). + */ +#define TORCH_ILISTREF_UNWRAP(TAG, BODY) \ + switch (TAG) { \ + TORCH_ILISTREF_FORALL_TAGS(TORCH_ILISTREF_UNWRAP_CASE, BODY) \ + break; \ + default: \ + TORCH_INTERNAL_ASSERT(false, "invalid IListRef tag."); \ + } + +enum class IListRefTag { +#define DEFINE_TAG(tag, ...) tag, + TORCH_ILISTREF_FORALL_TAGS(DEFINE_TAG) +#undef DEFINE_TAG + None +}; + +namespace detail { +/* + * Type alias that specifies whether we return a reference or a copy of `T`. + * + * What is this for? + * ================= + * Since values in the boxed world are represented by an `IValue`, we also + * depend on whether it can be converted to a const-reference (`Tensor`) or + * has to create a new copy of `T` (`OptionalTensorRef`). + */ +template +using IListRefConstRef = typename ivalue_to_const_ref_overload_return::type; + +/* + * Interface that implements key functions for each `IListRefTag` type. + * + * What is this for? + * ================= + * Given an `IListRef(Iterator)`, some methods have to be implemented + * differently for each `TAG`. Therefore, the methods inside this class + * are used as dispatch targets for the different `IListRefTag` values. + * + * You should create an specialization of this class for each possible + * combination of `IListRefTag` type (except `None`) and element types + * (e.g. `Tensor`). + * + * What does it do? + * ================ + * 1. defines static methods to be used as dispatch targets by both + * `IListRef` and `IListRefIterator` (see the implementation of + * `IListRefTagImplBase`). + * + * 2. defines the `elem_type` and `list_type` aliases that will be + * used in the definition of `IListRef`. In general, we should do + * so by inheriting from `IListRefTagImplBase`. + * + * [Note: IListRefTagImpl Specialization] + * ====================================== + * For `IListRef(Iterator)`: + * - + * - + * - + * + * For `IListRef(Iterator)`: + * - + * - + * - + */ +template +class IListRefTagImpl {}; + +/* + * Base implementation of `IListRefTagImpl` methods. + * + * What is this for? + * ================= + * This should make adding specializations for new types easier. For + * example, one should be able to add a new type just by making its + * `IListRefTagImpl` specialization inherit from `IListRefTagImplBase`. + * + * You should create a partial specialization for this class only if + * you introduce a new `IListRefTag`. The idea being that there is one + * default implementation for each possible value of `IListRefTag`. + * + * What does it do? + * ================ + * 1. defines `elem_type` as an alias to `ListElemT`. + * + * 1. defines `list_type` as an alias to the default container type + * that will hold a collection of `elem_type`. The idea being that + * all types tagged as `TAG` will have `list_type` as its container, + * with different `elem_type`. + * + * 3. defines the default implementation for each of the methods that + * are supposed to be defined on `IListRefTagImpl` specializations. + * + * 4. inheriting from `IListRefTagImplBase` also means + * that the payload of the type `IListRef` will be of type `list_type` + * when it is tagged as `TAG`. + */ +template +class IListRefTagImplBase {}; + +/* + * Materialized container for `IListRef`. + * + * What is this for? + * ================= + * Container that groups `T` references together. This exchanges the + * overhead of every method call from `IListRef` for a dynamic allocation. + * + * You should use this container instead of `IListRef` if: + * + * - You are going to iterate the list more than once + * - You need to repeatedly access arbitrary elements (using `operator[]`) + * What does it do? + + * ================ + * Removes the reference (&) from the type, and wraps it into a + * `std::reference_wrapper`. If `IListRefConstRef` is not a + * reference type, then it's left unchanged. + */ +template +using _MaterializedIListRefElem = std::conditional_t< + std::is_reference_v, + typename std::reference_wrapper>, + T>; + +template +using MaterializedIListRefElem = _MaterializedIListRefElem>; + +template +using MaterializedIListRef = std::vector>; + +} // namespace detail + +/* + * Iterator for `IListRef`. + * + * What is it? + * =========== + * Currently, a `std::bidirectional_iterator` that wraps the iterator + * types defined for each of the `IListRefTag`. + * + * One should be able to use it, as if it were the unwrapped + * iterators themselves. + + * What does it do? + * ================ + * Similarly to `IListRef`, this is a wrapper class. Specifically, it + * wraps each container's `const_iterator` type alias. So, for example, + * given that the container for `IListRefTag::Boxed` is `c10::List`, this + * iterator will wrap a `c10::List::const_iterator`. + * + * [Note: MSVC Iterator Debug] + * =========================== + * MSVC `vector::iterator` implementation (used in the boxed variant) + * makes it so this union's destructor, copy-constructor (assignment), and + * move-constructor (assignment) are implicitly deleted. + * + * Therefore, we need to explicitly define them as needed. Follows a list + * of places where these are needed and their reason: + * + * - `Payload` destructor: + * it is deleted only if the macro `_ITERATOR_DEBUG_LEVEL` is set to 2. + * + * - `IListRefIterator` destructor: + * same as above. However, we need to explicitly call the variant + * destructor explicitly. + * + * - `IListRefIterator` copy-constructor: + * it is deleted only if the macro `_ITERATOR_DEBUG_LEVEL` is different + * than 0. + */ +template +class IListRefIterator { + private: +#define DEFINE_FRIEND_CLASS(TAG, ...) \ + friend class detail::IListRefTagImpl; \ + friend class detail::IListRefTagImplBase< \ + IListRefTag::TAG, \ + T, \ + typename detail::IListRefTagImpl::elem_type>; + TORCH_ILISTREF_FORALL_TAGS(DEFINE_FRIEND_CLASS) +#undef DEFINE_FRIEND_CLASS + + public: + // C++17 friendly std::iterator implementation + using iterator_category = std::bidirectional_iterator_tag; + using value_type = T; + using difference_type = std::ptrdiff_t; + using pointer = T*; + using reference = T&; + + using unboxed_iterator_type = typename detail:: + IListRefTagImpl::list_type::const_iterator; + using boxed_iterator_type = typename detail:: + IListRefTagImpl::list_type::const_iterator; + using materialized_iterator_type = + typename detail::MaterializedIListRef::const_iterator; + + IListRefIterator() : tag_(IListRefTag::None) {} + +#if defined(_MSC_VER) && _ITERATOR_DEBUG_LEVEL != 0 + // See [Note: MSVC Iterator Debug] + IListRefIterator(const IListRefIterator& iterator) + : tag_(iterator.tag_) { + switch (tag_) { + case IListRefTag::Boxed: + payload_.boxed_iterator = iterator.payload_.boxed_iterator; + break; + case IListRefTag::Unboxed: + payload_.unboxed_iterator = iterator.payload_.unboxed_iterator; + break; + case IListRefTag::Materialized: + payload_.materialized_iterator = iterator.payload_.materialized_iterator; + break; + default: + TORCH_INTERNAL_ASSERT(false, "invalid IListRef tag."); + } + } +#endif + +#if defined(_MSC_VER) && _ITERATOR_DEBUG_LEVEL == 2 + // See [Note: MSVC Iterator Debug] + ~IListRefIterator() noexcept(false) { + switch (tag_) { + case IListRefTag::Boxed: + payload_.boxed_iterator.~boxed_iterator_type(); + break; + case IListRefTag::Unboxed: + payload_.unboxed_iterator.~unboxed_iterator_type(); + break; + case IListRefTag::Materialized: + payload_.materialized_iterator.~materialized_iterator_type(); + break; + default: + TORCH_INTERNAL_ASSERT(false, "invalid IListRef tag."); + } + } +#endif + + IListRefIterator(boxed_iterator_type boxed) : tag_(IListRefTag::Boxed) { + payload_.boxed_iterator = boxed; + } + + IListRefIterator(unboxed_iterator_type unboxed) : tag_(IListRefTag::Unboxed) { + payload_.unboxed_iterator = unboxed; + } + + IListRefIterator(materialized_iterator_type materialized) : tag_(IListRefTag::Materialized) { + payload_.materialized_iterator = materialized; + } + + detail::IListRefConstRef operator*() const { + TORCH_ILISTREF_UNWRAP(tag_, { return ImplT::iterator_get(this_); }); + } + + IListRefIterator& operator++() { + TORCH_ILISTREF_UNWRAP(tag_, { ++this_; }); + return *this; + } + + IListRefIterator operator++(int) { + auto old = *this; + TORCH_ILISTREF_UNWRAP(tag_, { ++this_; }); + return old; + } + + IListRefIterator& operator--() { + TORCH_ILISTREF_UNWRAP(tag_, { --this_; }); + return *this; + } + + IListRefIterator operator--(int) { + auto old = *this; + TORCH_ILISTREF_UNWRAP(tag_, { --this_; }); + return old; + } + + bool operator==(const IListRefIterator& rhs) const { + if (tag_ != rhs.tag_) { + return false; + } + TORCH_ILISTREF_UNWRAP(tag_, { + auto& rhs_it = ImplT::unwrap(rhs); + return this_ == rhs_it; + }); + } + + bool operator!=(const IListRefIterator& rhs) const { + return !(*this == rhs); + } + + private: + union Payload { + boxed_iterator_type boxed_iterator; + unboxed_iterator_type unboxed_iterator; + materialized_iterator_type materialized_iterator; + void* _init_ptr; + Payload() : _init_ptr(nullptr) {} +#if defined(_MSC_VER) + // See [Note: MSVC Iterator Debug] + ~Payload() {} +#endif + }; + + Payload payload_; + IListRefTag tag_; +}; + +/* + * See [Note: IListRef] + */ +template +class IListRef { + private: +#define DEFINE_FRIEND_CLASS(TAG, ...) \ + friend class detail::IListRefTagImpl; \ + friend class detail::IListRefTagImplBase< \ + IListRefTag::TAG, \ + T, \ + typename detail::IListRefTagImpl::elem_type>; + TORCH_ILISTREF_FORALL_TAGS(DEFINE_FRIEND_CLASS) +#undef DEFINE_FRIEND_CLASS + + public: + using unboxed_type = + typename detail::IListRefTagImpl::list_type; + using boxed_type = + typename detail::IListRefTagImpl::list_type; + using materialized_type = + typename detail::MaterializedIListRef; + + using iterator = IListRefIterator; + using const_iterator = IListRefIterator; + using reverse_iterator = std::reverse_iterator; + using value_type = typename iterator::value_type; + + IListRef() : tag_(IListRefTag::None) {} + + IListRef(const boxed_type& boxed) : tag_(IListRefTag::Boxed) { + payload_.boxed = &boxed; + } + + IListRef(const unboxed_type& unboxed) : tag_(IListRefTag::Unboxed) { + payload_.unboxed = unboxed; + } + + IListRef(const std::initializer_list& list) : tag_(IListRefTag::Unboxed) { + payload_.unboxed = at::ArrayRef(list); + } + + template < + typename... UnboxedConstructorArgs, + typename = std::enable_if_t< + std::is_constructible_v>> + IListRef(UnboxedConstructorArgs&&... args) : tag_(IListRefTag::Unboxed) { + payload_.unboxed = unboxed_type(std::forward(args)...); + } + + IListRef(const materialized_type& materialized) : tag_(IListRefTag::Materialized) { + payload_.materialized = &materialized; + } + + size_t size() const { + TORCH_ILISTREF_UNWRAP(tag_, { return this_.size(); }); + } + + bool empty() const { + return size() == 0; + } + + iterator begin() const { + TORCH_ILISTREF_UNWRAP(tag_, { return this_.begin(); }); + } + + iterator end() const { + TORCH_ILISTREF_UNWRAP(tag_, { return this_.end(); }); + } + + detail::IListRefConstRef front() const { + TORCH_ILISTREF_UNWRAP(tag_, { return ImplT::front(this_); }); + } + + /* + * Materializes the `IListRef` into a `std::vector`. + * + * This should be used when one wishes to either: + * + * - iterate over the list more than once: each `IListRefIterator` + * member function call has to go through a switch, introducing + * non-negligible overhead + * + * - randomly access an arbitrary element using `operator[]`: + * same reason as above + */ + detail::MaterializedIListRef materialize() const { + if (isMaterialized()) { + return toMaterialized(); + } + + detail::MaterializedIListRef materialized; + materialized.reserve(size()); + for (const auto& t : *this) { + materialized.emplace_back(t); + } + return materialized; + } + +#define DEFINE_CHECK(TAG, ...) \ + bool is##TAG() const { \ + return tag_ == IListRefTag::TAG; \ + } + TORCH_ILISTREF_FORALL_TAGS(DEFINE_CHECK) +#undef DEFINE_CHECK + + bool isNone() const { + return tag_ == IListRefTag::None; + } + +#define DEFINE_CASTING(TAG, ...) \ + const typename detail::IListRefTagImpl::list_type& \ + to##TAG() const { \ + TORCH_INTERNAL_ASSERT(is##TAG()); \ + return detail::IListRefTagImpl::unwrap(*this); \ + } + TORCH_ILISTREF_FORALL_TAGS(DEFINE_CASTING) +#undef DEFINE_CASTING + + private: + union Payload { + const boxed_type* boxed; + unboxed_type unboxed; + const materialized_type* materialized; + Payload() : boxed(nullptr) {} + }; + + Payload payload_; + IListRefTag tag_; +}; + +} // namespace c10 + +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/IListRef_inl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/IListRef_inl.h new file mode 100644 index 0000000000000000000000000000000000000000..a21bd22cf16c942896d663896be16e60e8612c5c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/IListRef_inl.h @@ -0,0 +1,201 @@ +#pragma once + +#include +#include + +namespace at { +class Tensor; +class OptionalTensorRef; +} + + +namespace c10::detail { + +/* + * Specializations of `IListRefTagImplBase` that implement the default + * implementation for `IListRefTag::Unboxed`. + */ +template +class IListRefTagImplBase { + public: + using elem_type = ListElemT; + using list_type = ArrayRef; + + /* + * These `unwrap` static methods unwraps the inner containers out + * of `IListRef` (and `IListRefIterator`). They are required when + * the macro `TORCH_ILISTREF_UNWRAP` is called. + */ + static const list_type& unwrap(const IListRef& ilist) { + return ilist.payload_.unboxed; + } + + static typename list_type::const_iterator& unwrap(IListRefIterator& it) { + return it.payload_.unboxed_iterator; + } + + static const typename list_type::const_iterator& unwrap( + const IListRefIterator& it) { + return it.payload_.unboxed_iterator; + } + + /* + * We have these function (besides the `unwrap`s above) because the + * implementation for both `IListRef::operator[]` and `IListRefIterator::operator*` + * weren't syntatically equal for the existing tags at the time + * (`Unboxed` and `Boxed`). + */ + static IListRefConstRef front(const list_type& lst) { + return lst.front(); + } + + static IListRefConstRef iterator_get( + const typename list_type::const_iterator& it) { + return *it; + } +}; + +/* + * Specializations of `IListRefTagImplBase` that implement the default + * implementation for `IListRefTag::Boxed`. + */ +template +class IListRefTagImplBase { + public: + using elem_type = ListElemT; + using list_type = List; + + static const list_type& unwrap(const IListRef& ilist) { + return *ilist.payload_.boxed; + } + + static typename list_type::const_iterator& unwrap(IListRefIterator& it) { + return it.payload_.boxed_iterator; + } + + static const typename list_type::const_iterator& unwrap( + const IListRefIterator& it) { + return it.payload_.boxed_iterator; + } + + static IListRefConstRef front(const list_type& lst) { + return lst[0]; + } + + static IListRefConstRef iterator_get( + const typename list_type::const_iterator& it) { + return (*it).get().toTensor(); + } +}; + +/* + * Specializations of `IListRefTagImplBase` that implement the default + * implementation for `IListRefTag::Materialized`. + */ +template +class IListRefTagImplBase> { + public: + using elem_type = MaterializedIListRefElem; + using list_type = MaterializedIListRef; + + static const list_type& unwrap(const IListRef& ilist) { + return *ilist.payload_.materialized; + } + + static typename list_type::const_iterator& unwrap(IListRefIterator& it) { + return it.payload_.materialized_iterator; + } + + static const typename list_type::const_iterator& unwrap( + const IListRefIterator& it) { + return it.payload_.materialized_iterator; + } + + static IListRefConstRef front(const list_type& lst) { + return lst[0]; + } + + static IListRefConstRef iterator_get( + const typename list_type::const_iterator& it) { + return *it; + } +}; + +/* + * [Note: ITensorListRef] + * Specializations necessary for `IListRef` type. + * + * Since the default implementations are usually done with supporting + * `Tensor` in mind, we only have to inherit from the base implementations. + */ +template <> +class IListRefTagImpl + : public IListRefTagImplBase {}; + +template <> +class IListRefTagImpl + : public IListRefTagImplBase {}; + +template <> +class IListRefTagImpl + : public IListRefTagImplBase< + IListRefTag::Materialized, + at::Tensor, + MaterializedIListRefElem> {}; + +/* + * [Note: IOptTensorListRef] + * Specializations necessary for `IListRef` type. + * + * We can't get an `at::OptionalTensorRef` directly from an instance of + * `List>` (the type that corresponds to the boxed world). + * + * So, the default implementation won't help us. Thus, we have to implement + * this method ourselves. + */ +template <> +class IListRefTagImpl + : public IListRefTagImplBase {}; + +template <> +class IListRefTagImpl + : public IListRefTagImplBase> { + + public: + /* + * Given an instance of the types corresponding to the `Boxed` tag, we override + * the default implementation, so that we can return a `at::OptionalTensorRef`. + */ + static IListRefConstRef iterator_get( + const typename list_type::const_iterator& it) { + const auto& ivalue = (*it).get(); + if (!ivalue.isNone()) { + const auto& tensor = ivalue.toTensor(); + return (tensor.defined()) ? tensor : at::OptionalTensorRef{}; + } + return {}; + } +}; + +template <> +class IListRefTagImpl + : public IListRefTagImplBase< + IListRefTag::Materialized, + at::OptionalTensorRef, + MaterializedIListRefElem> {}; + +} // namespace c10::detail + + +namespace at { + +// [Note: ITensorListRef] +using ITensorListRef = c10::IListRef; +using ITensorListRefIterator = c10::IListRefIterator; +using MaterializedITensorListRef = c10::detail::MaterializedIListRef; +// [Note: IOptTensorListRef] +using IOptTensorListRef = c10::IListRef; +using IOptTensorListRefIterator = c10::IListRefIterator; +using MaterializedIOptTensorListRef = c10::detail::MaterializedIListRef; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/LegacyTypeDispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/LegacyTypeDispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..3efe5e0f7b87b66a1cf22ef1d5fb0f93e2f78494 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/LegacyTypeDispatch.h @@ -0,0 +1,111 @@ +#pragma once + +// The legacy mechanism for dispatching operators in ATen is a Type +// object, which is essentially a giant virtual dispatch table +// for every operation we support dynamically dispatching over. +// +// This has been deprecated in favor of ATenDispatch, and in the future, +// c10 dispatcher. +// TODO: Clean up what remains here + +#include + +namespace at { + +// A RAII, thread local (!) guard that will disable dispatch to variable +// handler. +// +// NOTE [ Treating Variables as non-Variables in type dispatch ] +// +// What exactly does AutoDispatchBelowAutograd do? The short answer is, it causes +// dispatches on ATen functions to go to the non-variable implementation, +// bypassing autograd handling (and also profiling and tracing). +// +// To understand why this guard exists, it's helpful to understand the history +// behind how Variable was implemented. Previously, Variables were implemented +// as a wrapper on Tensors; so the act of processing a Variable involved +// unwrapping the underlying Tensor, and then calling the underlying base +// operation on /that/ operation +// +// However, after the Variable/Tensor merge, there is no concept of unwrapping +// a tensor anymore. If you just call the operation on the same variable +// again inside your VariableType handler, you'll dispatch back to +// VariableType, which is not what we want. +// +// The solution to the above problem is to add `at::AutoDispatchBelowAutograd`, which +// when enabled will cause `legacyTensorType()` and `getType()` to always return +// non-Variable type, even if the tensor being called on is a variable. + +/* Note [AutoDispatchBelowAutograd] + * AutoDispatchBelowAutograd is **INTERNAL ONLY** that it should be used + * for kernel implementations and customized C++ kernels. + * If you are looking for a guard to run workload in inference mode, please use + * c10::InferenceMode RAII which is user facing API. + * In the past AutoDispatchBelowAutograd(or its old version AutoNonVariableTypeMode) + * was used in the user code for inference-only workload, this was under risk of + * producing wrong results silently in some edge cases. For example: + * ``` + * torch::Tensor s = torch::ones({1, 2, 3}).set_requires_grad(true); + * torch::Tensor out = s * s; + * { + * at::AutoDispatchBelowAutograd guard; + * s.add_(1); // Skips version bump on `s`. + * } + * // WRONG GRADIENT! s.grad() are now computed using `s` value after the + * // inplace update. + * out.backward(torch::ones_like(out)); + * ``` + * Users should use `c10::InferenceMode` here so that it'll properly throw an + * error saying "one of the variables needed for gradient computation has be modified." + */ +struct TORCH_API AutoDispatchBelowAutograd { + AutoDispatchBelowAutograd() : + autograd_guard_(c10::autograd_dispatch_keyset) { + } + + // disable all autograd dispatch keys + c10::impl::ExcludeDispatchKeyGuard autograd_guard_; +}; + +// TODO: AutoNonVariableTypeMode should be removed in release 1.10. +struct TORCH_API AutoNonVariableTypeMode { + AutoNonVariableTypeMode(bool enabled = true) : + autograd_guard_(c10::autograd_dispatch_keyset) { + TORCH_WARN_ONCE("AutoNonVariableTypeMode is deprecated and will be removed in 1.10 release. " + "For kernel implementations please use AutoDispatchBelowADInplaceOrView instead, " + "If you are looking for a user facing API to enable running your inference-only " + "workload, please use c10::InferenceMode. Using AutoDispatchBelowADInplaceOrView in user code " + "is under risk of producing silent wrong result in some edge cases. " + "See Note [AutoDispatchBelowAutograd] for more details."); + TORCH_INTERNAL_ASSERT(enabled); + } + + // disable all autograd dispatch keys + c10::impl::ExcludeDispatchKeyGuard autograd_guard_; +}; + +struct TORCH_API AutoDispatchSkipFunctionalize { + AutoDispatchSkipFunctionalize() : + dispatch_key_guard_(c10::DispatchKeySet(c10::DispatchKey::Functionalize)) { + } + c10::impl::ExcludeDispatchKeyGuard dispatch_key_guard_; +}; + +/* Note [AutoDispatchBelowADInplaceOrView] + * AutoDispatchBelowADInplaceOrView is equivalent to AutoNonVariableTypeMode + * before we split inplace & view ops out of VariableType kernel. + * Note this guard is used in VariableType kernels for functional ops + * as well as ADInplaceOrView kernels for inplace/view ops to enforce the + * Invariant: + * Once you are in VariableType/ADInplaceOrView kernel for an op, + * you never go back to a kernel on same dispatch key until + * you finish the current op. + */ +struct TORCH_API AutoDispatchBelowADInplaceOrView { + AutoDispatchBelowADInplaceOrView() : + dispatch_key_guard_(c10::autograd_dispatch_keyset_with_ADInplaceOrView) { + } + // disable Autograd & ADInplaceOrView dispatch keys + c10::impl::ExcludeDispatchKeyGuard dispatch_key_guard_; +}; +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/List.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/List.h new file mode 100644 index 0000000000000000000000000000000000000000..4cb22831947f41efc44db148d43a3395f2883843 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/List.h @@ -0,0 +1,491 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at { +class Tensor; +} +namespace c10 { +struct IValue; +template class List; +struct Type; + +namespace detail { + +struct ListImpl final : public c10::intrusive_ptr_target { + using list_type = std::vector; + + explicit TORCH_API ListImpl(list_type list_, TypePtr elementType_); + + list_type list; + + TypePtr elementType; + + intrusive_ptr copy() const { + return make_intrusive(list, elementType); + } + friend TORCH_API bool operator==(const ListImpl& lhs, const ListImpl& rhs); +}; +} + +namespace impl { + +template class ListIterator; + +template class ListElementReference; + +template +void swap(ListElementReference&& lhs, ListElementReference&& rhs) noexcept; + +template +bool operator==(const ListElementReference& lhs, const T& rhs); + +template +bool operator==(const T& lhs, const ListElementReference& rhs); + +template +struct ListElementConstReferenceTraits { + // In the general case, we use IValue::to(). + using const_reference = typename c10::detail::ivalue_to_const_ref_overload_return::type; +}; + +// There is no to() overload for std::optional. +template<> +struct ListElementConstReferenceTraits> { + using const_reference = std::optional>; +}; + +template +class ListElementReference final { +public: + operator std::conditional_t< + std::is_reference_v::type>, + const T&, + T>() const; + + ListElementReference& operator=(T&& new_value) &&; + + ListElementReference& operator=(const T& new_value) &&; + + // assigning another ref to this assigns the underlying value + ListElementReference& operator=(ListElementReference&& rhs) && noexcept; + + const IValue& get() const& { + return *iterator_; + } + + friend void swap(ListElementReference&& lhs, ListElementReference&& rhs) noexcept; + + ListElementReference(const ListElementReference&) = delete; + ListElementReference& operator=(const ListElementReference&) = delete; + ~ListElementReference() = default; + +private: + ListElementReference(Iterator iter) + : iterator_(iter) {} + + // allow moving, but only our friends (i.e. the List class) can move us + ListElementReference(ListElementReference&&) noexcept = default; + ListElementReference& operator=(ListElementReference&& rhs) & noexcept { + iterator_ = std::move(rhs.iterator_); + return *this; + } + + friend class List; + friend class ListIterator; + + Iterator iterator_; +}; + +// this wraps vector::iterator to make sure user code can't rely +// on it being the type of the underlying vector. +template +class ListIterator final { + public: + // C++17 friendly std::iterator implementation + using iterator_category = std::random_access_iterator_tag; + using value_type = T; + using difference_type = std::ptrdiff_t; + using pointer = T*; + using reference = ListElementReference; + + explicit ListIterator() = default; + ~ListIterator() = default; + + ListIterator(const ListIterator&) = default; + ListIterator(ListIterator&&) noexcept = default; + ListIterator& operator=(const ListIterator&) = default; + ListIterator& operator=(ListIterator&&) noexcept = default; + + ListIterator& operator++() { + ++iterator_; + return *this; + } + + ListIterator operator++(int) { + ListIterator copy(*this); + ++*this; + return copy; + } + + ListIterator& operator--() { + --iterator_; + return *this; + } + + ListIterator operator--(int) { + ListIterator copy(*this); + --*this; + return copy; + } + + ListIterator& operator+=(typename List::size_type offset) { + iterator_ += offset; + return *this; + } + + ListIterator& operator-=(typename List::size_type offset) { + iterator_ -= offset; + return *this; + } + + ListIterator operator+(typename List::size_type offset) const { + return ListIterator{iterator_ + offset}; + } + + ListIterator operator-(typename List::size_type offset) const { + return ListIterator{iterator_ - offset}; + } + + friend difference_type operator-(const ListIterator& lhs, const ListIterator& rhs) { + return lhs.iterator_ - rhs.iterator_; + } + + ListElementReference operator*() const { + return {iterator_}; + } + + ListElementReference operator[](typename List::size_type offset) const { + return {iterator_ + offset}; + } + +private: + explicit ListIterator(Iterator iterator): iterator_(std::move(iterator)) {} + + Iterator iterator_; + + friend bool operator==(const ListIterator& lhs, const ListIterator& rhs) { + return lhs.iterator_ == rhs.iterator_; + } + + friend bool operator!=(const ListIterator& lhs, const ListIterator& rhs) { + return !(lhs == rhs); + } + + friend bool operator<(const ListIterator& lhs, const ListIterator& rhs) { + return lhs.iterator_ < rhs.iterator_; + } + + friend bool operator<=(const ListIterator& lhs, const ListIterator& rhs) { + return lhs.iterator_ <= rhs.iterator_; + } + + friend bool operator>(const ListIterator& lhs, const ListIterator& rhs) { + return lhs.iterator_ > rhs.iterator_; + } + + friend bool operator>=(const ListIterator& lhs, const ListIterator& rhs) { + return lhs.iterator_ >= rhs.iterator_; + } + + friend class ListIterator; + friend class List; +}; + +template List toTypedList(List list); +template List toList(List&& list); +template List toList(const List& list); +const IValue* ptr_to_first_element(const List& list); +} + +/** + * An object of this class stores a list of values of type T. + * + * This is a pointer type. After a copy, both Lists + * will share the same storage: + * + * > List a; + * > List b = a; + * > b.push_back("three"); + * > ASSERT("three" == a.get(0)); + * + * We use this class in the PyTorch kernel API instead of + * std::vector, because that allows us to do optimizations + * and switch out the underlying list implementation without + * breaking backwards compatibility for the kernel API. + */ +template +// NOLINTNEXTLINE(cppcoreguidelines-special-member-functions) +class List final { +private: + // This is an intrusive_ptr because List is a pointer type. + // Invariant: This will never be a nullptr, there will always be a valid + // ListImpl. + c10::intrusive_ptr impl_; + + using internal_reference_type = impl::ListElementReference; + using internal_const_reference_type = typename impl::ListElementConstReferenceTraits::const_reference; + +public: + using value_type = T; + using size_type = typename c10::detail::ListImpl::list_type::size_type; + using iterator = impl::ListIterator; + using const_iterator = impl::ListIterator; + using reverse_iterator = impl::ListIterator; + + /** + * Constructs an empty list. + */ + explicit List(); + + /** + * Constructs a list with some initial values. + * Example: + * List a({2, 3, 4}); + */ + List(std::initializer_list initial_values); + explicit List(ArrayRef initial_values); + + /** + * Create a generic list with runtime type information. + * This only works for c10::impl::GenericList and is not part of the public API + * but only supposed to be used internally by PyTorch. + */ + explicit List(TypePtr elementType); + + List(const List&) = default; + List& operator=(const List&) = default; + ~List() = default; + + /** + * Create a new List pointing to a deep copy of the same data. + * The List returned is a new list with separate storage. + * Changes in it are not reflected in the original list or vice versa. + */ + List copy() const; + + /** + * Returns the element at specified location pos, with bounds checking. + * If pos is not within the range of the container, an exception of type std::out_of_range is thrown. + */ + internal_const_reference_type get(size_type pos) const; + + /** + * Moves out the element at the specified location pos and returns it, with bounds checking. + * If pos is not within the range of the container, an exception of type std::out_of_range is thrown. + * The list contains an invalid element at position pos afterwards. Any operations + * on it before re-setting it are invalid. + */ + value_type extract(size_type pos) const; + + /** + * Returns a reference to the element at specified location pos, with bounds checking. + * If pos is not within the range of the container, an exception of type std::out_of_range is thrown. + * + * You cannot store the reference, but you can read it and assign new values to it: + * + * List list = ...; + * list[2] = 5; + * int64_t v = list[1]; + */ + internal_const_reference_type operator[](size_type pos) const; + + internal_reference_type operator[](size_type pos); + + /** + * Assigns a new value to the element at location pos. + */ + void set(size_type pos, const value_type& value) const; + + /** + * Assigns a new value to the element at location pos. + */ + void set(size_type pos, value_type&& value) const; + + /** + * Returns an iterator to the first element of the container. + * If the container is empty, the returned iterator will be equal to end(). + */ + iterator begin() const; + + /** + * Returns an iterator to the element following the last element of the container. + * This element acts as a placeholder; attempting to access it results in undefined behavior. + */ + iterator end() const; + + /** + * Checks if the container has no elements. + */ + bool empty() const; + + /** + * Returns the number of elements in the container + */ + size_type size() const; + + /** + * Increase the capacity of the vector to a value that's greater or equal to new_cap. + */ + void reserve(size_type new_cap) const; + + /** + * Erases all elements from the container. After this call, size() returns zero. + * Invalidates any references, pointers, or iterators referring to contained elements. Any past-the-end iterators are also invalidated. + */ + void clear() const; + + /** + * Inserts value before pos. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + iterator insert(iterator pos, const T& value) const; + + /** + * Inserts value before pos. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + iterator insert(iterator pos, T&& value) const; + + /** + * Inserts a new element into the container directly before pos. + * The new element is constructed with the given arguments. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + template + iterator emplace(iterator pos, Args&&... value) const; + + /** + * Appends the given element value to the end of the container. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + void push_back(const T& value) const; + + /** + * Appends the given element value to the end of the container. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + void push_back(T&& value) const; + + /** + * Appends the given list to the end of the container. Uses at most one memory allocation. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + void append(List lst) const; + + /** + * Appends the given element value to the end of the container. + * The new element is constructed with the given arguments. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + template + void emplace_back(Args&&... args) const; + + /** + * Removes the element at pos. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + iterator erase(iterator pos) const; + + /** + * Removes the elements in the range [first, last). + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + iterator erase(iterator first, iterator last) const; + + /** + * Removes the last element of the container. + * Calling pop_back on an empty container is undefined. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + void pop_back() const; + + /** + * Resizes the container to contain count elements. + * If the current size is less than count, additional default-inserted elements are appended. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + void resize(size_type count) const; + + /** + * Resizes the container to contain count elements. + * If the current size is less than count, additional copies of value are appended. + * May invalidate any references, pointers, or iterators referring to contained elements. Any past-the-end iterators may also be invalidated. + */ + void resize(size_type count, const T& value) const; + + /** + * Value equality comparison. This function implements Python-like semantics for + * equality: two lists with the same identity (e.g. same pointer) trivially + * compare equal, otherwise each element is compared for equality. + */ + template + friend bool operator==(const List& lhs, const List& rhs); + + template + friend bool operator!=(const List& lhs, const List& rhs); + + /** + * Identity comparison. Returns true if and only if `rhs` represents the same + * List object as `this`. + */ + bool is(const List& rhs) const; + + std::vector vec() const; + + /** + * Returns the number of Lists currently pointing to this same list. + * If this is the only instance pointing to this list, returns 1. + */ + // TODO Test use_count + size_t use_count() const; + + TypePtr elementType() const; + + // See [unsafe set type] for why this exists. + void unsafeSetElementType(TypePtr t); + +private: + explicit List(c10::intrusive_ptr&& elements); + explicit List(const c10::intrusive_ptr& elements); + friend struct IValue; + template friend List impl::toTypedList(List); + template friend List impl::toList(List&&); + template friend List impl::toList(const List&); + friend const IValue* impl::ptr_to_first_element(const List& list); +}; + +namespace impl { +// GenericList is how IValue stores lists. It is, however, not part of the +// public API. Kernels should use Lists with concrete types instead +// (maybe except for some internal prim ops). +using GenericList = List; + +} +} + +namespace torch { + template using List = c10::List; +} + +#include // IWYU pragma: keep diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/List_inl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/List_inl.h new file mode 100644 index 0000000000000000000000000000000000000000..96f78faea22d3f57a3f01b8fb46ddaef66e8ca25 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/List_inl.h @@ -0,0 +1,353 @@ +#pragma once + +#include +#include + +namespace c10 { + +template decltype(auto) getTypePtr(); +std::string toString(const Type& type); + +template +List::List(c10::intrusive_ptr&& elements) +: impl_(std::move(elements)) {} + +template +List::List(const c10::intrusive_ptr& elements) +: impl_(elements) {} + +template +List::List() +: List(make_intrusive( + typename c10::detail::ListImpl::list_type(), + getTypePtr())) { + static_assert(!std::is_same_v, "This constructor is not valid for List. Please use c10::impl::GenericList(elementType) instead."); +} + +template +List::List(ArrayRef values) +: List(make_intrusive( + typename c10::detail::ListImpl::list_type(), + getTypePtr())) { + static_assert(!std::is_same_v, "This constructor is not valid for List. Please use c10::impl::GenericList(elementType)."); + impl_->list.reserve(values.size()); + for (const T& element : values) { + impl_->list.push_back(element); + } +} + +template +List::List(std::initializer_list initial_values) +: List(ArrayRef(initial_values)) { + static_assert(!std::is_same_v, "This constructor is not valid for List. Please use c10::impl::GenericList(elementType)."); +} + +template +List::List(TypePtr elementType) +: List(make_intrusive( + typename c10::detail::ListImpl::list_type(), + std::move(elementType))) { + static_assert(std::is_same_v || std::is_same_v>, + "This constructor is only valid for c10::impl::GenericList or List."); +} + +namespace impl { +template +List toTypedList(impl::GenericList list) { + // If there's other instances of the list (i.e. list.use_count() > 1), then we have to be invariant + // because upcasting would allow people to add types into the new list that would break the old list. + // However, if there aren't any other instances of this list (i.e. list.use_count() == 1), then we can + // allow upcasting. This can be a perf improvement since we can cast List to List> + // without having to copy it. This is also used to provide backwards compatibility with some old models + // that serialized the index arguments to aten::index, aten::index_put, aten::index_put_ and aten::index_put_impl_ + // as List before we changed that argument to be List>. When deserializing, we + // have list.use_count() == 1 and can deserialize the List directly as List>. + TORCH_CHECK(*list.impl_->elementType == *getTypePtr() + || (list.use_count() == 1 && list.impl_->elementType->isSubtypeOf(*getTypePtr())) + , "Tried to cast a List<", toString(*list.impl_->elementType), "> to a List<", toString(*getTypePtr()), ">. Types mismatch."); + return List(std::move(list.impl_)); +} + +template +impl::GenericList toList(List&& list) { + return GenericList(std::move(list.impl_)); +} +template +impl::GenericList toList(const List& list) { + return GenericList(list.impl_); +} +} + +template +List List::copy() const { + return List(impl_->copy()); +} + +namespace detail { + template + T list_element_to(T element) { + return element; + } + template + T list_element_to(const IValue& element) { + return element.template to(); + } + template + T list_element_to(IValue&& element) { + return std::move(element).template to(); + } + template + struct ListElementFrom { + static IValue from(const T& element) { + return element; + } + static IValue from(T&& element) { + return std::move(element); + } + }; + template<> + struct ListElementFrom { + static const IValue& from(const IValue& element) { + return element; + } + static IValue&& from(IValue&& element) { + return std::move(element); + } + }; +} + +namespace impl { + +template +ListElementReference::operator std::conditional_t< + std::is_reference_v::type>, + const T&, + T>() const { + return iterator_->template to(); +} + +template +ListElementReference& ListElementReference::operator=(T&& new_value) && { + *iterator_ = c10::detail::ListElementFrom::from(std::move(new_value)); + return *this; +} + +template +ListElementReference& ListElementReference::operator=(const T& new_value) && { + *iterator_ = c10::detail::ListElementFrom::from(new_value); + return *this; +} + +template +ListElementReference& ListElementReference::operator=(ListElementReference&& rhs) && noexcept { + *iterator_ = *rhs.iterator_; + return *this; +} + +template +void swap(ListElementReference&& lhs, ListElementReference&& rhs) noexcept { + std::swap(*lhs.iterator_, *rhs.iterator_); +} + +template +bool operator==(const ListElementReference& lhs, const T& rhs) { + const T& lhs_tmp = lhs; + return lhs_tmp == rhs; +} + +template +inline bool operator==(const T& lhs, const ListElementReference& rhs) { + return rhs == lhs; +} + +template +inline typename ListElementConstReferenceTraits::const_reference +list_element_to_const_ref(const IValue& element) { + return element.template to(); +} + +template<> +inline typename ListElementConstReferenceTraits>::const_reference +list_element_to_const_ref>(const IValue& element) { + return element.toOptionalStringRef(); +} + +} // namespace impl + +template +void List::set(size_type pos, const value_type& value) const { + impl_->list.at(pos) = c10::detail::ListElementFrom::from(value); +} + +template +void List::set(size_type pos, value_type&& value) const { + impl_->list.at(pos) = c10::detail::ListElementFrom::from(std::move(value)); +} + +template +typename List::internal_const_reference_type List::get(size_type pos) const { + return operator[](pos); +} + +template +typename List::internal_const_reference_type List::operator[](size_type pos) const { + return c10::impl::list_element_to_const_ref(impl_->list.at(pos)); +} + +template +typename List::internal_reference_type List::operator[](size_type pos) { + static_cast(impl_->list.at(pos)); // Throw the exception if it is out of range. + return {impl_->list.begin() + static_castlist)::difference_type>(pos)}; +} + +template +typename List::value_type List::extract(size_type pos) const { + auto& elem = impl_->list.at(pos); + auto result = c10::detail::list_element_to(std::move(elem)); + // Reset the list element to a T() instead of None to keep it correctly typed + elem = c10::detail::ListElementFrom::from(T{}); + return result; +} + +template +typename List::iterator List::begin() const { + return iterator(impl_->list.begin()); +} + +template +typename List::iterator List::end() const { + return iterator(impl_->list.end()); +} + +template +bool List::empty() const { + return impl_->list.empty(); +} + +template +typename List::size_type List::size() const { + return impl_->list.size(); +} + +template +void List::reserve(size_type new_cap) const { + impl_->list.reserve(new_cap); +} + +template +void List::clear() const { + impl_->list.clear(); +} + +template +typename List::iterator List::insert(iterator pos, const T& value) const { + return iterator { impl_->list.insert(pos.iterator_, c10::detail::ListElementFrom::from(value)) }; +} + +template +typename List::iterator List::insert(iterator pos, T&& value) const { + return iterator { impl_->list.insert(pos.iterator_, c10::detail::ListElementFrom::from(std::move(value))) }; +} + +template +template +typename List::iterator List::emplace(iterator pos, Args&&... value) const { + // TODO Use list_element_from? + return iterator { impl_->list.emplace(pos.iterator_, std::forward(value)...) }; +} + +template +void List::push_back(const T& value) const { + impl_->list.push_back(c10::detail::ListElementFrom::from(value)); +} + +template +void List::push_back(T&& value) const { + impl_->list.push_back(c10::detail::ListElementFrom::from(std::move(value))); +} + +template +void List::append(List b) const { + if (b.use_count() == 1) { + impl_->list.insert(impl_->list.end(), make_move_iterator(b.impl_->list.begin()), make_move_iterator(b.impl_->list.end())); + } else { + impl_->list.insert(impl_->list.end(), b.impl_->list.begin(), b.impl_->list.end()); + } +} + +template +template +void List::emplace_back(Args&&... args) const { + // TODO Use list_element_from? + impl_->list.push_back(T(std::forward(args)...)); +} + +template +typename List::iterator List::erase(iterator pos) const { + return iterator { impl_->list.erase(pos.iterator_) }; +} + +template +typename List::iterator List::erase(iterator first, iterator last) const { + return iterator { impl_->list.erase(first.iterator_, last.iterator_) }; +} + +template +void List::pop_back() const { + impl_->list.pop_back(); +} + +template +void List::resize(size_type count) const { + impl_->list.resize(count, T{}); +} + +template +void List::resize(size_type count, const T& value) const { + impl_->list.resize(count, value); +} + +template +bool operator==(const List& lhs, const List& rhs) { + // Lists with the same identity trivially compare equal. + if (lhs.impl_ == rhs.impl_) { + return true; + } + + // Otherwise, just compare values directly. + return *lhs.impl_ == *rhs.impl_; +} + +template +bool operator!=(const List& lhs, const List& rhs) { + return !(lhs == rhs); +} + +template +bool List::is(const List& rhs) const { + return this->impl_ == rhs.impl_; +} + +template +std::vector List::vec() const { + std::vector result(begin(), end()); + return result; +} + +template +size_t List::use_count() const { + return impl_.use_count(); +} + +template +TypePtr List::elementType() const { + return impl_->elementType; +} + +template +void List::unsafeSetElementType(TypePtr t) { + impl_->elementType = std::move(t); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/MT19937RNGEngine.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/MT19937RNGEngine.h new file mode 100644 index 0000000000000000000000000000000000000000..5bcc4c0c15d967aedc4841052c89d0a18abe6fcd --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/MT19937RNGEngine.h @@ -0,0 +1,194 @@ +#pragma once + +#include + +// define constants like M_PI and C keywords for MSVC +#ifdef _MSC_VER +#ifndef _USE_MATH_DEFINES +#define _USE_MATH_DEFINES +#endif +#include +#endif + +#include +#include +#include + +namespace at { + +constexpr int MERSENNE_STATE_N = 624; +constexpr int MERSENNE_STATE_M = 397; +constexpr uint32_t MATRIX_A = 0x9908b0df; +constexpr uint32_t UMASK = 0x80000000; +constexpr uint32_t LMASK = 0x7fffffff; + +/** + * Note [Mt19937 Engine implementation] + * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + * Originally implemented in: + * http://www.math.sci.hiroshima-u.ac.jp/~m-mat/MT/MT2002/CODES/MTARCOK/mt19937ar-cok.c + * and modified with C++ constructs. Moreover the state array of the engine + * has been modified to hold 32 bit uints instead of 64 bits. + * + * Note that we reimplemented mt19937 instead of using std::mt19937 because, + * at::mt19937 turns out to be faster in the pytorch codebase. PyTorch builds with -O2 + * by default and following are the benchmark numbers (benchmark code can be found at + * https://github.com/syed-ahmed/benchmark-rngs): + * + * with -O2 + * Time to get 100000000 philox randoms with at::uniform_real_distribution = 0.462759s + * Time to get 100000000 at::mt19937 randoms with at::uniform_real_distribution = 0.39628s + * Time to get 100000000 std::mt19937 randoms with std::uniform_real_distribution = 0.352087s + * Time to get 100000000 std::mt19937 randoms with at::uniform_real_distribution = 0.419454s + * + * std::mt19937 is faster when used in conjunction with std::uniform_real_distribution, + * however we can't use std::uniform_real_distribution because of this bug: + * http://open-std.org/JTC1/SC22/WG21/docs/lwg-active.html#2524. Plus, even if we used + * std::uniform_real_distribution and filtered out the 1's, it is a different algorithm + * than what's in pytorch currently and that messes up the tests in tests_distributions.py. + * The other option, using std::mt19937 with at::uniform_real_distribution is a tad bit slower + * than at::mt19937 with at::uniform_real_distribution and hence, we went with the latter. + * + * Copyright notice: + * A C-program for MT19937, with initialization improved 2002/2/10. + * Coded by Takuji Nishimura and Makoto Matsumoto. + * This is a faster version by taking Shawn Cokus's optimization, + * Matthe Bellew's simplification, Isaku Wada's real version. + * + * Before using, initialize the state by using init_genrand(seed) + * or init_by_array(init_key, key_length). + * + * Copyright (C) 1997 - 2002, Makoto Matsumoto and Takuji Nishimura, + * All rights reserved. + * + * Redistribution and use in source and binary forms, with or without + * modification, are permitted provided that the following conditions + * are met: + * + * 1. Redistributions of source code must retain the above copyright + * notice, this list of conditions and the following disclaimer. + * + * 2. Redistributions in binary form must reproduce the above copyright + * notice, this list of conditions and the following disclaimer in the + * documentation and/or other materials provided with the distribution. + * + * 3. The names of its contributors may not be used to endorse or promote + * products derived from this software without specific prior written + * permission. + * + * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS + * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT + * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR + * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR + * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, + * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, + * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR + * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF + * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING + * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS + * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + * + * + * Any feedback is very welcome. + * http://www.math.sci.hiroshima-u.ac.jp/~m-mat/MT/emt.html + * email: m-mat @ math.sci.hiroshima-u.ac.jp (remove space) + */ + +/** + * mt19937_data_pod is used to get POD data in and out + * of mt19937_engine. Used in torch.get_rng_state and + * torch.set_rng_state functions. + */ +struct mt19937_data_pod { + uint64_t seed_; + int left_; + bool seeded_; + uint32_t next_; + std::array state_; +}; + +class mt19937_engine { +public: + + // NOLINTNEXTLINE(cppcoreguidelines-pro-type-member-init) + inline explicit mt19937_engine(uint64_t seed = 5489) { + init_with_uint32(seed); + } + + inline mt19937_data_pod data() const { + return data_; + } + + inline void set_data(const mt19937_data_pod& data) { + data_ = data; + } + + inline uint64_t seed() const { + return data_.seed_; + } + + inline bool is_valid() { + if ((data_.seeded_ == true) + && (data_.left_ > 0 && data_.left_ <= MERSENNE_STATE_N) + && (data_.next_ <= MERSENNE_STATE_N)) { + return true; + } + return false; + } + + inline uint32_t operator()() { + if (--(data_.left_) == 0) { + next_state(); + } + uint32_t y = *(data_.state_.data() + data_.next_++); + y ^= (y >> 11); + y ^= (y << 7) & 0x9d2c5680; + y ^= (y << 15) & 0xefc60000; + y ^= (y >> 18); + + return y; + } + +private: + mt19937_data_pod data_; + + inline void init_with_uint32(uint64_t seed) { + data_.seed_ = seed; + data_.seeded_ = true; + data_.state_[0] = seed & 0xffffffff; + for (const auto j : c10::irange(1, MERSENNE_STATE_N)) { + data_.state_[j] = (1812433253 * (data_.state_[j-1] ^ (data_.state_[j-1] >> 30)) + j); + } + data_.left_ = 1; + data_.next_ = 0; + } + + inline uint32_t mix_bits(uint32_t u, uint32_t v) { + return (u & UMASK) | (v & LMASK); + } + + inline uint32_t twist(uint32_t u, uint32_t v) { + return (mix_bits(u,v) >> 1) ^ (v & 1 ? MATRIX_A : 0); + } + + inline void next_state() { + uint32_t* p = data_.state_.data(); + data_.left_ = MERSENNE_STATE_N; + data_.next_ = 0; + + for(int j = MERSENNE_STATE_N - MERSENNE_STATE_M + 1; --j; p++) { + *p = p[MERSENNE_STATE_M] ^ twist(p[0], p[1]); + } + + for(int j = MERSENNE_STATE_M; --j; p++) { + *p = p[MERSENNE_STATE_M - MERSENNE_STATE_N] ^ twist(p[0], p[1]); + } + + *p = p[MERSENNE_STATE_M - MERSENNE_STATE_N] ^ twist(p[0], data_.state_[0]); + } + +}; + +typedef mt19937_engine mt19937; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/NamedTensor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/NamedTensor.h new file mode 100644 index 0000000000000000000000000000000000000000..81998e160185aba0561404e637ff20a2d18d4869 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/NamedTensor.h @@ -0,0 +1,143 @@ +#pragma once + +#include +#include + +namespace at { + +class TensorBase; + +// XXX: This file exists because TensorImpl is in c10, but Dimname is in ATen. +// Due to the c10/ATen library split, TensorImpl cannot depend on Dimname, +// so we have a couple of workarounds. +// +// In the long term, we'll move Dimname to c10 and everything in this file +// can be refactored out. The main blocker for that is that "c10::Symbol" +// actually exists outside of c10 and needs to be moved in. + +// TensorImpl has a unique_ptr field. +// XXX: Ideally we would just put std::optional> into TensorImpl. +// +// This class has an important invariant: there must be at least ONE +// non-wildcard +struct TORCH_API NamedTensorMeta final : public c10::NamedTensorMetaInterface { + // This enum is to remind people that the invariant on constructors is that + // the list of dimnames must have at least one non-wildcard + enum HAS_NON_WILDCARD { + HasNonWildcard + }; + + explicit NamedTensorMeta(HAS_NON_WILDCARD, DimnameList names) + : names_(names.vec()) { + check_invariants(); + } + explicit NamedTensorMeta(HAS_NON_WILDCARD, std::vector&& names) + : names_(std::move(names)) { + check_invariants(); + } + + std::unique_ptr clone() const override { + return std::make_unique(HasNonWildcard, names_); + } + + DimnameList names() const { return names_; } + + // Used for an assertion in TensorImpl.h + int64_t slow_dim() const override { + return static_cast(names_.size()); + } + + void check_invariants() const { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + std::any_of(names_.begin(), names_.end(), [](const Dimname& n) { return !n.isWildcard(); })); + } + + void set_names(HAS_NON_WILDCARD, DimnameList new_names) { + TORCH_INTERNAL_ASSERT(new_names.size() == names_.size()); + std::copy(new_names.begin(), new_names.end(), names_.begin()); + check_invariants(); + } + + void set_names(HAS_NON_WILDCARD, std::vector&& new_names) { + TORCH_INTERNAL_ASSERT(new_names.size() == names_.size()); + names_ = std::move(new_names); + check_invariants(); + } + + // INVARIANT: at least one Dimname is non-WILDCARD + std::vector names_; +}; + +// When NamesMode is disabled, then all operations ignore tensors' names fields. +// Concretely speaking, all tensors are treated as having nullopt names. +struct TORCH_API NamesMode { + static bool is_enabled(); + static void set_enabled(bool enabled); +}; + + +// A RAII, thread local (!) guard that enables or disables names upon +// construction, and sets it back to the original value upon destruction. +struct TORCH_API NoNamesGuard { + NoNamesGuard() : prev_mode(NamesMode::is_enabled()) { + NamesMode::set_enabled(false); + } + NoNamesGuard(const NoNamesGuard&) = delete; + NoNamesGuard(NoNamesGuard&&) = delete; + NoNamesGuard& operator=(const NoNamesGuard&) = delete; + NoNamesGuard& operator=(NoNamesGuard&&) = delete; + ~NoNamesGuard() { + if (initialized) { + reset(); + } + } + void reset() { + TORCH_INTERNAL_ASSERT(initialized); + NamesMode::set_enabled(prev_mode); + } + private: + bool prev_mode; + bool initialized{true}; +}; + +void check_names_valid_for(const TensorBase& tensor, DimnameList names); +void check_names_valid_for(size_t tensor_dim, DimnameList names); + +// Sets the names of `tensor` to be `names`. +TORCH_API const TensorBase& internal_set_names_inplace(const TensorBase& tensor, std::optional names); +TORCH_API const TensorBase& internal_set_names_inplace(const TensorBase& tensor, std::vector&& names, bool validate_names); + +constexpr size_t kMaxNamedTensorDim = 64; + +DimnameList default_names(size_t len); + +namespace impl { + +// Some helper functions on TensorImpl. Useful for working with names in TH. +// XXX: Ideally these would exist as methods on TensorImpl +TORCH_API void internal_set_names_inplace(TensorImpl* impl, std::optional names, bool validate_names); +TORCH_API void internal_set_names_inplace(TensorImpl* impl, std::vector&& names, bool validate_names); + +void check_names_valid_for(TensorImpl* impl, DimnameList names); + +// Returns true if the tensor's names exist and are not all 'None'. +// Returns false if the tensor's names don't exist (were not allocated), +// or if all names are 'None'. +// We treat not-allocated-names the same as allocated names that are all 'None'. +TORCH_API bool has_names(const TensorImpl* impl); + +// Returns the names of the tensor's dimensions. +// Unnamed tensors are treated as having 'None' in all dimension; this method +// would return a DimnameList of all 'None's for an unnamed tensor. +TORCH_API DimnameList get_names(const TensorImpl* impl); + +// This is more of an implementation detail; one should use impl::get_names / +// Tensor::names() whenever possible because it provides a cleaner API. +// Returns the names of the tensor if they have been allocated; returns nullopt +// instead if the haven't been. The names of a tensor are not allocated if a +// tensor is constructed with names=None. +TORCH_API std::optional get_opt_names(const TensorImpl* impl); + +} // namespace impl + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/NestedIntSymNodeImpl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/NestedIntSymNodeImpl.h new file mode 100644 index 0000000000000000000000000000000000000000..23ae67f25cc17242bad288c60f7bd3e3a2af412a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/NestedIntSymNodeImpl.h @@ -0,0 +1,187 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include + +namespace c10 { + +// The motivating usecase for this is to represent the ragged size structure +// of a jagged tensor [B, [s_0, s_1, s_2], D] as a single integer j0. This +// allows us to simply return [B, j0, D] if someone queries for the size of our +// tensor. +// +// Morally we define comparison between two nested ints to return true if +// that comparison holds for all corresponding elements of the arrays they +// represent. Comparison between a nested int and a plain int is defined +// similarly. +// +// To simulate this desired behavior but also avoid the O(N) cost of checking, +// we associate each raggedness pattern with an integer "id" that can be used as +// a proxy to evaluate equality. We also constrain the range of values for this +// as to enable inequality checks. +// +// We also support a positive integer scalar "coeff" that is used for computing +// strides. For example given, a [B, j0, D] tensor, it can be strided in two +// different ways: [D * j0, D, 1] and [j0, 1, sum(j0)]. The coeff is used to +// differentiate the two cases. +// +// During tracing the strides of the outputs need to be a function of the size +// and strides of the inputs so it is important that NestedIntSymNode itself is +// able to express this. +class TORCH_API NestedIntSymNodeImpl : public SymNodeImpl { + public: + // CAUTION: you should probably not be constructing these directly; please + // the higher-level API in python instead (TODO: actually introduce that). + explicit NestedIntSymNodeImpl(int64_t val, int64_t coeff) + : val_(val), coeff_(coeff) {} + + bool bool_() override { + return false; + } + + bool is_int() override { + return true; + } + + bool is_float() override { + return false; + } + + bool is_bool() override { + return false; + } + + bool is_nested_int() const override { + return true; + } + + bool has_hint() override { + return true; + } + + c10::SymNode wrap_int(int64_t num) override { + return SymNode(c10::make_intrusive>(num)); + } + + int64_t guard_int(const char* file, int64_t line) override { + TORCH_CHECK(false); + } + + double guard_float(const char* file, int64_t line) override { + TORCH_CHECK(false, "not a float"); + } + + bool guard_bool(const char* file, int64_t line) override { + TORCH_CHECK(false, "not a bool"); + } + + int64_t int_() override { + TORCH_CHECK(false); + } + + std::string str() override { + if (coeff_ == 1) { + return "j" + std::to_string(val_); + } + return std::to_string(coeff_) + "*j" + std::to_string(val_); + } + + // NOTE [ Inequalities with nested int ] + // + // The semantics of nested int when it comes to relations is that it is + // treated as integer known to be within a certain range, + // + // j0 \in [2, int64_t::max] + // + // allowing us to answer queries like j0 >= 1 (True), and j0 == 0 (False). + // This is a useful default range for the raggedness pattern of a jagged + // tensor (1) since sizes are non-negative, and (2) we need to get past 0/1 + // specialization checks. + // + // [ Indeterminate inequalities error out ] + // + // Given the semantic defined above, certain relations like j0 < 3 are thus + // indeterminable. In our impl today, evaluating such relations error + // + // It may seem convenient to just define indeterminate relations to return + // False, but the implementation we maintain in parallel using sympy does not + // allow this. + // + // Sympy only allows overriding of Ge. The other relations (Lt, Gt, Le) are, + // by consequence, all derived from Ge e.g., Lt(a, b) := !Ge(a, b). This + // would mean that means that if we define the indeterminate j0 >= 3 to be + // False, the also indeterminate j0 < 3 will be evaluated to be True! + // + // [ Coefficient are assumed positive ] + // + // For the purpose of computing inequalities, we consider the coefficient of + // the nested int to be a positive integer. + // + // Thus, no modifications are needed to the logic since + // j0 >= k implies coeff * j0 >= k + // + c10::SymNode eq(const c10::SymNode& other) override; + c10::SymNode ne(const c10::SymNode& other) override; + c10::SymNode ge(const c10::SymNode& other) override; + c10::SymNode gt(const c10::SymNode& other) override; + c10::SymNode lt(const c10::SymNode& other) override; + c10::SymNode le(const c10::SymNode& other) override; + c10::SymNode mul(const c10::SymNode& other) override; + + std::optional nested_int() override { + return val_; + } + + std::optional nested_int_coeff() override { + return coeff_; + } + + bool is_symbolic() override { + return false; + } + + c10::SymNode clone() override; + +#define DEFINE_BINARY_NOT_SUPPORTED(name) \ + c10::SymNode name(const c10::SymNode& other) override { \ + TORCH_CHECK(false, #name " not supported by NestedIntSymNode"); \ + } + + DEFINE_BINARY_NOT_SUPPORTED(add) + DEFINE_BINARY_NOT_SUPPORTED(sub) + DEFINE_BINARY_NOT_SUPPORTED(truediv) + DEFINE_BINARY_NOT_SUPPORTED(pow) + DEFINE_BINARY_NOT_SUPPORTED(floordiv) + DEFINE_BINARY_NOT_SUPPORTED(mod) + DEFINE_BINARY_NOT_SUPPORTED(sym_min) + DEFINE_BINARY_NOT_SUPPORTED(sym_max) + DEFINE_BINARY_NOT_SUPPORTED(sym_and) + DEFINE_BINARY_NOT_SUPPORTED(sym_or) + +#undef DEFINE_BINARY_NOT_SUPPORTED + +#define DEFINE_NOT_SUPPORTED(name) \ + c10::SymNode name() override { \ + TORCH_CHECK(false, #name " is not supported by NestedIntSymNode"); \ + } + + DEFINE_NOT_SUPPORTED(sym_not) + DEFINE_NOT_SUPPORTED(ceil) + DEFINE_NOT_SUPPORTED(floor) + DEFINE_NOT_SUPPORTED(neg) + DEFINE_NOT_SUPPORTED(sym_float) + +#undef DEFINE_NOT_SUPPORTED + + private: + int64_t val_; + int64_t coeff_; +}; + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/PhiloxRNGEngine.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/PhiloxRNGEngine.h new file mode 100644 index 0000000000000000000000000000000000000000..413055d3fad6555582e9b7ccf80e38387a52d535 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/PhiloxRNGEngine.h @@ -0,0 +1,240 @@ +#pragma once + +// define constants like M_PI and C keywords for MSVC +#ifdef _MSC_VER +#define _USE_MATH_DEFINES +#include +#endif + + +#ifdef __CUDACC__ +#include +#endif + +#include +#include +#include +#include + +namespace at { + +// typedefs for holding vector data +namespace detail { + +typedef std::array UINT4; +typedef std::array UINT2; +typedef std::array DOUBLE2; +typedef std::array FLOAT2; + +} // namespace detail + +/** + * Note [Philox Engine implementation] + * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + * Originally implemented in PyTorch's fusion compiler + * Refer to: http://www.thesalmons.org/john/random123/papers/random123sc11.pdf + * for details regarding the engine. + * + * Note that currently this implementation of the philox engine is not used + * anywhere except for tests in cpu_generator_test.cpp. However, this engine + * will replace curandStatePhilox4_32_10_t in the future. + * + * The philox engine takes a seed value, a subsequeunce + * for starting the generation and an offset for the subsequence. + * Think of this engine as an algorithm producing a huge array. We are + * parallelizing this array by partitioning the huge array and assigning + * a thread index to each partition. In other words, each seed value + * (there are 2^64 possible seed values) gives a sub array of size + * 2^128 (each element in that array is a 128 bit number). Reasoning + * behind the array being of size 2^128 is, there are 2^64 possible + * thread index value and there is an array of size 2^64 for each of + * those thread index. Hence 2^64 * 2^64 = 2^128 for each seed value. + * + * In short, this generator can produce 2^64 (seed values) * 2^128 (number + * of elements in an array given by a seed value) = 2^192 values. + * + * Arguments: + * seed: Seed values could be any number from 0 to 2^64-1. + * subsequence: Subsequence is just the cuda thread indexing with: + * - blockIdx.x * blockDim.x + threadIdx.x + * offset: The offset variable in PhiloxEngine decides how many 128-bit + * random numbers to skip (i.e. how many groups of 4, 32-bit numbers to skip) + * and hence really decides the total number of randoms that can be achieved + * for the given subsequence. + */ + +class philox_engine { +public: + + // NOLINTNEXTLINE(cppcoreguidelines-pro-type-member-init) + C10_HOST_DEVICE inline explicit philox_engine(uint64_t seed = 67280421310721, + uint64_t subsequence = 0, + uint64_t offset = 0) { + + reset_state(seed, subsequence); + incr_n(offset); + } + + C10_HOST_DEVICE inline void reset_state(uint64_t seed = 67280421310721, + uint64_t subsequence = 0) { + key_[0] = static_cast(seed); + key_[1] = static_cast(seed >> 32); + counter_ = detail::UINT4{}; + counter_[2] = static_cast(subsequence); + counter_[3] = static_cast(subsequence >> 32); + STATE = 0; + } + + /** + * Set the offset field of Philox Generator to the desired offset. + */ + C10_HOST_DEVICE inline void set_offset(uint64_t offset) { + counter_[0] = static_cast(offset); + counter_[1] = static_cast(offset >> 32); + } + + /** + * Gets the current offset of the Philox Generator. + */ + C10_HOST_DEVICE uint64_t get_offset() const { + uint64_t lo = static_cast(counter_[0]); + uint64_t hi = static_cast(counter_[1]) << 32; + return lo | hi; + } + + /** + * Produces a unique 32-bit pseudo random number on every invocation. Bookeeps state to avoid waste. + */ + C10_HOST_DEVICE inline uint32_t operator()(int32_t n_rounds = 10) { // 10 here to preserve back-compat behavior + if(STATE == 0) { + detail::UINT4 counter = counter_; + detail::UINT2 key = key_; + output_ = rand(counter, key, n_rounds); + incr(); + } + uint32_t ret = output_[static_cast(STATE)]; + STATE = (STATE + 1) & 3; + return ret; + } + + inline float randn(uint32_t n_rounds) { + #ifdef __CUDA_ARCH__ + AT_ASSERT(false, "Unsupported invocation of randn on CUDA"); + #endif + if(STATE == 0) { + detail::UINT4 counter = counter_; + detail::UINT2 key = key_; + output_ = rand(counter, key, n_rounds); + incr(); + } + // TODO(min-jean-cho) change to Polar method, a more efficient version of Box-Muller method + // TODO(voz) We use std:: below, and thus need a separate impl for CUDA. + float u1 = 1 - uint32_to_uniform_float(output_[0]); // uint32_to_uniform_float returns [0,1), we need (0,1] to avoid passing 0 to log. + float u2 = 1 - uint32_to_uniform_float(output_[1]); + return static_cast(std::sqrt(-2.0 * std::log(u1)) * std::cos(2.0 * M_PI * u2)); + } + + /** + * Function that Skips N 128 bit numbers in a subsequence + */ + C10_HOST_DEVICE inline void incr_n(uint64_t n) { + uint32_t nlo = static_cast(n); + uint32_t nhi = static_cast(n >> 32); + counter_[0] += nlo; + // if overflow in x has occurred, carry over to nhi + if (counter_[0] < nlo) { + nhi++; + // if overflow in nhi has occurred during carry over, + // propagate that overflow to y and exit to increment z + // otherwise return + counter_[1] += nhi; + if(nhi != 0) { + if (nhi <= counter_[1]) { + return; + } + } + } else { + // if overflow in y has occurred during addition, + // exit to increment z + // otherwise return + counter_[1] += nhi; + if (nhi <= counter_[1]) { + return; + } + } + if (++counter_[2]) + return; + ++counter_[3]; + } + + /** + * Function that Skips one 128 bit number in a subsequence + */ + C10_HOST_DEVICE inline void incr() { + if (++counter_[0]) + return; + if (++counter_[1]) + return; + if (++counter_[2]) { + return; + } + ++counter_[3]; + } + +private: + detail::UINT4 counter_; + detail::UINT4 output_; + detail::UINT2 key_; + uint32_t STATE; + + C10_HOST_DEVICE inline uint32_t mulhilo32(uint32_t a, uint32_t b, + uint32_t *result_high) { + #ifdef __CUDA_ARCH__ + *result_high = __umulhi(a, b); + return a*b; + #else + const uint64_t product = static_cast(a) * b; + *result_high = static_cast(product >> 32); + return static_cast(product); + #endif + } + + C10_HOST_DEVICE inline detail::UINT4 single_round(detail::UINT4 ctr, detail::UINT2 in_key) { + uint32_t hi0 = 0; + uint32_t hi1 = 0; + uint32_t lo0 = mulhilo32(kPhiloxSA, ctr[0], &hi0); + uint32_t lo1 = mulhilo32(kPhiloxSB, ctr[2], &hi1); + detail::UINT4 ret; + ret[0] = hi1 ^ ctr[1] ^ in_key[0]; + ret[1] = lo1; + ret[2] = hi0 ^ ctr[3] ^ in_key[1]; + ret[3] = lo0; + return ret; + } + + C10_HOST_DEVICE constexpr float uint32_to_uniform_float(uint32_t value) { + // maximum value such that `MAX_INT * scale < 1.0` (with float rounding) + constexpr float scale = 4.6566127342e-10; + return static_cast(value & 0x7FFFFFFF) * scale; + } + + + + C10_HOST_DEVICE inline detail::UINT4 rand(detail::UINT4& counter, detail::UINT2& key, uint32_t n_rounds) { + for (uint32_t round = 0; round < (n_rounds - 1); round++) { + counter = single_round(counter, key); + key[0] += (kPhilox10A); key[1] += (kPhilox10B); + } + return single_round(counter, key); + } + + + static const uint32_t kPhilox10A = 0x9E3779B9; + static const uint32_t kPhilox10B = 0xBB67AE85; + static const uint32_t kPhiloxSA = 0xD2511F53; + static const uint32_t kPhiloxSB = 0xCD9E8D57; +}; + +typedef philox_engine Philox4_32; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/PythonFallbackKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/PythonFallbackKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..1d2b613166d3f308ea3114b0726a37ad113460a8 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/PythonFallbackKernel.h @@ -0,0 +1,35 @@ +#pragma once +#include + + +namespace at::impl { + +struct TORCH_API RestorePythonTLSSnapshot { + RestorePythonTLSSnapshot(); + RestorePythonTLSSnapshot(RestorePythonTLSSnapshot&& other) = delete; + RestorePythonTLSSnapshot(const RestorePythonTLSSnapshot&) = delete; + RestorePythonTLSSnapshot& operator=(const RestorePythonTLSSnapshot&) = delete; + RestorePythonTLSSnapshot& operator=(RestorePythonTLSSnapshot&&) = delete; + ~RestorePythonTLSSnapshot(); + +private: + c10::impl::LocalDispatchKeySet saved_; + c10::impl::ForceDispatchKeyGuard guard_; +}; + + +// RAII guard to make working with the above TLS safer. +struct TORCH_API MaybeSetTLSOnEntryGuard { +public: + MaybeSetTLSOnEntryGuard(); + MaybeSetTLSOnEntryGuard(MaybeSetTLSOnEntryGuard&& other) = delete; + MaybeSetTLSOnEntryGuard(const MaybeSetTLSOnEntryGuard&) = delete; + MaybeSetTLSOnEntryGuard& operator=(const MaybeSetTLSOnEntryGuard&) = delete; + MaybeSetTLSOnEntryGuard& operator=(MaybeSetTLSOnEntryGuard&&) = delete; + ~MaybeSetTLSOnEntryGuard(); + +private: + bool value_set_; +}; + +} // namespace at::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/PythonOpRegistrationTrampoline.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/PythonOpRegistrationTrampoline.h new file mode 100644 index 0000000000000000000000000000000000000000..bec323c7d25bf0143dae83edc3ac1da3efd8eb48 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/PythonOpRegistrationTrampoline.h @@ -0,0 +1,22 @@ +#pragma once + +#include + +// TODO: this can probably live in c10 + + +namespace at::impl { + +class TORCH_API PythonOpRegistrationTrampoline final { + static std::atomic interpreter_; + +public: + // Returns true if you successfully registered yourself (that means + // you are in the hot seat for doing the operator registrations!) + static bool registerInterpreter(c10::impl::PyInterpreter*); + + // Returns nullptr if no interpreter has been registered yet. + static c10::impl::PyInterpreter* getInterpreter(); +}; + +} // namespace at::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/QuantizerBase.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/QuantizerBase.h new file mode 100644 index 0000000000000000000000000000000000000000..a56ead7a30c69623f4c893a1c237a3f4fb617212 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/QuantizerBase.h @@ -0,0 +1,84 @@ +#pragma once + +#include +#include +#include + +namespace at { + +class Tensor; +struct QTensorImpl; +struct Quantizer; +using ConstQuantizerPtr = const c10::intrusive_ptr&; +using QuantizerPtr = c10::intrusive_ptr; + +/** + * Quantizer is the class for storing all the information + * that's necessary to perform quantize and dequantize + * operation. + * + * We might have different types of quantization schemes and this is + * the base class for all quantizers. + * + * QTensorImpl will hold a pointer to Quantizer so that we can support + * different quantization schemes on Tensor. + * + * For example, the most common quantization scheme, Affine Quantization, + * requires scale and zero_point as parameters, we'll store scale and zero_point + * inside the instance and we can use it to quantize a float Tensor or + * dequantize a quantized Tensor. + * + * When you add new types of leaf Quantizer class, please also + * make sure to add a corresponding QScheme enum since + * they should have one to one mapping. + * + * Note about intrusive_ptr: + * Quantized Tensor holds an intrusive_ptr to Quantizer, and multiple Tensor can + * share the same Quantizer. Quantizer should be immutable. + */ +struct TORCH_API Quantizer : public c10::intrusive_ptr_target { + // NOLINTNEXTLINE(cppcoreguidelines-avoid-const-or-ref-data-members) + const ScalarType scalar_type_; + explicit Quantizer(ScalarType scalar_type) : scalar_type_(scalar_type) {} + ~Quantizer() override = default; + + // Copied from torch/csrc/jit/ir/scope.h + QuantizerPtr intrusive_from_this() { + c10::raw::intrusive_ptr::incref(this); // we are creating a new pointer + // from a raw `this` pointer + // so we need to bump the refcount + // to account for this ownership + return c10::intrusive_ptr::reclaim(this); + } + + /** + * Each concrete Quantizer type should have a unique QScheme type. + */ + virtual QScheme qscheme() const = 0; + + ScalarType scalar_type() const { + return scalar_type_; + } + + /** + * quantize a float Tensor into a quantized Tensor. + */ + virtual Tensor quantize(const Tensor& t) = 0; + + /** + * dequantize a quantized Tensor into a float Tensor. + */ + virtual Tensor dequantize(const Tensor& t) = 0; + + /** + * dequantize a quantized Tensor into a float Tensor, out= variant + */ + virtual Tensor& dequantize_out(Tensor& out, const Tensor& t) = 0; + + /** + * Compare against `other` for equality. + */ + virtual bool equalTo(QuantizerPtr other) const = 0; +}; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Range.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Range.h new file mode 100644 index 0000000000000000000000000000000000000000..2bf6b2b73ac4d4c178ac0388e9b45e262e506b86 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Range.h @@ -0,0 +1,25 @@ +#pragma once + +#include +#include + +namespace at { + +struct Range { + Range(int64_t begin, int64_t end) + : begin(begin) + , end(end) {} + + int64_t size() const { return end - begin; } + + Range operator/(int64_t divisor) { + return Range(begin / divisor, end / divisor); + } + + int64_t begin; + int64_t end; +}; + +std::ostream& operator<<(std::ostream& out, const Range& range); + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Reduction.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Reduction.h new file mode 100644 index 0000000000000000000000000000000000000000..340e9f91ae8f7fd10919148d2632149f5642fd7d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Reduction.h @@ -0,0 +1,14 @@ +#pragma once + +namespace at::Reduction { + +// NB: Keep this in sync with Reduction class in torch/nn/_reduction.py +// These constants control the reduction behavior of loss functions. +// Ideally, this would be a scoped enum, but jit doesn't support that +enum Reduction { + None, // Do not reduce + Mean, // (Possibly weighted) mean of losses + Sum, // Sum losses + END +}; +} // namespace at::Reduction diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Scalar.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Scalar.h new file mode 100644 index 0000000000000000000000000000000000000000..a14b48f0120cbfc23c45db14dd363b0c88c59a2c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Scalar.h @@ -0,0 +1 @@ +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ScalarType.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ScalarType.h new file mode 100644 index 0000000000000000000000000000000000000000..eb30ee86f737a3544e727c42f72147fdb64a5e3b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ScalarType.h @@ -0,0 +1 @@ +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Tensor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Tensor.h new file mode 100644 index 0000000000000000000000000000000000000000..96ef0ee4d8636c4e2bc4b163dc7db235ab5fac2d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Tensor.h @@ -0,0 +1,98 @@ +#pragma once + +#include +#include + +namespace at { +// NOLINTNEXTLINE(cppcoreguidelines-special-member-functions) +class TORCH_API OptionalTensorRef { + public: + OptionalTensorRef() = default; + + ~OptionalTensorRef() { + ref_.unsafeReleaseTensorImpl(); + } + + OptionalTensorRef(const TensorBase& src) + : ref_(Tensor::unsafe_borrow_t{}, src) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(src.defined()); + } + + OptionalTensorRef(const OptionalTensorRef& rhs) + : ref_(Tensor::unsafe_borrow_t{}, rhs.ref_) {} + + OptionalTensorRef(OptionalTensorRef&& rhs) = default; + OptionalTensorRef& operator=(OptionalTensorRef rhs) { + std::swap(ref_, rhs.ref_); + return *this; + } + + bool has_value() const { + return ref_.defined(); + } + + const Tensor& getTensorRef() const & { + return ref_; + } + + const Tensor& operator*() const & { + return ref_; + } + + const Tensor* operator->() const & { + return &ref_; + } + + operator bool() const { + return ref_.defined(); + } + + private: + Tensor ref_; +}; + +// Use to convert a TensorBase (that may be undefined) to an at::Tensor +// without bumping refcount. +class TORCH_API TensorRef { + public: + ~TensorRef() { + ref_.unsafeReleaseTensorImpl(); + } + + TensorRef(const TensorBase& src) + : ref_(Tensor::unsafe_borrow_t{}, src) {} + TensorRef(TensorRef&& other) = default; + TensorRef(const TensorRef&) = default; + TensorRef& operator=(const TensorRef&) = default; + TensorRef& operator=(TensorRef&&) = default; + + const Tensor& operator*() const & { + return ref_; + } + private: + Tensor ref_; +}; + +template +auto Tensor::register_hook(T&& hook) const -> Tensor::hook_return_void_t { + // Return the grad argument in case of a hook with void return type to have an + // std::function with Tensor return type + static_assert(std::is_same_v, + "Expected hook to return void"); + return _register_hook([fn=std::forward(hook)](const TensorBase& grad_base) { + TensorRef grad(grad_base); + fn(*grad); + return Tensor(); + }); +} + +template +auto Tensor::register_hook(T&& hook) const -> Tensor::hook_return_var_t { + return _register_hook([fn=std::forward(hook)](const TensorBase& grad_base) { + TensorRef grad(grad_base); + Tensor ret = fn(*grad); + return TensorBase(std::move(ret)); + }); +} + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TensorAccessor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TensorAccessor.h new file mode 100644 index 0000000000000000000000000000000000000000..8cf57d2b646fe134d93aadd83bd96380b1242bb9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TensorAccessor.h @@ -0,0 +1,275 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at { + +// The PtrTraits argument to the TensorAccessor/GenericPackedTensorAccessor +// is used to enable the __restrict__ keyword/modifier for the data +// passed to cuda. +template +struct DefaultPtrTraits { + typedef T* PtrType; +}; + +#if defined(__CUDACC__) || defined(__HIPCC__) +template +struct RestrictPtrTraits { + typedef T* __restrict__ PtrType; +}; +#endif + +// TensorAccessorBase and TensorAccessor are used for both CPU and CUDA tensors. +// For CUDA tensors it is used in device code (only). This means that we restrict ourselves +// to functions and types available there (e.g. IntArrayRef isn't). + +// The PtrTraits argument is only relevant to cuda to support `__restrict__` pointers. +template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> +class TensorAccessorBase { +public: + typedef typename PtrTraits::PtrType PtrType; + + C10_HOST_DEVICE TensorAccessorBase( + PtrType data_, + const index_t* sizes_, + const index_t* strides_) + : data_(data_), sizes_(sizes_), strides_(strides_) {} + C10_HOST IntArrayRef sizes() const { + return IntArrayRef(sizes_,N); + } + C10_HOST IntArrayRef strides() const { + return IntArrayRef(strides_,N); + } + C10_HOST_DEVICE index_t stride(index_t i) const { + return strides_[i]; + } + C10_HOST_DEVICE index_t size(index_t i) const { + return sizes_[i]; + } + C10_HOST_DEVICE PtrType data() { + return data_; + } + C10_HOST_DEVICE const PtrType data() const { + return data_; + } +protected: + PtrType data_; + const index_t* sizes_; + const index_t* strides_; +}; + +// The `TensorAccessor` is typically instantiated for CPU `Tensor`s using +// `Tensor.accessor()`. +// For CUDA `Tensor`s, `GenericPackedTensorAccessor` is used on the host and only +// indexing on the device uses `TensorAccessor`s. +template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> +class TensorAccessor : public TensorAccessorBase { +public: + typedef typename PtrTraits::PtrType PtrType; + + C10_HOST_DEVICE TensorAccessor( + PtrType data_, + const index_t* sizes_, + const index_t* strides_) + : TensorAccessorBase(data_,sizes_,strides_) {} + + C10_HOST_DEVICE TensorAccessor operator[](index_t i) { + return TensorAccessor(this->data_ + this->strides_[0]*i,this->sizes_+1,this->strides_+1); + } + + C10_HOST_DEVICE const TensorAccessor operator[](index_t i) const { + return TensorAccessor(this->data_ + this->strides_[0]*i,this->sizes_+1,this->strides_+1); + } +}; + +template class PtrTraits, typename index_t> +class TensorAccessor : public TensorAccessorBase { +public: + typedef typename PtrTraits::PtrType PtrType; + + C10_HOST_DEVICE TensorAccessor( + PtrType data_, + const index_t* sizes_, + const index_t* strides_) + : TensorAccessorBase(data_,sizes_,strides_) {} + C10_HOST_DEVICE T & operator[](index_t i) { + // NOLINTNEXTLINE(clang-analyzer-core.NullDereference) + return this->data_[this->strides_[0]*i]; + } + C10_HOST_DEVICE const T & operator[](index_t i) const { + return this->data_[this->strides_[0]*i]; + } +}; + + +// GenericPackedTensorAccessorBase and GenericPackedTensorAccessor are used on for CUDA `Tensor`s on the host +// and as +// In contrast to `TensorAccessor`s, they copy the strides and sizes on instantiation (on the host) +// in order to transfer them on the device when calling kernels. +// On the device, indexing of multidimensional tensors gives to `TensorAccessor`s. +// Use RestrictPtrTraits as PtrTraits if you want the tensor's data pointer to be marked as __restrict__. +// Instantiation from data, sizes, strides is only needed on the host and std::copy isn't available +// on the device, so those functions are host only. +template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> +class GenericPackedTensorAccessorBase { +public: + typedef typename PtrTraits::PtrType PtrType; + C10_HOST GenericPackedTensorAccessorBase( + PtrType data_, + const index_t* sizes_, + const index_t* strides_) + : data_(data_) { + std::copy(sizes_, sizes_ + N, std::begin(this->sizes_)); + std::copy(strides_, strides_ + N, std::begin(this->strides_)); + } + + // if index_t is not int64_t, we want to have an int64_t constructor + template >> + C10_HOST GenericPackedTensorAccessorBase( + PtrType data_, + const source_index_t* sizes_, + const source_index_t* strides_) + : data_(data_) { + for (const auto i : c10::irange(N)) { + this->sizes_[i] = sizes_[i]; + this->strides_[i] = strides_[i]; + } + } + + C10_HOST_DEVICE index_t stride(index_t i) const { + return strides_[i]; + } + C10_HOST_DEVICE index_t size(index_t i) const { + return sizes_[i]; + } + C10_HOST_DEVICE PtrType data() { + return data_; + } + C10_HOST_DEVICE const PtrType data() const { + return data_; + } +protected: + PtrType data_; + // NOLINTNEXTLINE(*c-arrays*) + index_t sizes_[N]; + // NOLINTNEXTLINE(*c-arrays*) + index_t strides_[N]; + C10_HOST void bounds_check_(index_t i) const { + TORCH_CHECK_INDEX( + 0 <= i && i < index_t{N}, + "Index ", + i, + " is not within bounds of a tensor of dimension ", + N); + } +}; + +template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> +class GenericPackedTensorAccessor : public GenericPackedTensorAccessorBase { +public: + typedef typename PtrTraits::PtrType PtrType; + + C10_HOST GenericPackedTensorAccessor( + PtrType data_, + const index_t* sizes_, + const index_t* strides_) + : GenericPackedTensorAccessorBase(data_, sizes_, strides_) {} + + // if index_t is not int64_t, we want to have an int64_t constructor + template >> + C10_HOST GenericPackedTensorAccessor( + PtrType data_, + const source_index_t* sizes_, + const source_index_t* strides_) + : GenericPackedTensorAccessorBase(data_, sizes_, strides_) {} + + C10_DEVICE TensorAccessor operator[](index_t i) { + index_t* new_sizes = this->sizes_ + 1; + index_t* new_strides = this->strides_ + 1; + return TensorAccessor(this->data_ + this->strides_[0]*i, new_sizes, new_strides); + } + + C10_DEVICE const TensorAccessor operator[](index_t i) const { + const index_t* new_sizes = this->sizes_ + 1; + const index_t* new_strides = this->strides_ + 1; + return TensorAccessor(this->data_ + this->strides_[0]*i, new_sizes, new_strides); + } + + /// Returns a PackedTensorAccessor of the same dimension after transposing the + /// two dimensions given. Does not actually move elements; transposition is + /// made by permuting the size/stride arrays. If the dimensions are not valid, + /// asserts. + C10_HOST GenericPackedTensorAccessor transpose( + index_t dim1, + index_t dim2) const { + this->bounds_check_(dim1); + this->bounds_check_(dim2); + GenericPackedTensorAccessor result( + this->data_, this->sizes_, this->strides_); + std::swap(result.strides_[dim1], result.strides_[dim2]); + std::swap(result.sizes_[dim1], result.sizes_[dim2]); + return result; + } +}; + +template class PtrTraits, typename index_t> +class GenericPackedTensorAccessor : public GenericPackedTensorAccessorBase { +public: + typedef typename PtrTraits::PtrType PtrType; + C10_HOST GenericPackedTensorAccessor( + PtrType data_, + const index_t* sizes_, + const index_t* strides_) + : GenericPackedTensorAccessorBase(data_, sizes_, strides_) {} + + // if index_t is not int64_t, we want to have an int64_t constructor + template >> + C10_HOST GenericPackedTensorAccessor( + PtrType data_, + const source_index_t* sizes_, + const source_index_t* strides_) + : GenericPackedTensorAccessorBase(data_, sizes_, strides_) {} + + C10_DEVICE T & operator[](index_t i) { + return this->data_[this->strides_[0] * i]; + } + C10_DEVICE const T& operator[](index_t i) const { + return this->data_[this->strides_[0]*i]; + } + + // Same as in the general N-dimensional case, but note that in the + // 1-dimensional case the returned PackedTensorAccessor will always be an + // identical copy of the original + C10_HOST GenericPackedTensorAccessor transpose( + index_t dim1, + index_t dim2) const { + this->bounds_check_(dim1); + this->bounds_check_(dim2); + return GenericPackedTensorAccessor( + this->data_, this->sizes_, this->strides_); + } +}; + + +// Can't put this directly into the macro function args because of commas +#define AT_X GenericPackedTensorAccessor + +// Old name for `GenericPackedTensorAccessor` +template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> +C10_DEFINE_DEPRECATED_USING(PackedTensorAccessor, AT_X) + +#undef AT_X + +template class PtrTraits = DefaultPtrTraits> +using PackedTensorAccessor32 = GenericPackedTensorAccessor; + +template class PtrTraits = DefaultPtrTraits> +using PackedTensorAccessor64 = GenericPackedTensorAccessor; +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TensorBase.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TensorBase.h new file mode 100644 index 0000000000000000000000000000000000000000..8d300debebe3dea5d2dc258dfb16828c3880f2de --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TensorBase.h @@ -0,0 +1,1056 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include + +namespace c10 { +class Scalar; +} + +namespace torch::autograd { + +struct Node; + +} // namespace torch::autograd + +namespace at { + +class Tensor; +class TensorBase; + +// Convert Tensor to TensorBase without any need to include Tensor.h +TORCH_API const TensorBase& get_tensor_base(const Tensor& t); + +namespace impl { +inline bool variable_excluded_from_dispatch() { +#ifdef C10_MOBILE + // Please read the comment in `VariableFallbackKernel.cpp` about the background of this change. + return true; +#else + return c10::impl::tls_local_dispatch_key_set().excluded_.isSupersetOf(c10::autograd_dispatch_keyset); +#endif +} + +} + +// NOTE: [Tensor vs. TensorBase] +// +// Tensor, being the central data structure in PyTorch, gets used and +// it's header included almost everywhere. Unfortunately this means +// every time an operator signature is updated or changed in +// native_functions.yaml, you (and every other PyTorch developer) need +// to recompile all of ATen and it's dependencies. +// +// TensorBase aims to break up these header dependencies, and improve +// incremental build times for all PyTorch developers. TensorBase +// represents a reference counted handle to TensorImpl, exactly the +// same as Tensor. However, TensorBase doesn't have code generated +// methods in it's API and thus no dependence on native_functions.yaml. +// +// Usage tips +// ---------- +// - You can `#define TORCH_ASSERT_NO_OPERATORS` at the top of a .cpp +// or .cu file to ensure it has no header dependencies on +// native_functions.yaml (direct or indirect). +// - Tensor inherits from TensorBase, so functions taking +// `const TensorBase &` are callable with Tensor as well. +// - TensorBase can be converted to tensor with `Tensor(tensor_base)`, +// but this requires a reference-count bump. OptionalTensorRef on +// the other hand can materialize a `const Tensor &` without +// touching the reference-count. +class TORCH_API TensorBase { + public: + struct unsafe_borrow_t { explicit unsafe_borrow_t() = default; }; + + protected: + // Create a Tensor with a +0 reference count. Special care must be + // taken to avoid decrementing this reference count at destruction + // time. Intended to support MaybeOwnedTraits. + explicit TensorBase(unsafe_borrow_t, const TensorBase& rhs) + : impl_(c10::intrusive_ptr(rhs.impl_.get(), c10::raw::DontIncreaseRefcount{})) {} + friend MaybeOwnedTraits; + + public: + TensorBase() = default; + // This constructor should not be used by end users and is an implementation + // detail invoked by autogenerated code. + explicit TensorBase( + c10::intrusive_ptr tensor_impl) + : impl_(std::move(tensor_impl)) { + if (impl_.get() == nullptr) { + throw std::runtime_error("TensorImpl with nullptr is not supported"); + } + } + TensorBase(const TensorBase&) = default; + TensorBase(TensorBase&&) noexcept = default; + ~TensorBase() noexcept = default; + + public: + // Creates a new wrapper from TensorImpl. Intentionally a free method because + // it should be used with care. Checks necessary invariants + static TensorBase wrap_tensor_impl( + c10::intrusive_ptr tensor_impl) { + TensorBase r(std::move(tensor_impl)); + r.enforce_invariants(); + return r; + } + + int64_t dim() const { + return impl_->dim(); + } + int64_t storage_offset() const { + return impl_->storage_offset(); + } + + TensorBase contiguous(MemoryFormat memory_format=MemoryFormat::Contiguous) const { + if (is_contiguous(memory_format)) { + return *this; + } else { + return __dispatch_contiguous(memory_format); + } + } + + /// Should be used if *this can reasonably be expected to be contiguous and + /// performance is important. + /// Compared to contiguous, it saves a reference count + /// increment/decrement if *this is already contiguous, at the cost + /// in all cases of an extra pointer of stack usage, an extra branch + /// to access, and an extra branch at destruction time. + c10::MaybeOwned expect_contiguous( + MemoryFormat memory_format=MemoryFormat::Contiguous) const &; + + // Use .contiguous() instead. Trying to borrow from a prvalue + // will only lead to trouble and dangling references. + c10::MaybeOwned expect_contiguous( + MemoryFormat memory_format=MemoryFormat::Contiguous) && = delete; + + const TensorBase& fill_(const c10::Scalar& scalar) const; + const TensorBase& zero_() const; + + TensorBase to(at::TensorOptions options={}, bool non_blocking=false, bool copy=false, std::optional memory_format=std::nullopt) const; + + bool is_complex() const { + return at::isComplexType(this->scalar_type()); + } + + bool is_floating_point() const { + return at::isFloatingType(this->scalar_type()); + } + + bool is_signed() const { + return at::isSignedType(this->scalar_type()); + } + + c10::SymInt sym_size(int64_t dim) const { + return impl_->sym_size(dim); + } + + c10::SymInt sym_stride(int64_t dim) const { + const auto sizes = this->sym_strides(); + const auto ndim = static_cast(sizes.size()); + // false is passed to maybe_wrap_dim so behavior is identical to array access (but with wrapping) + return sizes[c10::maybe_wrap_dim(dim, ndim, /*wrap_scalar=*/false)]; + + } + + int64_t size(int64_t dim) const { + return impl_->size(dim); + } + + int64_t stride(int64_t dim) const { + const auto strides = this->strides(); + const auto ndim = static_cast(strides.size()); + // false is passed to maybe_wrap_dim so behavior is identical to array access (but with wrapping) + return strides[c10::maybe_wrap_dim(dim, ndim, /*wrap_scalar=*/false)]; + } + + TensorImpl * unsafeGetTensorImpl() const { + return impl_.get(); + } + TensorImpl * unsafeReleaseTensorImpl() { + return impl_.release(); + } + const c10::intrusive_ptr& getIntrusivePtr() const { + return impl_; + } + + c10::intrusive_ptr unsafeReleaseIntrusivePtr() { + return std::move(impl_); + } + + bool defined() const { + return impl_; + } + + void reset() { + impl_.reset(); + } + +#if defined (_MSC_VER) + TensorBase& operator=(const TensorBase& x) & { + impl_ = x.impl_; + return *this; + }; + TensorBase& operator=(TensorBase&& x) & noexcept { + impl_ = std::move(x.impl_); + return *this; + } +#else + TensorBase& operator=(const TensorBase& x) & = default; + TensorBase& operator=(TensorBase&& x) & noexcept = default; +#endif + + // Ban assignment to rvalues, since at::Tensor (weirdly) performs a deep copy here + TensorBase& operator=(const TensorBase&) && = delete; + TensorBase& operator=(TensorBase&&) && noexcept = delete; + + bool is_same(const TensorBase& other) const noexcept { + return impl_ == other.impl_; + } + size_t use_count() const noexcept { + return impl_.use_count(); + } + size_t weak_use_count() const noexcept { + return impl_.weak_use_count(); + } + + std::string toString() const; + + IntArrayRef sizes() const { + return impl_->sizes(); + } + c10::SymIntArrayRef sym_sizes() const { + return impl_->sym_sizes(); + } + c10::SymIntArrayRef sym_strides() const { + return impl_->sym_strides(); + } + IntArrayRef strides() const { + return impl_->strides(); + } + // See impl::get_opt_names in ATen/NamedTensor.h for docs. + std::optional opt_names() const { + return impl::get_opt_names(unsafeGetTensorImpl()); + } + // See impl::get_names in ATen/NamedTensor.h for docs. + DimnameList names() const { + return impl::get_names(unsafeGetTensorImpl()); + } + int64_t ndimension() const { + return dim(); + } + + bool is_contiguous(at::MemoryFormat memory_format=at::MemoryFormat::Contiguous) const { + return impl_->is_contiguous(memory_format); + } + + bool is_non_overlapping_and_dense() const { + return impl_->is_non_overlapping_and_dense(); + } + + at::MemoryFormat suggest_memory_format( + bool channels_last_strides_exact_match = false) const { + // Setting channels_last_strides_exact_match to true forces function to + // check 0,1 - sized dimension strides. + if (layout() == at::kStrided) { + if (impl_->is_strides_like_channels_last()) { + if (!channels_last_strides_exact_match || + get_channels_last_strides_2d(sizes()) == strides()) { + return at::MemoryFormat::ChannelsLast; + } + } + else if (impl_->is_strides_like_channels_last_3d()) { + if (!channels_last_strides_exact_match || + get_channels_last_strides_3d(sizes()) == strides()) { + return at::MemoryFormat::ChannelsLast3d; + } + } + } + return at::MemoryFormat::Contiguous; + } + + // Total bytes consumed by the "view" of elements of the array. Does not + // include size of metadata. The number reported here does not necessarily + // correspond to the true physical memory consumed by a tensor; instead, + // it reports the memory the tensor would take *if* it were contiguous. + // Defined to be numel() * itemsize() + size_t nbytes() const { + TORCH_CHECK(layout () != at::kSparse, + "nbytes is not defined for sparse tensors. If you want the size of the constituent " \ + "tensors, add the nbytes of the indices and values. If you want the size of the " \ + "equivalent dense tensor, multiply numel() by element_size()"); + return impl_->numel() * impl_->itemsize(); + } + + c10::SymInt sym_nbytes() const { + TORCH_CHECK(layout () != at::kSparse, + "nbytes is not defined for sparse tensors. If you want the size of the constituent " \ + "tensors, add the nbytes of the indices and values. If you want the size of the " \ + "equivalent dense tensor, multiply numel() by element_size()"); + return impl_->sym_numel() * impl_->itemsize(); + } + + int64_t numel() const { + return impl_->numel(); + } + + c10::SymInt sym_numel() const { + return impl_->sym_numel(); + } + + c10::SymInt sym_storage_offset() const { + return impl_->sym_storage_offset(); + } + + // Length of one array element in bytes. This is the traditional + // Numpy naming. + size_t itemsize() const { + return impl_->itemsize(); + } + + // Same as itemsize(). This is the PyTorch naming. + int64_t element_size() const { + return static_cast(impl_->itemsize()); + } + + DispatchKeySet key_set() const { + return impl_->key_set(); + } + ScalarType scalar_type() const { + return typeMetaToScalarType(impl_->dtype()); + } + bool has_storage() const { + return defined() && impl_->has_storage(); + } + const Storage& storage() const { + return impl_->storage(); + } + bool is_alias_of(const at::TensorBase& other) const{ + return impl_->storage().is_alias_of(other.storage()); + } + + // Move the storage backend to shm based + // to enable memory sharing across processes. + // + // NB1: the ideal behavior of this API still requires further discussion + // but for now we are inclined to keep it consistent with existing THP behavior + // https://github.com/pytorch/pytorch/blob/4dca9bde0552afc67b5b74f4a0696fe6055709c4/torch/storage.py#L196-L212 + // so we don't assert on anything here and rely on caller knowing + // what it's doing. + // + // NB2: this currently provides Linux fd based shm support only + // to simplify the storage lifetime management logic in ATen + // and similarly for now we are not adding support for file system based + // shm support like in THP due to additional GC manager support needed + // to prevent leaks. + // As such, calling this from non supported systems (e.g. Windows) would fail. + void share_memory_() { + at::share_memory_(*this); + } + + inline bool _is_zerotensor() const { + return impl_->_is_zerotensor(); + } + + inline void _set_zero(bool zero) const { + impl_->_set_zero(zero); + } + + inline bool is_conj() const { + return impl_->is_conj(); + } + + // sets the conjugate bit of a tensor. + // NOTE: Conjugate bit is supposed to be a read-only field. Only change this, if you are sure + // that's what you want. Changing this might lead to incorrect behavior since conjugation is + // a lazy operation and we rely on this bit to determine if a conjugation needs to be materialized. + inline void _set_conj(bool conjugate) const { + impl_->_set_conj(conjugate); + } + + inline bool is_neg() const { + return impl_->is_neg(); + } + + // sets the negative bit of a tensor. + // NOTE: Negative bit is supposed to be a read-only field. Only change this, if you are sure + // that's what you want. Changing this might lead to incorrect behavior since we rely on this + // bit to determine if a negation needs to be materialized. + inline void _set_neg(bool negative) const { + impl_->_set_neg(negative); + } + + /// Returns a `Tensor`'s layout. + Layout layout() const { + return impl_->layout(); + } + + /// Returns a `Tensor`'s dtype (`TypeMeta`). + caffe2::TypeMeta dtype() const { + return impl_->dtype(); + } + + /// Returns a `Tensor`'s device. + inline Device device() const { + return impl_->device(); + } + + /// Returns a `Tensor`'s device index. + DeviceIndex get_device() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->get_device(); + } + + /// Returns if a `Tensor` has CPU backend. + bool is_cpu() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_cpu(); + } + + /// Returns if a `Tensor` has CUDA backend. + bool is_cuda() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_cuda(); + } + + /// Returns if a `Tensor` has IPU backend. + bool is_ipu() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_ipu(); + } + + /// Returns if a `Tensor` has XPU backend. + bool is_xpu() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_xpu(); + } + + /// Returns if a `Tensor` has XLA backend. + bool is_xla() const { + return impl_->is_xla(); + } + + /// Returns if a `Tensor` has MTIA backend. + bool is_mtia() const { + return impl_->is_mtia(); + } + + /// Returns if a `Tensor` has HPU backend. + bool is_hpu() const { + return impl_->is_hpu(); + } + + /// Returns if a `Tensor` has Lazy backend. + bool is_lazy() const { + return impl_->is_lazy(); + } + + /// Returns if a `Tensor` has HIP backend. + bool is_hip() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_hip(); + } + + /// Returns if a `Tensor` has VE backend. + bool is_ve() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_ve(); + } + + /// Returns if a `Tensor` has PrivateUse1 backend. + bool is_privateuseone() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_privateuseone(); + } + + /// Returns if a `Tensor` has sparse backend. + bool is_sparse() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_sparse(); + } + + /// Returns is a `Tensor` has a sparse CSR backend. + bool is_sparse_csr() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_sparse_csr(); + } + + /// Returns if a `Tensor` is mkldnn tensor. + bool is_mkldnn() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_mkldnn(); + } + + /// Returns if a `Tensor` is mps tensor. + bool is_mps() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_mps(); + } + + /// Returns if a `Tensor` is maia tensor. + bool is_maia() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_maia(); + } + + /// Returns if a `Tensor` is vulkan tensor. + bool is_vulkan() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_vulkan(); + } + + /// Returns if a `Tensor` is metal tensor. + bool is_metal() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_metal(); + } + + /// Returns if a `Tensor` has quantized backend. + bool is_quantized() const { + // NB: this is not a native function to avoid dispatching overhead. + return impl_->is_quantized(); + } + + /// Returns if a `Tensor` is a meta tensor. Meta tensors can + /// also have other designations. + bool is_meta() const { + return impl_->is_meta(); + } + + /// Returns if a `Tensor` is an inference tensor. + bool is_inference() const { + return impl_->is_inference(); + } + + // Returns if a `Tensor` is a NestedTensor. + bool is_nested() const { + return impl_->is_nested(); + } + + /// If a tensor is a quantized tensor, returns its quantizer + /// TODO: it's not in native_functions.yaml yet as it's not exposed to python + QuantizerPtr quantizer() const; + + /// Returns if a `Tensor` has any dimension names + bool has_names() const { + // If a user is using unnamed tensors, then we can short-circuit right here. + // Otherwise, impl::has_names attempts to retrieve names. + if (!impl_->has_named_tensor_meta()) { + return false; + } + return impl::has_names(unsafeGetTensorImpl()); + } + + /// Returns a `Tensor`'s dimension names data structure + const NamedTensorMeta* get_named_tensor_meta() const { + return static_cast(impl_->named_tensor_meta()); + } + + NamedTensorMeta* get_named_tensor_meta() { + return static_cast(impl_->named_tensor_meta()); + } + + /// Returns the `TensorOptions` corresponding to this `Tensor`. Defined in + /// TensorOptions.h. + TensorOptions options() const { + return TensorOptions().dtype(dtype()) + .device(device()) + .layout(layout()); + } + + const void* const_data_ptr() const { + return this->unsafeGetTensorImpl()->data(); + } + + void* mutable_data_ptr() const { + return this->unsafeGetTensorImpl()->mutable_data(); + } + + // TODO(#97856) Make this return a const pointer. This currently + // returns a non-const pointer because of the large + // number of clients that we still want to audit before + // migrating to mutable_data_ptr(). + void* data_ptr() const { + return mutable_data_ptr(); + } + + template , int> = 0> + const T* const_data_ptr() const; + + template , int> = 0> + const std::remove_const_t* const_data_ptr() const; + + template + T* mutable_data_ptr() const; + + // Legacy interface during the migration to indicate that a callsite + // has not been audited for mutability. + // + // Do not add new uses of this, use const_data_ptr() if possible, + // mutable_data_ptr() otherwise. + // + // TODO(#97856) Make this return a const pointer. This is currently + // const because of the vast number of clients that + // rely on this. + template + T* data_ptr() const; + + // Purposely not defined here to avoid inlining + void print() const; + + // Return a `TensorAccessor` for CPU `Tensor`s. You have to specify scalar type and + // dimension. + template + TensorAccessor accessor() const& { + static_assert(N > 0, "accessor is used for indexing tensor, for scalars use *data_ptr()"); + TORCH_CHECK(dim() == N, "TensorAccessor expected ", N, " dims but tensor has ", dim()); + T* ptr = nullptr; + if constexpr (std::is_const_v) { + ptr = const_data_ptr(); + } else { + ptr = mutable_data_ptr(); + } + return TensorAccessor(ptr,sizes().data(),strides().data()); + } + template + TensorAccessor accessor() && = delete; + + // Return a `GenericPackedTensorAccessor` for CUDA `Tensor`s. You have to specify scalar type and + // dimension. You can optionally specify RestrictPtrTraits as a template parameter to + // cast the data pointer to a __restrict__ pointer. + // In order to use this, your CUDA kernel has to take a corresponding GenericPackedTensorAccessor + // as an argument. + template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> + GenericPackedTensorAccessor generic_packed_accessor() const& { + static_assert(N > 0, "accessor is used for indexing tensor, for scalars use *data_ptr()"); + TORCH_CHECK(dim() == N, "TensorAccessor expected ", N, " dims but tensor has ", dim()); + T* ptr = nullptr; + if constexpr (std::is_const_v) { + ptr = const_data_ptr(); + } else { + ptr = mutable_data_ptr(); + } + return GenericPackedTensorAccessor(static_cast::PtrType>(ptr),sizes().data(),strides().data()); + } + template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> + GenericPackedTensorAccessor generic_packed_accessor() && = delete; + + template class PtrTraits = DefaultPtrTraits> + PackedTensorAccessor32 packed_accessor32() const& { + TORCH_CHECK( + impl_->numel() <= + static_cast(std::numeric_limits::max()), + "numel needs to be smaller than int32_t max; otherwise, please use packed_accessor64"); + return generic_packed_accessor(); + } + template class PtrTraits = DefaultPtrTraits> + PackedTensorAccessor32 packed_accessor32() && = delete; + + template class PtrTraits = DefaultPtrTraits> + PackedTensorAccessor64 packed_accessor64() const& { + return generic_packed_accessor(); + } + template class PtrTraits = DefaultPtrTraits> + PackedTensorAccessor64 packed_accessor64() && = delete; + + // ~~~~~ Autograd API ~~~~~ + + /// \fn bool is_leaf() const; + /// + /// All Tensors that have `requires_grad()` which is ``false`` will be leaf Tensors by convention. + /// + /// For Tensors that have `requires_grad()` which is ``true``, they will be leaf Tensors if they were + /// created by the user. This means that they are not the result of an operation and so + /// `grad_fn()` is `nullptr`. + /// + /// Only leaf Tensors will have their `grad()` populated during a call to `backward()`. + /// To get `grad()` populated for non-leaf Tensors, you can use `retain_grad()`. + /// + /// Example: + /// @code + /// auto a = torch::rand(10, torch::requires_grad()); + /// std::cout << a.is_leaf() << std::endl; // prints `true` + /// + /// auto b = torch::rand(10, torch::requires_grad()).to(torch::kCUDA); + /// std::cout << b.is_leaf() << std::endl; // prints `false` + /// // b was created by the operation that cast a cpu Tensor into a cuda Tensor + /// + /// auto c = torch::rand(10, torch::requires_grad()) + 2; + /// std::cout << c.is_leaf() << std::endl; // prints `false` + /// // c was created by the addition operation + /// + /// auto d = torch::rand(10).cuda(); + /// std::cout << d.is_leaf() << std::endl; // prints `true` + /// // d does not require gradients and so has no operation creating it (that is tracked by the autograd engine) + /// + /// auto e = torch::rand(10).cuda().requires_grad_(); + /// std::cout << e.is_leaf() << std::endl; // prints `true` + /// // e requires gradients and has no operations creating it + /// + /// auto f = torch::rand(10, torch::device(torch::kCUDA).requires_grad(true)); + /// std::cout << f.is_leaf() << std::endl; // prints `true` + /// // f requires grad, has no operation creating it + /// @endcode + + /// \fn void backward(const Tensor & gradient={}, std::optional retain_graph=std::nullopt, bool create_graph=false, std::optional inputs=std::nullopt) const; + /// + /// Computes the gradient of current tensor with respect to graph leaves. + /// + /// The graph is differentiated using the chain rule. If the tensor is + /// non-scalar (i.e. its data has more than one element) and requires + /// gradient, the function additionally requires specifying ``gradient``. + /// It should be a tensor of matching type and location, that contains + /// the gradient of the differentiated function w.r.t. this Tensor. + /// + /// This function accumulates gradients in the leaves - you might need to + /// zero them before calling it. + /// + /// \param gradient Gradient w.r.t. the + /// tensor. If it is a tensor, it will be automatically converted + /// to a Tensor that does not require grad unless ``create_graph`` is True. + /// None values can be specified for scalar Tensors or ones that + /// don't require grad. If a None value would be acceptable then + /// this argument is optional. + /// \param retain_graph If ``false``, the graph used to compute + /// the grads will be freed. Note that in nearly all cases setting + /// this option to True is not needed and often can be worked around + /// in a much more efficient way. Defaults to the value of + /// ``create_graph``. + /// \param create_graph If ``true``, graph of the derivative will + /// be constructed, allowing to compute higher order derivative + /// products. Defaults to ``false``. + /// \param inputs Inputs w.r.t. which the gradient will be accumulated into + /// ``at::Tensor::grad``. All other Tensors will be ignored. If not + /// provided, the gradient is accumulated into all the leaf Tensors + /// that were used to compute the current tensor. + /// When inputs are provided and a given input is not a leaf, + /// the current implementation will call its grad_fn (even though it is not strictly needed to get this gradients). + /// It is an implementation detail on which the user should not rely. + /// See https://github.com/pytorch/pytorch/pull/60521#issuecomment-867061780 for more details. + + /// \fn Tensor detach() const; + /// + /// Returns a new Tensor, detached from the current graph. + /// The result will never require gradient. + + /// \fn Tensor & detach_() const; + /// + /// Detaches the Tensor from the graph that created it, making it a leaf. + /// Views cannot be detached in-place. + + /// \fn void retain_grad() const; + /// + /// Enables this Tensor to have their :attr:`grad` populated during + /// :func:`backward`. This is a no-op for leaf tensors. + + /// \fn bool retains_grad() const; + /// + /// Is ``true`` if this Tensor is non-leaf and its :attr:`grad` is enabled to be + /// populated during :func:`backward`, ``false`` otherwise. + + const TensorBase& set_requires_grad(bool requires_grad) const { + impl_->set_requires_grad(requires_grad); + return *this; + } + bool requires_grad() const { + return impl_->requires_grad(); + } + + // The Forward AD API functions below are low level and are not to be used by end + // users who should use the API provided in torch/csrc/autograd.h + + /// This function returns the forward gradient for this Tensor at the given level. + const Tensor& _fw_grad(uint64_t level) const { + return impl_->_fw_grad(level, *this); + } + + /// This function can be used to set the value of the forward grad. + /// Note that the given new_grad might not be used directly if it has different + /// metadata (size/stride/storage offset) compared to this Tensor. In that case, + /// new_grad content will be copied into a new Tensor + void _set_fw_grad(const TensorBase& new_grad, uint64_t level, bool is_inplace_op) const { + impl_->_set_fw_grad(new_grad, *this, level, is_inplace_op); + } + + /// NOTE: This is similar to the legacy `.data()` function on `Variable`, and is intended + /// to be used from functions that need to access the `Variable`'s equivalent `Tensor` + /// (i.e. `Tensor` that shares the same storage and tensor metadata with the `Variable`). + /// + /// One notable difference with the legacy `.data()` function is that changes to the + /// returned `Tensor`'s tensor metadata (e.g. sizes / strides / storage / storage_offset) + /// will not update the original `Variable`, due to the fact that this function + /// shallow-copies the `Variable`'s underlying TensorImpl. + at::TensorBase tensor_data() const; + + /// NOTE: `var.variable_data()` in C++ has the same semantics as `tensor.data` + /// in Python, which create a new `Variable` that shares the same storage and + /// tensor metadata with the original `Variable`, but with a completely new + /// autograd history. + /// + /// NOTE: If we change the tensor metadata (e.g. sizes / strides / + /// storage / storage_offset) of a variable created from `var.variable_data()`, those + /// changes will not update the original variable `var`. In `.variable_data()`, we set + /// `allow_tensor_metadata_change_` to false to make such changes explicitly illegal, + /// in order to prevent users from changing metadata of `var.variable_data()` + /// and expecting the original variable `var` to also be updated. + at::TensorBase variable_data() const; + + // Gradient Node and Edges + //~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + + /// Gets the gradient function of the `Variable`. If this is a leaf variable, + /// the pointer returned will be null. + /// + /// For View Variables: + /// Gets the up-to-date grad_fn. If the shared data or base was modified, we + /// re-create the grad_fn to express the up-to-date view relationship between + /// this and the base Variable. + const std::shared_ptr& grad_fn() const; + + // Hooks + //~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + + template + using hook_return_void_t = std::enable_if_t>, unsigned>; + template + using hook_return_var_t = std::enable_if_t, TensorBase>, unsigned>; + + /// Registers a backward hook. + /// + /// The hook will be called every time a gradient with respect to the Tensor is computed. + /// The hook should have one of the following signature: + /// ``` + /// hook(TensorBase grad) -> TensorBase + /// ``` + /// ``` + /// hook(TensorBase grad) -> void + /// ``` + /// The hook should not modify its argument, but it can optionally return a new gradient + /// which will be used in place of `grad`. + /// + /// This function returns the index of the hook in the list which can be used to remove hook. + /// + /// Example: + /// @code + /// auto v = torch::tensor({0., 0., 0.}, torch::requires_grad()); + /// auto h = v.register_hook([](torch::Tensor grad){ return grad * 2; }); // double the gradient + /// v.backward(torch::tensor({1., 2., 3.})); + /// // This prints: + /// // ``` + /// // 2 + /// // 4 + /// // 6 + /// // [ CPUFloatType{3} ] + /// // ``` + /// std::cout << v.grad() << std::endl; + /// v.remove_hook(h); // removes the hook + /// @endcode + template + hook_return_void_t register_hook(T&& hook) const; + template + hook_return_var_t register_hook(T&& hook) const; + +protected: + unsigned _register_hook(std::function hook) const; + +public: + + /// Remove hook at given position + void remove_hook(unsigned pos) const; + + // Variable methods + //~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + + bool is_leaf() const; + + int64_t output_nr() const; + + void set_data(const TensorBase & new_data) const; + + TensorBase data() const; + + int64_t _version() const; + + void retain_grad() const; + + bool retains_grad() const; + + const TensorBase& requires_grad_(bool _requires_grad=true) const; + + // View Variables + //~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + + /// Returns true if this `Variable` is a view of another `Variable`. + bool is_view() const; + + /// Returns the `Variable` that this `Variable` is a view of. If this + /// `Variable` is not a view, throw a `std::runtime_error`. + const TensorBase& _base() const; + + // Miscellaneous + //~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + + const std::string& name() const; + +protected: + void enforce_invariants(); + c10::intrusive_ptr impl_; + +private: + TensorBase __dispatch_contiguous(c10::MemoryFormat) const; +}; + +inline DeviceIndex get_device(const TensorBase& self) { + return self.get_device(); +} + +template +auto TensorBase::register_hook(T&& hook) const -> TensorBase::hook_return_void_t { + // Return the grad argument in case of a hook with void return type to have an + // std::function with Tensor return type + static_assert(std::is_same_v, + "Expected hook to return void"); + return _register_hook([fn=std::forward(hook)](const TensorBase& grad) { + fn(grad); + return TensorBase(); + }); +} + +template +auto TensorBase::register_hook(T&& hook) const -> TensorBase::hook_return_var_t { + return _register_hook(std::forward(hook)); +} + +namespace detail { +// Helper creator for Tensor class which doesn't requires the users to pass +// in an intrusive_ptr instead it just converts the argument passed to +// requested intrusive_ptr type. +template +TensorBase make_tensor_base(Args&&... args) { + return TensorBase(c10::make_intrusive(std::forward(args)...)); +} + +} // namespace detail + +inline DispatchKey legacyExtractDispatchKey(const TensorBase& t) { + return legacyExtractDispatchKey(t.key_set()); +} + +} // namespace at + +namespace c10 { +template <> +struct MaybeOwnedTraits { + using owned_type = at::TensorBase; + using borrow_type = at::TensorBase; + + static borrow_type createBorrow(const owned_type& from) { + // NOTE: this can be implemented without the special + // unsafe_borrow_t Tensor constructor as + // + // return borrow_type(c10::intrusive_ptr::reclaim(from.unsafeGetTensorImpl())); + // + // but that hurts inlining due to the nullptr check in the + // Tensor(c10::intrusive_ptr<...>) constructor. We already know + // that from.impl_ isn't null because from is a valid Tensor, so + // we needn't do the check again. (using __builtin_assume can + // avoid this, but wouldn't be portable to MSVC.) + return borrow_type(borrow_type::unsafe_borrow_t{}, from); + } + + static void assignBorrow(borrow_type& lhs, const borrow_type& rhs) { + lhs.unsafeReleaseTensorImpl(); + // See above note: this can be implemented with public API + // similarly to createBorrow(), but that would hurt inlining. + lhs = borrow_type(borrow_type::unsafe_borrow_t{}, rhs); + } + + static void destroyBorrow(borrow_type& toDestroy) { + toDestroy.unsafeReleaseTensorImpl(); // "leak" it, but it was already +0. + } + + static const owned_type& referenceFromBorrow(const borrow_type& borrow) { + return borrow; + } + + static const owned_type* pointerFromBorrow(const borrow_type& borrow) { + return &borrow; + } + + static bool debugBorrowIsValid(const borrow_type& /*borrow*/) { + return true; + } +}; + +template <> +struct ExclusivelyOwnedTraits : public c10::ExclusivelyOwnedTensorTraits {}; +} // namespace c10 + +namespace at { + +inline c10::MaybeOwned borrow_from_optional_tensor( + const std::optional& opt) { + return opt.has_value() + ? c10::MaybeOwned::borrowed(*opt) + : c10::MaybeOwned::owned(std::in_place); +} + +inline c10::MaybeOwned TensorBase::expect_contiguous(MemoryFormat memory_format) const & { + if (is_contiguous(memory_format)) { + return c10::MaybeOwned::borrowed(*this); + } else { + return c10::MaybeOwned::owned(__dispatch_contiguous(memory_format)); + } +} + +namespace symint { + +template +using enable_if_symint = std::enable_if_t>; +template +using enable_if_int = std::enable_if_t>; + +template > +c10::SymIntArrayRef sizes(const TensorBase& t) { return t.sym_sizes(); } +template > +IntArrayRef sizes(const TensorBase& t) { return t.sizes(); } + +template > +c10::SymInt size(const TensorBase& t, int64_t dim) { return t.sym_size(dim); } +template > +int64_t size(const TensorBase& t, int64_t dim) { return t.size(dim); } + +template > +c10::SymIntArrayRef strides(const TensorBase& t) { return t.sym_strides(); } +template > +IntArrayRef strides(const TensorBase& t) { return t.strides(); } + +template > +c10::SymInt numel(const TensorBase& t) { return t.sym_numel(); } +template > +int64_t numel(const TensorBase& t) { return t.numel(); } + +} // namespace symint + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TensorBody.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TensorBody.h new file mode 100644 index 0000000000000000000000000000000000000000..6c71ba1ce333a26a8dbf991de22410306935d68d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TensorBody.h @@ -0,0 +1,5737 @@ +#pragma once + +#ifdef TORCH_ASSERT_NO_OPERATORS +#error This change adds a dependency on native_functions.yaml, \ + meaning the file will need to be re-compiled every time an operator \ + is changed or added. Consider if your change would be better placed in \ + another file, or if a more specific header might achieve the same goal. \ + See NOTE: [Tensor vs. TensorBase] +#endif + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +#include + +namespace c10{ +template class List; +template class IListRef; +} +namespace at { +struct Generator; +struct Type; +class DeprecatedTypeProperties; +class Tensor; +} // namespace at +namespace at { +namespace indexing { +struct TensorIndex; +} // namespace indexing +} // namespace at + +namespace torch { namespace autograd { + +struct Node; + +}} // namespace torch::autograd + +namespace at { + +class OptionalTensorRef; +class TensorRef; +class Tensor; +using TensorList = ArrayRef; +using ITensorList = c10::IListRef; + +using Stream = c10::Stream; + +// Tensor is a "generic" object holding a pointer to the underlying TensorImpl object, which +// has an embedded reference count. In this way, Tensor is similar to boost::intrusive_ptr. +// +// For example: +// +// void func(Tensor a) { +// Tensor b = a; +// ... +// } +// +// In this example, when we say Tensor b = a, we are creating a new object that points to the +// same underlying TensorImpl, and bumps its reference count. When b goes out of scope, the +// destructor decrements the reference count by calling release() on the TensorImpl it points to. +// The existing constructors, operator overloads, etc. take care to implement the correct semantics. +// +// Note that Tensor can also be NULL, i.e. it is not associated with any underlying TensorImpl, and +// special care must be taken to handle this. +class TORCH_API Tensor: public TensorBase { + protected: + // Create a Tensor with a +0 reference count. Special care must be + // taken to avoid decrementing this reference count at destruction + // time. Intended to support MaybeOwnedTraits. + explicit Tensor(unsafe_borrow_t, const TensorBase& rhs): TensorBase(unsafe_borrow_t{}, rhs) {} + friend MaybeOwnedTraits; + friend OptionalTensorRef; + friend TensorRef; + + public: + Tensor() = default; + // This constructor should not be used by end users and is an implementation + // detail invoked by autogenerated code. + explicit Tensor( + c10::intrusive_ptr tensor_impl) + : TensorBase(std::move(tensor_impl)) {} + Tensor(const Tensor &tensor) = default; + Tensor(Tensor &&tensor) = default; + + // Implicitly move-constructible from TensorBase, but must be explicit to increase refcount + explicit Tensor(const TensorBase &base): TensorBase(base) {} + /*implicit*/ Tensor(TensorBase &&base): TensorBase(std::move(base)) {} + + // Creates a new wrapper from TensorImpl. Intentionally a free method because + // it should be used with care. Checks necessary invariants + static Tensor wrap_tensor_impl( + c10::intrusive_ptr tensor_impl) { + return TensorBase::wrap_tensor_impl(std::move(tensor_impl)); + } + + Tensor contiguous(MemoryFormat memory_format=MemoryFormat::Contiguous) const { + return TensorBase::contiguous(memory_format); + } + + Tensor conj() const { + if (!this->is_complex()) { + return *this; + } + + switch (this->layout()) { + case at::kSparse: + case at::kSparseCsr: + case at::kSparseCsc: + case at::kSparseBsr: + case at::kSparseBsc: + return this->conj_physical(); + default: + return this->_conj(); + } + } + + // Aliased by Dimname overloads, so need explicit using + using TensorBase::size; + using TensorBase::sym_size; + using TensorBase::stride; + + /// Should be used if *this can reasonably be expected to be contiguous and + /// performance is important. + /// Compared to contiguous, it saves a reference count + /// increment/decrement if *this is already contiguous, at the cost + /// in all cases of an extra pointer of stack usage, an extra branch + /// to access, and an extra branch at destruction time. + c10::MaybeOwned expect_contiguous(MemoryFormat memory_format=MemoryFormat::Contiguous) const &; + + // Use .contiguous() instead. Trying to borrow from a prvalue Tensor + // will only lead to trouble and dangling references. + c10::MaybeOwned expect_contiguous(MemoryFormat memory_format=MemoryFormat::Contiguous) && = delete; + + // The following overloads are very intruiging. Consider the following + // program: + // + // x[1] = 3; + // + // We would expect that the first entry of x is written to 3. But how can we + // actually achieve this? x[1] evaluates to a tensor... + // + // The answer is, using a ref-qualifier. x[1] is an rvalue, which cannot be + // (profitably) assigned to in the traditional sense, so we overload + // assignment to mean, "Actually, copy 3 into the tensor data." This is done + // with an rvalue-reference ref-qualified overload (the methods with && at the + // end of their type.) + // + // There's one more fly in the ointment: We also want + // + // Tensor x = y; + // + // to work, and we want it NOT to copy. So we need a traditional operator= + // overload. But we MUST specify a mutable lvalue ref-qualifier, to + // disambiguate the traditional overload from the rvalue-reference + // ref-qualified overload. Otherwise, it will be ambiguous, because + // a non ref-qualified method is eligible for all situations. + + // Unfortunately, we have to write these constructors out manually + // to work around an MSVC bug: + // error C2580: 'at::Tensor &at::Tensor::operator =(const at::Tensor &) &': + // multiple versions of a defaulted special member functions are not allowed + // Tensor& operator=(const Tensor&) & = default; + // Tensor& operator=(Tensor&&) & = default; + + // Also MSVC will wrongly issue the following warning with the aforementioned fix + // warning C4522: 'at::Tensor': multiple assignment operators specified + // Let's just skip the warning. + // + // TODO: temporarily disabled + + Tensor& operator=(const TensorBase& x) & noexcept { + impl_ = x.getIntrusivePtr(); + return *this; + } + Tensor& operator=(TensorBase&& x) & noexcept { + impl_ = x.unsafeReleaseIntrusivePtr(); + return *this; + } + + Tensor& operator=(const Tensor &x) & noexcept { + return operator=(static_cast(x)); + } + Tensor& operator=(Tensor &&x) & noexcept { + return operator=(static_cast(x)); + } + + Tensor& operator=(const Scalar &v) && { + return fill_(v); + } + Tensor& operator=(const Tensor &rhs) && { + return copy_(rhs); + } + Tensor& operator=(Tensor&& rhs) && { + return copy_(rhs); + } + + C10_DEPRECATED_MESSAGE("Tensor.type() is deprecated. Instead use Tensor.options(), which in many cases (e.g. in a constructor) is a drop-in replacement. If you were using data from type(), that is now available from Tensor itself, so instead of tensor.type().scalar_type(), use tensor.scalar_type() instead and instead of tensor.type().backend() use tensor.device().") + DeprecatedTypeProperties & type() const { + return globalDeprecatedTypePropertiesRegistry().getDeprecatedTypeProperties( + dispatchKeyToBackend(legacyExtractDispatchKey(key_set())), + scalar_type()); + } + + Tensor toType(ScalarType t) const { + return to(options().dtype(t), /*non_blocking*/ false, /*copy*/ false); + } + + // TODO: Deprecate me + Tensor toBackend(Backend b) const { + return to(options().device(backendToDeviceType(b)).layout(layout_from_backend(b)), /*non_blocking*/ false, /*copy*/ false); + } + + C10_DEPRECATED_MESSAGE("Tensor.is_variable() is deprecated; everything is a variable now. (If you want to assert that variable has been appropriately handled already, use at::impl::variable_excluded_from_dispatch())") + bool is_variable() const noexcept { + return !at::impl::variable_excluded_from_dispatch(); + } + + template + C10_DEPRECATED_MESSAGE("Tensor.data() is deprecated. Please use Tensor.data_ptr() instead.") + T * data() const { + return data_ptr(); + } + + template + T item() const; + + template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> + C10_DEPRECATED_MESSAGE("packed_accessor is deprecated, use packed_accessor32 or packed_accessor64 instead") + GenericPackedTensorAccessor packed_accessor() const & { + return generic_packed_accessor(); + } + template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> + C10_DEPRECATED_MESSAGE("packed_accessor is deprecated, use packed_accessor32 or packed_accessor64 instead") + GenericPackedTensorAccessor packed_accessor() && = delete; + + Tensor operator~() const { + return bitwise_not(); + } + Tensor operator-() const { + return neg(); + } + Tensor& operator+=(const Tensor & other) { + return add_(other); + } + Tensor& operator+=(const Scalar & other) { + return add_(other); + } + Tensor& operator-=(const Tensor & other) { + return sub_(other); + } + Tensor& operator-=(const Scalar & other) { + return sub_(other); + } + Tensor& operator*=(const Tensor & other) { + return mul_(other); + } + Tensor& operator*=(const Scalar & other) { + return mul_(other); + } + Tensor& operator/=(const Tensor & other) { + return div_(other); + } + Tensor& operator/=(const Scalar & other) { + return div_(other); + } + Tensor& operator&=(const Tensor & other) { + return bitwise_and_(other); + } + Tensor& operator|=(const Tensor & other) { + return bitwise_or_(other); + } + Tensor& operator^=(const Tensor & other) { + return bitwise_xor_(other); + } + Tensor operator[](const Scalar & index) const { + if (!index.isIntegral(false)) { + TORCH_CHECK_INDEX(false, "Can only index tensors with integral scalars"); + } + return this->operator[](index.toLong()); + } + Tensor operator[](const Tensor & index) const { + // These properties are checked in the Scalar constructor, but we already + // check them here to provide more useful diagnostics for the user. + if (!index.defined()) { + TORCH_CHECK_INDEX(false, "Can only index with tensors that are defined"); + } + if (index.dim() != 0) { + TORCH_CHECK_INDEX(false, + "Can only index with tensors that are scalars (zero-dim)"); + } + // The Scalar(Tensor) constructor is explicit, so we need to call it. + return this->operator[](index.item()); + } + Tensor operator[](int64_t index) const { + return select(0, index); + } + + Tensor index(ArrayRef indices) const; + Tensor index(std::initializer_list indices) const; + + Tensor & index_put_(ArrayRef indices, Tensor const & rhs); + Tensor & index_put_(ArrayRef indices, const Scalar& v); + Tensor & index_put_(std::initializer_list indices, Tensor const & rhs); + Tensor & index_put_(std::initializer_list indices, const Scalar& v); + + Tensor cpu() const { + return to(options().device(c10::DeviceType::CPU), /*non_blocking*/ false, /*copy*/ false); + } + + // TODO: The Python version also accepts arguments + Tensor cuda() const { + return to(options().device(c10::DeviceType::CUDA), /*non_blocking*/ false, /*copy*/ false); + } + + Tensor hip() const { + return to(options().device(c10::DeviceType::HIP), /*non_blocking*/ false, /*copy*/ false); + } + + Tensor ve() const { + return to(options().device(c10::DeviceType::VE), /*non_blocking*/ false, /*copy*/ false); + } + + Tensor vulkan() const { + return to(options().device(c10::DeviceType::Vulkan), /*non_blocking*/ false, /*copy*/ false); + } + + Tensor metal() const { + return to(options().device(c10::DeviceType::Metal), /*non_blocking*/ false, /*copy*/ false); + } + + Tensor meta() const { + return to(options().device(c10::DeviceType::Meta), /*non_blocking*/ false, /*copy*/ false); + } + + // ~~~~~ Autograd API ~~~~~ + + /// \fn bool is_leaf() const; + /// + /// All Tensors that have `requires_grad()` which is ``false`` will be leaf Tensors by convention. + /// + /// For Tensors that have `requires_grad()` which is ``true``, they will be leaf Tensors if they were + /// created by the user. This means that they are not the result of an operation and so + /// `grad_fn()` is `nullptr`. + /// + /// Only leaf Tensors will have their `grad()` populated during a call to `backward()`. + /// To get `grad()` populated for non-leaf Tensors, you can use `retain_grad()`. + /// + /// Example: + /// @code + /// auto a = torch::rand(10, torch::requires_grad()); + /// std::cout << a.is_leaf() << std::endl; // prints `true` + /// + /// auto b = torch::rand(10, torch::requires_grad()).to(torch::kCUDA); + /// std::cout << b.is_leaf() << std::endl; // prints `false` + /// // b was created by the operation that cast a cpu Tensor into a cuda Tensor + /// + /// auto c = torch::rand(10, torch::requires_grad()) + 2; + /// std::cout << c.is_leaf() << std::endl; // prints `false` + /// // c was created by the addition operation + /// + /// auto d = torch::rand(10).cuda(); + /// std::cout << d.is_leaf() << std::endl; // prints `true` + /// // d does not require gradients and so has no operation creating it (that is tracked by the autograd engine) + /// + /// auto e = torch::rand(10).cuda().requires_grad_(); + /// std::cout << e.is_leaf() << std::endl; // prints `true` + /// // e requires gradients and has no operations creating it + /// + /// auto f = torch::rand(10, torch::device(torch::kCUDA).requires_grad(true)); + /// std::cout << f.is_leaf() << std::endl; // prints `true` + /// // f requires grad, has no operation creating it + /// @endcode + + /// \fn void backward(const Tensor & gradient={}, std::optional retain_graph=std::nullopt, bool create_graph=false, std::optional inputs=std::nullopt) const; + /// + /// Computes the gradient of current tensor with respect to graph leaves. + /// + /// The graph is differentiated using the chain rule. If the tensor is + /// non-scalar (i.e. its data has more than one element) and requires + /// gradient, the function additionally requires specifying ``gradient``. + /// It should be a tensor of matching type and location, that contains + /// the gradient of the differentiated function w.r.t. this Tensor. + /// + /// This function accumulates gradients in the leaves - you might need to + /// zero them before calling it. + /// + /// \param gradient Gradient w.r.t. the + /// tensor. If it is a tensor, it will be automatically converted + /// to a Tensor that does not require grad unless ``create_graph`` is True. + /// None values can be specified for scalar Tensors or ones that + /// don't require grad. If a None value would be acceptable then + /// this argument is optional. + /// \param retain_graph If ``false``, the graph used to compute + /// the grads will be freed. Note that in nearly all cases setting + /// this option to True is not needed and often can be worked around + /// in a much more efficient way. Defaults to the value of + /// ``create_graph``. + /// \param create_graph If ``true``, graph of the derivative will + /// be constructed, allowing to compute higher order derivative + /// products. Defaults to ``false``. + /// \param inputs Inputs w.r.t. which the gradient will be accumulated into + /// ``at::Tensor::grad``. All other Tensors will be ignored. If not + /// provided, the gradient is accumulated into all the leaf Tensors + /// that were used to compute the current tensor. + /// When inputs are provided and a given input is not a leaf, + /// the current implementation will call its grad_fn (even though it is not strictly needed to get this gradients). + /// It is an implementation detail on which the user should not rely. + /// See https://github.com/pytorch/pytorch/pull/60521#issuecomment-867061780 for more details. + void backward(const Tensor & gradient={}, std::optional retain_graph=std::nullopt, bool create_graph=false, std::optional inputs=std::nullopt) const { + // NB: Adding this wrapper to _backward here because we'd like our + // 'backwards' api to accept the 'inputs' argument optionally. Since code gen + // currently does not support optional of TensorList our approach is to replace + // backward in native_functions.yaml with _backward and call it here instead. + if (inputs.has_value()) { + TORCH_CHECK(inputs.value().size() > 0, "'inputs' argument to backward cannot be empty") + this->_backward(inputs.value(), gradient, retain_graph, create_graph); + } else { + this->_backward({}, gradient, retain_graph, create_graph); + } + } + + /// \fn Tensor detach() const; + /// + /// Returns a new Tensor, detached from the current graph. + /// The result will never require gradient. + + /// \fn Tensor & detach_() const; + /// + /// Detaches the Tensor from the graph that created it, making it a leaf. + /// Views cannot be detached in-place. + + /// \fn void retain_grad() const; + /// + /// Enables this Tensor to have their :attr:`grad` populated during + /// :func:`backward`. This is a no-op for leaf tensors. + + /// \fn bool retains_grad() const; + /// + /// Is ``true`` if this Tensor is non-leaf and its :attr:`grad` is enabled to be + /// populated during :func:`backward`, ``false`` otherwise. + + const Tensor& set_requires_grad(bool requires_grad) const { + TensorBase::set_requires_grad(requires_grad); + return *this; + } + + /// Return a mutable reference to the gradient. This is conventionally + /// used as `t.grad() = x` to set a gradient to a completely new tensor. + /// Note that this function work with a non-const Tensor and is not + /// thread safe. + Tensor& mutable_grad() const { + return impl_->mutable_grad(); + } + + /// This function returns an undefined tensor by default and returns a defined tensor + /// the first time a call to `backward()` computes gradients for this Tensor. + /// The attribute will then contain the gradients computed and future calls + /// to `backward()` will accumulate (add) gradients into it. + const Tensor& grad() const { + const Tensor& maybe_grad = impl_->grad(); + if (!is_leaf() && !retains_grad() && !maybe_grad.defined()) { + TORCH_WARN( + "The .grad attribute of a Tensor that is not a leaf Tensor is being accessed. Its .grad " + "attribute won't be populated during autograd.backward(). If you indeed want the .grad " + "field to be populated for a non-leaf Tensor, use .retain_grad() on the non-leaf Tensor. " + "If you access the non-leaf Tensor by mistake, make sure you access the leaf Tensor " + "instead. See github.com/pytorch/pytorch/pull/30531 for more informations."); + } + return maybe_grad; + } + + // The Forward AD API functions below are low level and are not to be used by end + // users who should use the API provided in torch/csrc/autograd.h + + /// This function returns the forward gradient for this Tensor at the given level. + const Tensor& _fw_grad(uint64_t level) const { + return impl_->_fw_grad(level, *this); + } + + /// This function can be used to set the value of the forward grad. + /// Note that the given new_grad might not be used directly if it has different + /// metadata (size/stride/storage offset) compared to this Tensor. In that case, + /// new_grad content will be copied into a new Tensor + void _set_fw_grad(const TensorBase& new_grad, uint64_t level, bool is_inplace_op) const { + impl_->_set_fw_grad(new_grad, *this, level, is_inplace_op); + } + + + // STOP. Thinking of adding a method here, which only makes use + // of other ATen methods? Define it in native_functions.yaml. + + //example + //Tensor * add(Tensor & b); + void __dispatch__backward(at::TensorList inputs, const ::std::optional & gradient={}, ::std::optional retain_graph=::std::nullopt, bool create_graph=false) const; + void __dispatch_set_data(const at::Tensor & new_data) const; + at::Tensor __dispatch_data() const; + bool __dispatch_is_leaf() const; + int64_t __dispatch_output_nr() const; + int64_t __dispatch__version() const; + at::Tensor & __dispatch_requires_grad_(bool requires_grad=true) const; + void __dispatch_retain_grad() const; + bool __dispatch_retains_grad() const; + at::Tensor _fw_primal(int64_t level) const; + at::Tensor & rename_(::std::optional names) const; + at::Tensor rename(::std::optional names) const; + at::Tensor align_to(at::DimnameList names) const; + at::Tensor align_to(at::DimnameList order, int64_t ellipsis_idx) const; + at::Tensor align_as(const at::Tensor & other) const; + at::Tensor refine_names(at::DimnameList names) const; + at::Tensor abs() const; + at::Tensor & abs_() const; + at::Tensor absolute() const; + at::Tensor & absolute_() const; + at::Tensor angle() const; + at::Tensor sgn() const; + at::Tensor & sgn_() const; + at::Tensor chalf(::std::optional memory_format=::std::nullopt) const; + at::Tensor _conj() const; + at::Tensor __dispatch_conj() const; + at::Tensor _conj_physical() const; + at::Tensor conj_physical() const; + at::Tensor & conj_physical_() const; + at::Tensor resolve_conj() const; + at::Tensor resolve_neg() const; + at::Tensor _neg_view() const; + at::Tensor acos() const; + at::Tensor & acos_() const; + at::Tensor arccos() const; + at::Tensor & arccos_() const; + at::Tensor add(const at::Tensor & other, const at::Scalar & alpha=1) const; + at::Tensor & add_(const at::Tensor & other, const at::Scalar & alpha=1) const; + at::Tensor add(const at::Scalar & other, const at::Scalar & alpha=1) const; + at::Tensor & add_(const at::Scalar & other, const at::Scalar & alpha=1) const; + at::Tensor addmv(const at::Tensor & mat, const at::Tensor & vec, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor & addmv_(const at::Tensor & mat, const at::Tensor & vec, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor addr(const at::Tensor & vec1, const at::Tensor & vec2, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor & addr_(const at::Tensor & vec1, const at::Tensor & vec2, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor _is_all_true() const; + at::Tensor _is_any_true() const; + at::Tensor all(int64_t dim, bool keepdim=false) const; + at::Tensor all(at::OptionalIntArrayRef dim, bool keepdim=false) const; + at::Tensor all(at::Dimname dim, bool keepdim=false) const; + bool allclose(const at::Tensor & other, double rtol=1e-05, double atol=1e-08, bool equal_nan=false) const; + at::Tensor any(int64_t dim, bool keepdim=false) const; + at::Tensor any(at::OptionalIntArrayRef dim, bool keepdim=false) const; + at::Tensor any(at::Dimname dim, bool keepdim=false) const; + at::Tensor argmax(::std::optional dim=::std::nullopt, bool keepdim=false) const; + at::Tensor argmin(::std::optional dim=::std::nullopt, bool keepdim=false) const; + at::Tensor acosh() const; + at::Tensor & acosh_() const; + at::Tensor arccosh() const; + at::Tensor & arccosh_() const; + at::Tensor asinh() const; + at::Tensor & asinh_() const; + at::Tensor arcsinh() const; + at::Tensor & arcsinh_() const; + at::Tensor atanh() const; + at::Tensor & atanh_() const; + at::Tensor arctanh() const; + at::Tensor & arctanh_() const; + at::Tensor as_strided(at::IntArrayRef size, at::IntArrayRef stride, ::std::optional storage_offset=::std::nullopt) const; + at::Tensor as_strided_symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride, ::std::optional storage_offset=::std::nullopt) const; + const at::Tensor & as_strided_(at::IntArrayRef size, at::IntArrayRef stride, ::std::optional storage_offset=::std::nullopt) const; + const at::Tensor & as_strided__symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride, ::std::optional storage_offset=::std::nullopt) const; + at::Tensor asin() const; + at::Tensor & asin_() const; + at::Tensor arcsin() const; + at::Tensor & arcsin_() const; + at::Tensor atan() const; + at::Tensor & atan_() const; + at::Tensor arctan() const; + at::Tensor & arctan_() const; + at::Tensor baddbmm(const at::Tensor & batch1, const at::Tensor & batch2, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor & baddbmm_(const at::Tensor & batch1, const at::Tensor & batch2, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor bernoulli(::std::optional generator=::std::nullopt) const; + at::Tensor & bernoulli_(const at::Tensor & p, ::std::optional generator=::std::nullopt) const; + at::Tensor & bernoulli_(double p=0.5, ::std::optional generator=::std::nullopt) const; + at::Tensor bernoulli(double p, ::std::optional generator=::std::nullopt) const; + at::Tensor bincount(const ::std::optional & weights={}, int64_t minlength=0) const; + at::Tensor bitwise_not() const; + at::Tensor & bitwise_not_() const; + at::Tensor copysign(const at::Tensor & other) const; + at::Tensor & copysign_(const at::Tensor & other) const; + at::Tensor copysign(const at::Scalar & other) const; + at::Tensor & copysign_(const at::Scalar & other) const; + at::Tensor _lazy_clone() const; + at::Tensor logical_not() const; + at::Tensor & logical_not_() const; + at::Tensor logical_xor(const at::Tensor & other) const; + at::Tensor & logical_xor_(const at::Tensor & other) const; + at::Tensor logical_and(const at::Tensor & other) const; + at::Tensor & logical_and_(const at::Tensor & other) const; + at::Tensor logical_or(const at::Tensor & other) const; + at::Tensor & logical_or_(const at::Tensor & other) const; + at::Tensor bmm(const at::Tensor & mat2) const; + at::Tensor broadcast_to(at::IntArrayRef size) const; + at::Tensor broadcast_to_symint(c10::SymIntArrayRef size) const; + at::Tensor ceil() const; + at::Tensor & ceil_() const; + ::std::vector unsafe_chunk(int64_t chunks, int64_t dim=0) const; + ::std::vector chunk(int64_t chunks, int64_t dim=0) const; + ::std::vector tensor_split(int64_t sections, int64_t dim=0) const; + ::std::vector tensor_split_symint(c10::SymInt sections, int64_t dim=0) const; + ::std::vector tensor_split(at::IntArrayRef indices, int64_t dim=0) const; + ::std::vector tensor_split_symint(c10::SymIntArrayRef indices, int64_t dim=0) const; + ::std::vector tensor_split(const at::Tensor & tensor_indices_or_sections, int64_t dim=0) const; + at::Tensor clamp(const ::std::optional & min, const ::std::optional & max=::std::nullopt) const; + at::Tensor clamp(const ::std::optional & min={}, const ::std::optional & max={}) const; + at::Tensor & clamp_(const ::std::optional & min, const ::std::optional & max=::std::nullopt) const; + at::Tensor & clamp_(const ::std::optional & min={}, const ::std::optional & max={}) const; + at::Tensor clamp_max(const at::Scalar & max) const; + at::Tensor clamp_max(const at::Tensor & max) const; + at::Tensor & clamp_max_(const at::Scalar & max) const; + at::Tensor & clamp_max_(const at::Tensor & max) const; + at::Tensor clamp_min(const at::Scalar & min) const; + at::Tensor clamp_min(const at::Tensor & min) const; + at::Tensor & clamp_min_(const at::Scalar & min) const; + at::Tensor & clamp_min_(const at::Tensor & min) const; + at::Tensor clip(const ::std::optional & min, const ::std::optional & max=::std::nullopt) const; + at::Tensor clip(const ::std::optional & min={}, const ::std::optional & max={}) const; + at::Tensor & clip_(const ::std::optional & min, const ::std::optional & max=::std::nullopt) const; + at::Tensor & clip_(const ::std::optional & min={}, const ::std::optional & max={}) const; + at::Tensor __dispatch_contiguous(at::MemoryFormat memory_format=c10::MemoryFormat::Contiguous) const; + at::Tensor & copy_(const at::Tensor & src, bool non_blocking=false) const; + at::Tensor cos() const; + at::Tensor & cos_() const; + at::Tensor cosh() const; + at::Tensor & cosh_() const; + at::Tensor count_nonzero(at::IntArrayRef dim) const; + at::Tensor count_nonzero(::std::optional dim=::std::nullopt) const; + at::Tensor cov(int64_t correction=1, const ::std::optional & fweights={}, const ::std::optional & aweights={}) const; + at::Tensor corrcoef() const; + ::std::tuple cummax(int64_t dim) const; + ::std::tuple cummax(at::Dimname dim) const; + ::std::tuple cummin(int64_t dim) const; + ::std::tuple cummin(at::Dimname dim) const; + at::Tensor cumprod(int64_t dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor & cumprod_(int64_t dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor cumprod(at::Dimname dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor & cumprod_(at::Dimname dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor cumsum(int64_t dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor & cumsum_(int64_t dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor cumsum(at::Dimname dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor & cumsum_(at::Dimname dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor diag_embed(int64_t offset=0, int64_t dim1=-2, int64_t dim2=-1) const; + at::Tensor diagflat(int64_t offset=0) const; + at::Tensor diagonal(int64_t offset=0, int64_t dim1=0, int64_t dim2=1) const; + at::Tensor diagonal(at::Dimname outdim, at::Dimname dim1, at::Dimname dim2, int64_t offset=0) const; + at::Tensor & fill_diagonal_(const at::Scalar & fill_value, bool wrap=false) const; + at::Tensor diff(int64_t n=1, int64_t dim=-1, const ::std::optional & prepend={}, const ::std::optional & append={}) const; + at::Tensor div(const at::Tensor & other) const; + at::Tensor & div_(const at::Tensor & other) const; + at::Tensor div(const at::Tensor & other, ::std::optional rounding_mode) const; + at::Tensor & div_(const at::Tensor & other, ::std::optional rounding_mode) const; + at::Tensor div(const at::Scalar & other) const; + at::Tensor & div_(const at::Scalar & other) const; + at::Tensor div(const at::Scalar & other, ::std::optional rounding_mode) const; + at::Tensor & div_(const at::Scalar & other, ::std::optional rounding_mode) const; + at::Tensor divide(const at::Tensor & other) const; + at::Tensor & divide_(const at::Tensor & other) const; + at::Tensor divide(const at::Scalar & other) const; + at::Tensor & divide_(const at::Scalar & other) const; + at::Tensor divide(const at::Tensor & other, ::std::optional rounding_mode) const; + at::Tensor & divide_(const at::Tensor & other, ::std::optional rounding_mode) const; + at::Tensor divide(const at::Scalar & other, ::std::optional rounding_mode) const; + at::Tensor & divide_(const at::Scalar & other, ::std::optional rounding_mode) const; + at::Tensor true_divide(const at::Tensor & other) const; + at::Tensor & true_divide_(const at::Tensor & other) const; + at::Tensor true_divide(const at::Scalar & other) const; + at::Tensor & true_divide_(const at::Scalar & other) const; + at::Tensor dot(const at::Tensor & tensor) const; + at::Tensor vdot(const at::Tensor & other) const; + at::Tensor new_empty(at::IntArrayRef size, at::TensorOptions options={}) const; + at::Tensor new_empty(at::IntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + at::Tensor new_empty_symint(c10::SymIntArrayRef size, at::TensorOptions options={}) const; + at::Tensor new_empty_symint(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + at::Tensor new_empty_strided(at::IntArrayRef size, at::IntArrayRef stride, at::TensorOptions options={}) const; + at::Tensor new_empty_strided(at::IntArrayRef size, at::IntArrayRef stride, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + at::Tensor new_empty_strided_symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride, at::TensorOptions options={}) const; + at::Tensor new_empty_strided_symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + at::Tensor new_full(at::IntArrayRef size, const at::Scalar & fill_value, at::TensorOptions options={}) const; + at::Tensor new_full(at::IntArrayRef size, const at::Scalar & fill_value, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + at::Tensor new_full_symint(c10::SymIntArrayRef size, const at::Scalar & fill_value, at::TensorOptions options={}) const; + at::Tensor new_full_symint(c10::SymIntArrayRef size, const at::Scalar & fill_value, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + at::Tensor new_zeros(at::IntArrayRef size, at::TensorOptions options={}) const; + at::Tensor new_zeros(at::IntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + at::Tensor new_zeros_symint(c10::SymIntArrayRef size, at::TensorOptions options={}) const; + at::Tensor new_zeros_symint(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + at::Tensor new_ones(at::IntArrayRef size, at::TensorOptions options={}) const; + at::Tensor new_ones(at::IntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + at::Tensor new_ones_symint(c10::SymIntArrayRef size, at::TensorOptions options={}) const; + at::Tensor new_ones_symint(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const; + const at::Tensor & resize_(at::IntArrayRef size, ::std::optional memory_format=::std::nullopt) const; + const at::Tensor & resize__symint(c10::SymIntArrayRef size, ::std::optional memory_format=::std::nullopt) const; + at::Tensor erf() const; + at::Tensor & erf_() const; + at::Tensor erfc() const; + at::Tensor & erfc_() const; + at::Tensor exp() const; + at::Tensor & exp_() const; + at::Tensor exp2() const; + at::Tensor & exp2_() const; + at::Tensor expm1() const; + at::Tensor & expm1_() const; + at::Tensor expand(at::IntArrayRef size, bool implicit=false) const; + at::Tensor expand_symint(c10::SymIntArrayRef size, bool implicit=false) const; + at::Tensor expand_as(const at::Tensor & other) const; + at::Tensor flatten(int64_t start_dim=0, int64_t end_dim=-1) const; + at::Tensor flatten(int64_t start_dim, int64_t end_dim, at::Dimname out_dim) const; + at::Tensor flatten(at::Dimname start_dim, at::Dimname end_dim, at::Dimname out_dim) const; + at::Tensor flatten(at::DimnameList dims, at::Dimname out_dim) const; + at::Tensor unflatten(int64_t dim, at::IntArrayRef sizes) const; + at::Tensor unflatten_symint(int64_t dim, c10::SymIntArrayRef sizes) const; + at::Tensor unflatten(at::Dimname dim, at::IntArrayRef sizes, at::DimnameList names) const; + at::Tensor unflatten_symint(at::Dimname dim, c10::SymIntArrayRef sizes, at::DimnameList names) const; + at::Tensor & fill_(const at::Scalar & value) const; + at::Tensor & fill_(const at::Tensor & value) const; + at::Tensor floor() const; + at::Tensor & floor_() const; + at::Tensor floor_divide(const at::Tensor & other) const; + at::Tensor & floor_divide_(const at::Tensor & other) const; + at::Tensor floor_divide(const at::Scalar & other) const; + at::Tensor & floor_divide_(const at::Scalar & other) const; + at::Tensor frac() const; + at::Tensor & frac_() const; + at::Tensor gcd(const at::Tensor & other) const; + at::Tensor & gcd_(const at::Tensor & other) const; + at::Tensor lcm(const at::Tensor & other) const; + at::Tensor & lcm_(const at::Tensor & other) const; + at::Tensor index(const c10::List<::std::optional> & indices) const; + at::Tensor & index_copy_(int64_t dim, const at::Tensor & index, const at::Tensor & source) const; + at::Tensor index_copy(int64_t dim, const at::Tensor & index, const at::Tensor & source) const; + at::Tensor & index_copy_(at::Dimname dim, const at::Tensor & index, const at::Tensor & source) const; + at::Tensor index_copy(at::Dimname dim, const at::Tensor & index, const at::Tensor & source) const; + at::Tensor & index_put_(const c10::List<::std::optional> & indices, const at::Tensor & values, bool accumulate=false) const; + at::Tensor index_put(const c10::List<::std::optional> & indices, const at::Tensor & values, bool accumulate=false) const; + at::Tensor isclose(const at::Tensor & other, double rtol=1e-05, double atol=1e-08, bool equal_nan=false) const; + at::Tensor isnan() const; + bool is_distributed() const; + bool __dispatch_is_floating_point() const; + bool __dispatch_is_complex() const; + bool __dispatch_is_conj() const; + bool __dispatch__is_zerotensor() const; + bool __dispatch_is_neg() const; + at::Tensor isreal() const; + bool is_nonzero() const; + bool is_same_size(const at::Tensor & other) const; + bool __dispatch_is_signed() const; + bool __dispatch_is_inference() const; + at::Tensor kron(const at::Tensor & other) const; + ::std::tuple kthvalue(int64_t k, int64_t dim=-1, bool keepdim=false) const; + ::std::tuple kthvalue(int64_t k, at::Dimname dim, bool keepdim=false) const; + at::Tensor nan_to_num(::std::optional nan=::std::nullopt, ::std::optional posinf=::std::nullopt, ::std::optional neginf=::std::nullopt) const; + at::Tensor & nan_to_num_(::std::optional nan=::std::nullopt, ::std::optional posinf=::std::nullopt, ::std::optional neginf=::std::nullopt) const; + at::Tensor ldexp(const at::Tensor & other) const; + at::Tensor & ldexp_(const at::Tensor & other) const; + at::Tensor log() const; + at::Tensor & log_() const; + at::Tensor log10() const; + at::Tensor & log10_() const; + at::Tensor log1p() const; + at::Tensor & log1p_() const; + at::Tensor log2() const; + at::Tensor & log2_() const; + at::Tensor logaddexp(const at::Tensor & other) const; + at::Tensor logaddexp2(const at::Tensor & other) const; + at::Tensor xlogy(const at::Tensor & other) const; + at::Tensor xlogy(const at::Scalar & other) const; + at::Tensor & xlogy_(const at::Tensor & other) const; + at::Tensor & xlogy_(const at::Scalar & other) const; + at::Tensor log_softmax(int64_t dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor log_softmax(at::Dimname dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor logcumsumexp(int64_t dim) const; + at::Tensor logcumsumexp(at::Dimname dim) const; + at::Tensor logsumexp(at::IntArrayRef dim, bool keepdim=false) const; + at::Tensor logsumexp(at::DimnameList dim, bool keepdim=false) const; + at::Tensor matmul(const at::Tensor & other) const; + at::Tensor matrix_power(int64_t n) const; + at::Tensor matrix_exp() const; + ::std::tuple aminmax(::std::optional dim=::std::nullopt, bool keepdim=false) const; + ::std::tuple max(int64_t dim, bool keepdim=false) const; + ::std::tuple max(at::Dimname dim, bool keepdim=false) const; + at::Tensor amax(at::IntArrayRef dim={}, bool keepdim=false) const; + at::Tensor mean(::std::optional dtype=::std::nullopt) const; + at::Tensor mean(at::OptionalIntArrayRef dim, bool keepdim=false, ::std::optional dtype=::std::nullopt) const; + at::Tensor mean(at::DimnameList dim, bool keepdim=false, ::std::optional dtype=::std::nullopt) const; + at::Tensor nanmean(at::OptionalIntArrayRef dim=::std::nullopt, bool keepdim=false, ::std::optional dtype=::std::nullopt) const; + at::Tensor median() const; + ::std::tuple median(int64_t dim, bool keepdim=false) const; + ::std::tuple median(at::Dimname dim, bool keepdim=false) const; + at::Tensor nanmedian() const; + ::std::tuple nanmedian(int64_t dim, bool keepdim=false) const; + ::std::tuple nanmedian(at::Dimname dim, bool keepdim=false) const; + ::std::tuple min(int64_t dim, bool keepdim=false) const; + ::std::tuple min(at::Dimname dim, bool keepdim=false) const; + at::Tensor amin(at::IntArrayRef dim={}, bool keepdim=false) const; + at::Tensor mm(const at::Tensor & mat2) const; + ::std::tuple mode(int64_t dim=-1, bool keepdim=false) const; + ::std::tuple mode(at::Dimname dim, bool keepdim=false) const; + at::Tensor mul(const at::Tensor & other) const; + at::Tensor & mul_(const at::Tensor & other) const; + at::Tensor mul(const at::Scalar & other) const; + at::Tensor & mul_(const at::Scalar & other) const; + at::Tensor multiply(const at::Tensor & other) const; + at::Tensor & multiply_(const at::Tensor & other) const; + at::Tensor multiply(const at::Scalar & other) const; + at::Tensor & multiply_(const at::Scalar & other) const; + at::Tensor mv(const at::Tensor & vec) const; + at::Tensor mvlgamma(int64_t p) const; + at::Tensor & mvlgamma_(int64_t p) const; + at::Tensor narrow_copy(int64_t dim, int64_t start, int64_t length) const; + at::Tensor narrow_copy_symint(int64_t dim, c10::SymInt start, c10::SymInt length) const; + at::Tensor narrow(int64_t dim, int64_t start, int64_t length) const; + at::Tensor narrow_symint(int64_t dim, c10::SymInt start, c10::SymInt length) const; + at::Tensor narrow(int64_t dim, const at::Tensor & start, int64_t length) const; + at::Tensor narrow_symint(int64_t dim, const at::Tensor & start, c10::SymInt length) const; + at::Tensor permute(at::IntArrayRef dims) const; + at::Tensor movedim(at::IntArrayRef source, at::IntArrayRef destination) const; + at::Tensor movedim(int64_t source, int64_t destination) const; + at::Tensor moveaxis(at::IntArrayRef source, at::IntArrayRef destination) const; + at::Tensor moveaxis(int64_t source, int64_t destination) const; + at::Tensor numpy_T() const; + at::Tensor matrix_H() const; + at::Tensor mT() const; + at::Tensor mH() const; + at::Tensor adjoint() const; + bool is_pinned(::std::optional device=::std::nullopt) const; + at::Tensor pin_memory(::std::optional device=::std::nullopt) const; + at::Tensor pinverse(double rcond=1e-15) const; + at::Tensor rad2deg() const; + at::Tensor & rad2deg_() const; + at::Tensor deg2rad() const; + at::Tensor & deg2rad_() const; + at::Tensor ravel() const; + at::Tensor reciprocal() const; + at::Tensor & reciprocal_() const; + at::Tensor neg() const; + at::Tensor & neg_() const; + at::Tensor negative() const; + at::Tensor & negative_() const; + at::Tensor repeat(at::IntArrayRef repeats) const; + at::Tensor repeat_symint(c10::SymIntArrayRef repeats) const; + at::Tensor repeat_interleave(const at::Tensor & repeats, ::std::optional dim=::std::nullopt, ::std::optional output_size=::std::nullopt) const; + at::Tensor repeat_interleave_symint(const at::Tensor & repeats, ::std::optional dim=::std::nullopt, ::std::optional output_size=::std::nullopt) const; + at::Tensor repeat_interleave(int64_t repeats, ::std::optional dim=::std::nullopt, ::std::optional output_size=::std::nullopt) const; + at::Tensor repeat_interleave_symint(c10::SymInt repeats, ::std::optional dim=::std::nullopt, ::std::optional output_size=::std::nullopt) const; + at::Tensor reshape(at::IntArrayRef shape) const; + at::Tensor reshape_symint(c10::SymIntArrayRef shape) const; + at::Tensor _reshape_alias(at::IntArrayRef size, at::IntArrayRef stride) const; + at::Tensor _reshape_alias_symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride) const; + at::Tensor reshape_as(const at::Tensor & other) const; + at::Tensor round() const; + at::Tensor & round_() const; + at::Tensor round(int64_t decimals) const; + at::Tensor & round_(int64_t decimals) const; + at::Tensor relu() const; + at::Tensor & relu_() const; + at::Tensor prelu(const at::Tensor & weight) const; + at::Tensor hardshrink(const at::Scalar & lambd=0.5) const; + at::Tensor hardshrink_backward(const at::Tensor & grad_out, const at::Scalar & lambd) const; + at::Tensor rsqrt() const; + at::Tensor & rsqrt_() const; + at::Tensor select(at::Dimname dim, int64_t index) const; + at::Tensor select(int64_t dim, int64_t index) const; + at::Tensor select_symint(int64_t dim, c10::SymInt index) const; + at::Tensor sigmoid() const; + at::Tensor & sigmoid_() const; + at::Tensor logit(::std::optional eps=::std::nullopt) const; + at::Tensor & logit_(::std::optional eps=::std::nullopt) const; + at::Tensor sin() const; + at::Tensor & sin_() const; + at::Tensor sinc() const; + at::Tensor & sinc_() const; + at::Tensor sinh() const; + at::Tensor & sinh_() const; + at::Tensor detach() const; + at::Tensor & detach_() const; + int64_t size(at::Dimname dim) const; + at::Tensor slice(int64_t dim=0, ::std::optional start=::std::nullopt, ::std::optional end=::std::nullopt, int64_t step=1) const; + at::Tensor slice_symint(int64_t dim=0, ::std::optional start=::std::nullopt, ::std::optional end=::std::nullopt, c10::SymInt step=1) const; + at::Tensor slice_inverse(const at::Tensor & src, int64_t dim=0, ::std::optional start=::std::nullopt, ::std::optional end=::std::nullopt, int64_t step=1) const; + at::Tensor slice_inverse_symint(const at::Tensor & src, int64_t dim=0, ::std::optional start=::std::nullopt, ::std::optional end=::std::nullopt, c10::SymInt step=1) const; + at::Tensor slice_scatter(const at::Tensor & src, int64_t dim=0, ::std::optional start=::std::nullopt, ::std::optional end=::std::nullopt, int64_t step=1) const; + at::Tensor slice_scatter_symint(const at::Tensor & src, int64_t dim=0, ::std::optional start=::std::nullopt, ::std::optional end=::std::nullopt, c10::SymInt step=1) const; + at::Tensor select_scatter(const at::Tensor & src, int64_t dim, int64_t index) const; + at::Tensor select_scatter_symint(const at::Tensor & src, int64_t dim, c10::SymInt index) const; + at::Tensor diagonal_scatter(const at::Tensor & src, int64_t offset=0, int64_t dim1=0, int64_t dim2=1) const; + at::Tensor as_strided_scatter(const at::Tensor & src, at::IntArrayRef size, at::IntArrayRef stride, ::std::optional storage_offset=::std::nullopt) const; + at::Tensor as_strided_scatter_symint(const at::Tensor & src, c10::SymIntArrayRef size, c10::SymIntArrayRef stride, ::std::optional storage_offset=::std::nullopt) const; + at::Tensor smm(const at::Tensor & mat2) const; + at::Tensor softmax(int64_t dim, ::std::optional dtype=::std::nullopt) const; + at::Tensor softmax(at::Dimname dim, ::std::optional dtype=::std::nullopt) const; + ::std::vector unsafe_split(int64_t split_size, int64_t dim=0) const; + ::std::vector unsafe_split_symint(c10::SymInt split_size, int64_t dim=0) const; + ::std::vector split(int64_t split_size, int64_t dim=0) const; + ::std::vector split_symint(c10::SymInt split_size, int64_t dim=0) const; + ::std::vector split(at::IntArrayRef split_size, int64_t dim=0) const; + ::std::vector split_symint(c10::SymIntArrayRef split_size, int64_t dim=0) const; + ::std::vector unsafe_split_with_sizes(at::IntArrayRef split_sizes, int64_t dim=0) const; + ::std::vector unsafe_split_with_sizes_symint(c10::SymIntArrayRef split_sizes, int64_t dim=0) const; + ::std::vector split_with_sizes(at::IntArrayRef split_sizes, int64_t dim=0) const; + ::std::vector split_with_sizes_symint(c10::SymIntArrayRef split_sizes, int64_t dim=0) const; + ::std::vector hsplit(int64_t sections) const; + ::std::vector hsplit(at::IntArrayRef indices) const; + ::std::vector vsplit(int64_t sections) const; + ::std::vector vsplit(at::IntArrayRef indices) const; + ::std::vector dsplit(int64_t sections) const; + ::std::vector dsplit(at::IntArrayRef indices) const; + at::Tensor squeeze() const; + at::Tensor squeeze(int64_t dim) const; + at::Tensor squeeze(at::Dimname dim) const; + at::Tensor squeeze(at::IntArrayRef dim) const; + at::Tensor & squeeze_() const; + at::Tensor & squeeze_(int64_t dim) const; + at::Tensor & squeeze_(at::IntArrayRef dim) const; + at::Tensor & squeeze_(at::Dimname dim) const; + at::Tensor sspaddmm(const at::Tensor & mat1, const at::Tensor & mat2, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor stft(int64_t n_fft, ::std::optional hop_length, ::std::optional win_length, const ::std::optional & window, bool normalized, ::std::optional onesided=::std::nullopt, ::std::optional return_complex=::std::nullopt, ::std::optional align_to_window=::std::nullopt) const; + at::Tensor stft(int64_t n_fft, ::std::optional hop_length=::std::nullopt, ::std::optional win_length=::std::nullopt, const ::std::optional & window={}, bool center=true, c10::string_view pad_mode="reflect", bool normalized=false, ::std::optional onesided=::std::nullopt, ::std::optional return_complex=::std::nullopt, ::std::optional align_to_window=::std::nullopt) const; + at::Tensor istft(int64_t n_fft, ::std::optional hop_length=::std::nullopt, ::std::optional win_length=::std::nullopt, const ::std::optional & window={}, bool center=true, bool normalized=false, ::std::optional onesided=::std::nullopt, ::std::optional length=::std::nullopt, bool return_complex=false) const; + int64_t stride(at::Dimname dim) const; + at::Tensor sum(::std::optional dtype=::std::nullopt) const; + at::Tensor sum(at::OptionalIntArrayRef dim, bool keepdim=false, ::std::optional dtype=::std::nullopt) const; + at::Tensor sum(at::DimnameList dim, bool keepdim=false, ::std::optional dtype=::std::nullopt) const; + at::Tensor nansum(at::OptionalIntArrayRef dim=::std::nullopt, bool keepdim=false, ::std::optional dtype=::std::nullopt) const; + at::Tensor sum_to_size(at::IntArrayRef size) const; + at::Tensor sum_to_size_symint(c10::SymIntArrayRef size) const; + at::Tensor sqrt() const; + at::Tensor & sqrt_() const; + at::Tensor square() const; + at::Tensor & square_() const; + at::Tensor std(bool unbiased) const; + at::Tensor std(at::OptionalIntArrayRef dim, bool unbiased, bool keepdim=false) const; + at::Tensor std(at::OptionalIntArrayRef dim=::std::nullopt, const ::std::optional & correction=::std::nullopt, bool keepdim=false) const; + at::Tensor std(at::DimnameList dim, bool unbiased, bool keepdim=false) const; + at::Tensor std(at::DimnameList dim, const ::std::optional & correction=::std::nullopt, bool keepdim=false) const; + at::Tensor prod(::std::optional dtype=::std::nullopt) const; + at::Tensor prod(int64_t dim, bool keepdim=false, ::std::optional dtype=::std::nullopt) const; + at::Tensor prod(at::Dimname dim, bool keepdim=false, ::std::optional dtype=::std::nullopt) const; + at::Tensor t() const; + at::Tensor & t_() const; + at::Tensor tan() const; + at::Tensor & tan_() const; + at::Tensor tanh() const; + at::Tensor & tanh_() const; + at::Tensor tile(at::IntArrayRef dims) const; + at::Tensor tile_symint(c10::SymIntArrayRef dims) const; + at::Tensor transpose(int64_t dim0, int64_t dim1) const; + at::Tensor transpose(at::Dimname dim0, at::Dimname dim1) const; + at::Tensor & transpose_(int64_t dim0, int64_t dim1) const; + at::Tensor flip(at::IntArrayRef dims) const; + at::Tensor fliplr() const; + at::Tensor flipud() const; + at::Tensor roll(at::IntArrayRef shifts, at::IntArrayRef dims={}) const; + at::Tensor roll_symint(c10::SymIntArrayRef shifts, at::IntArrayRef dims={}) const; + at::Tensor rot90(int64_t k=1, at::IntArrayRef dims={0,1}) const; + at::Tensor _nested_tensor_size() const; + at::Tensor _nested_tensor_strides() const; + at::Tensor _nested_tensor_storage_offsets() const; + at::Tensor trunc() const; + at::Tensor & trunc_() const; + at::Tensor fix() const; + at::Tensor & fix_() const; + at::Tensor type_as(const at::Tensor & other) const; + at::Tensor unsqueeze(int64_t dim) const; + at::Tensor & unsqueeze_(int64_t dim) const; + at::Tensor var(bool unbiased) const; + at::Tensor var(at::OptionalIntArrayRef dim, bool unbiased, bool keepdim=false) const; + at::Tensor var(at::OptionalIntArrayRef dim=::std::nullopt, const ::std::optional & correction=::std::nullopt, bool keepdim=false) const; + at::Tensor var(at::DimnameList dim, bool unbiased, bool keepdim=false) const; + at::Tensor var(at::DimnameList dim, const ::std::optional & correction=::std::nullopt, bool keepdim=false) const; + at::Tensor view_as(const at::Tensor & other) const; + at::Tensor where(const at::Tensor & condition, const at::Tensor & other) const; + at::Tensor where(const at::Tensor & condition, const at::Scalar & other) const; + at::Tensor norm(const ::std::optional & p, at::ScalarType dtype) const; + at::Tensor norm(const at::Scalar & p=2) const; + at::Tensor norm(const ::std::optional & p, at::IntArrayRef dim, bool keepdim, at::ScalarType dtype) const; + at::Tensor norm(const ::std::optional & p, at::IntArrayRef dim, bool keepdim=false) const; + at::Tensor norm(const ::std::optional & p, at::DimnameList dim, bool keepdim, at::ScalarType dtype) const; + at::Tensor norm(const ::std::optional & p, at::DimnameList dim, bool keepdim=false) const; + ::std::tuple frexp() const; + at::Tensor clone(::std::optional memory_format=::std::nullopt) const; + at::Tensor positive() const; + const at::Tensor & resize_as_(const at::Tensor & the_template, ::std::optional memory_format=::std::nullopt) const; + const at::Tensor & resize_as_sparse_(const at::Tensor & the_template) const; + at::Tensor & zero_() const; + at::Tensor sub(const at::Tensor & other, const at::Scalar & alpha=1) const; + at::Tensor & sub_(const at::Tensor & other, const at::Scalar & alpha=1) const; + at::Tensor sub(const at::Scalar & other, const at::Scalar & alpha=1) const; + at::Tensor & sub_(const at::Scalar & other, const at::Scalar & alpha=1) const; + at::Tensor subtract(const at::Tensor & other, const at::Scalar & alpha=1) const; + at::Tensor & subtract_(const at::Tensor & other, const at::Scalar & alpha=1) const; + at::Tensor subtract(const at::Scalar & other, const at::Scalar & alpha=1) const; + at::Tensor & subtract_(const at::Scalar & other, const at::Scalar & alpha=1) const; + at::Tensor heaviside(const at::Tensor & values) const; + at::Tensor & heaviside_(const at::Tensor & values) const; + at::Tensor addmm(const at::Tensor & mat1, const at::Tensor & mat2, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor & addmm_(const at::Tensor & mat1, const at::Tensor & mat2, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor _addmm_activation(const at::Tensor & mat1, const at::Tensor & mat2, const at::Scalar & beta=1, const at::Scalar & alpha=1, bool use_gelu=false) const; + const at::Tensor & sparse_resize_(at::IntArrayRef size, int64_t sparse_dim, int64_t dense_dim) const; + const at::Tensor & sparse_resize_and_clear_(at::IntArrayRef size, int64_t sparse_dim, int64_t dense_dim) const; + at::Tensor sparse_mask(const at::Tensor & mask) const; + at::Tensor _sparse_mask_projection(const at::Tensor & mask, bool accumulate_matches=false) const; + at::Tensor to_dense(::std::optional dtype=::std::nullopt, ::std::optional masked_grad=::std::nullopt) const; + at::Tensor _to_dense(::std::optional dtype=::std::nullopt, ::std::optional masked_grad=::std::nullopt) const; + int64_t sparse_dim() const; + int64_t _dimI() const; + int64_t dense_dim() const; + int64_t _dimV() const; + int64_t _nnz() const; + at::Tensor coalesce() const; + bool is_coalesced() const; + at::Tensor _indices() const; + at::Tensor _values() const; + at::Tensor & _coalesced_(bool coalesced) const; + at::Tensor indices() const; + at::Tensor values() const; + at::Tensor crow_indices() const; + at::Tensor col_indices() const; + at::Tensor ccol_indices() const; + at::Tensor row_indices() const; + ::std::vector unbind(int64_t dim=0) const; + ::std::vector unbind(at::Dimname dim) const; + at::Tensor to_sparse(int64_t sparse_dim) const; + at::Tensor _to_sparse(int64_t sparse_dim) const; + at::Tensor to_sparse(::std::optional layout=::std::nullopt, at::OptionalIntArrayRef blocksize=::std::nullopt, ::std::optional dense_dim=::std::nullopt) const; + at::Tensor _to_sparse(::std::optional layout=::std::nullopt, at::OptionalIntArrayRef blocksize=::std::nullopt, ::std::optional dense_dim=::std::nullopt) const; + at::Tensor to_sparse_csr(::std::optional dense_dim=::std::nullopt) const; + at::Tensor _to_sparse_csr(::std::optional dense_dim=::std::nullopt) const; + at::Tensor to_sparse_csc(::std::optional dense_dim=::std::nullopt) const; + at::Tensor _to_sparse_csc(::std::optional dense_dim=::std::nullopt) const; + at::Tensor to_sparse_bsr(at::IntArrayRef blocksize, ::std::optional dense_dim=::std::nullopt) const; + at::Tensor _to_sparse_bsr(at::IntArrayRef blocksize, ::std::optional dense_dim=::std::nullopt) const; + at::Tensor to_sparse_bsc(at::IntArrayRef blocksize, ::std::optional dense_dim=::std::nullopt) const; + at::Tensor _to_sparse_bsc(at::IntArrayRef blocksize, ::std::optional dense_dim=::std::nullopt) const; + at::Tensor to_mkldnn(::std::optional dtype=::std::nullopt) const; + at::Tensor dequantize() const; + double q_scale() const; + int64_t q_zero_point() const; + at::Tensor q_per_channel_scales() const; + at::Tensor q_per_channel_zero_points() const; + int64_t q_per_channel_axis() const; + at::Tensor int_repr() const; + at::QScheme qscheme() const; + at::Tensor _autocast_to_reduced_precision(bool cuda_enabled, bool cpu_enabled, at::ScalarType cuda_dtype, at::ScalarType cpu_dtype) const; + at::Tensor _autocast_to_full_precision(bool cuda_enabled, bool cpu_enabled) const; + at::Tensor to(at::TensorOptions options={}, bool non_blocking=false, bool copy=false, ::std::optional memory_format=::std::nullopt) const; + at::Tensor to(::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory, bool non_blocking, bool copy, ::std::optional memory_format) const; + at::Tensor to(at::Device device, at::ScalarType dtype, bool non_blocking=false, bool copy=false, ::std::optional memory_format=::std::nullopt) const; + at::Tensor to(at::ScalarType dtype, bool non_blocking=false, bool copy=false, ::std::optional memory_format=::std::nullopt) const; + at::Tensor to(const at::Tensor & other, bool non_blocking=false, bool copy=false, ::std::optional memory_format=::std::nullopt) const; + at::Scalar item() const; + at::Tensor & set_(at::Storage source) const; + at::Tensor & set_(at::Storage source, int64_t storage_offset, at::IntArrayRef size, at::IntArrayRef stride={}) const; + at::Tensor & set__symint(at::Storage source, c10::SymInt storage_offset, c10::SymIntArrayRef size, c10::SymIntArrayRef stride={}) const; + at::Tensor & set_(const at::Tensor & source, int64_t storage_offset, at::IntArrayRef size, at::IntArrayRef stride={}) const; + at::Tensor & set__symint(const at::Tensor & source, c10::SymInt storage_offset, c10::SymIntArrayRef size, c10::SymIntArrayRef stride={}) const; + at::Tensor & set_(const at::Tensor & source) const; + at::Tensor & set_() const; + bool is_set_to(const at::Tensor & tensor) const; + at::Tensor & masked_fill_(const at::Tensor & mask, const at::Scalar & value) const; + at::Tensor masked_fill(const at::Tensor & mask, const at::Scalar & value) const; + at::Tensor & masked_fill_(const at::Tensor & mask, const at::Tensor & value) const; + at::Tensor masked_fill(const at::Tensor & mask, const at::Tensor & value) const; + at::Tensor & masked_scatter_(const at::Tensor & mask, const at::Tensor & source) const; + at::Tensor masked_scatter(const at::Tensor & mask, const at::Tensor & source) const; + at::Tensor view(at::IntArrayRef size) const; + at::Tensor view_symint(c10::SymIntArrayRef size) const; + at::Tensor view(at::ScalarType dtype) const; + at::Tensor & put_(const at::Tensor & index, const at::Tensor & source, bool accumulate=false) const; + at::Tensor put(const at::Tensor & index, const at::Tensor & source, bool accumulate=false) const; + at::Tensor & index_add_(int64_t dim, const at::Tensor & index, const at::Tensor & source, const at::Scalar & alpha=1) const; + at::Tensor index_add(int64_t dim, const at::Tensor & index, const at::Tensor & source, const at::Scalar & alpha=1) const; + at::Tensor index_add(at::Dimname dim, const at::Tensor & index, const at::Tensor & source, const at::Scalar & alpha=1) const; + at::Tensor & index_reduce_(int64_t dim, const at::Tensor & index, const at::Tensor & source, c10::string_view reduce, bool include_self=true) const; + at::Tensor index_reduce(int64_t dim, const at::Tensor & index, const at::Tensor & source, c10::string_view reduce, bool include_self=true) const; + at::Tensor & index_fill_(int64_t dim, const at::Tensor & index, const at::Scalar & value) const; + at::Tensor index_fill(int64_t dim, const at::Tensor & index, const at::Scalar & value) const; + at::Tensor & index_fill_(int64_t dim, const at::Tensor & index, const at::Tensor & value) const; + at::Tensor index_fill(int64_t dim, const at::Tensor & index, const at::Tensor & value) const; + at::Tensor & index_fill_(at::Dimname dim, const at::Tensor & index, const at::Scalar & value) const; + at::Tensor & index_fill_(at::Dimname dim, const at::Tensor & index, const at::Tensor & value) const; + at::Tensor index_fill(at::Dimname dim, const at::Tensor & index, const at::Scalar & value) const; + at::Tensor index_fill(at::Dimname dim, const at::Tensor & index, const at::Tensor & value) const; + at::Tensor scatter(int64_t dim, const at::Tensor & index, const at::Tensor & src) const; + at::Tensor & scatter_(int64_t dim, const at::Tensor & index, const at::Tensor & src) const; + at::Tensor scatter(int64_t dim, const at::Tensor & index, const at::Scalar & value) const; + at::Tensor & scatter_(int64_t dim, const at::Tensor & index, const at::Scalar & value) const; + at::Tensor scatter(int64_t dim, const at::Tensor & index, const at::Tensor & src, c10::string_view reduce) const; + at::Tensor & scatter_(int64_t dim, const at::Tensor & index, const at::Tensor & src, c10::string_view reduce) const; + at::Tensor scatter(int64_t dim, const at::Tensor & index, const at::Scalar & value, c10::string_view reduce) const; + at::Tensor & scatter_(int64_t dim, const at::Tensor & index, const at::Scalar & value, c10::string_view reduce) const; + at::Tensor scatter(at::Dimname dim, const at::Tensor & index, const at::Tensor & src) const; + at::Tensor scatter(at::Dimname dim, const at::Tensor & index, const at::Scalar & value) const; + at::Tensor scatter_add(int64_t dim, const at::Tensor & index, const at::Tensor & src) const; + at::Tensor & scatter_add_(int64_t dim, const at::Tensor & index, const at::Tensor & src) const; + at::Tensor scatter_add(at::Dimname dim, const at::Tensor & index, const at::Tensor & src) const; + at::Tensor scatter_reduce(int64_t dim, const at::Tensor & index, const at::Tensor & src, c10::string_view reduce, bool include_self=true) const; + at::Tensor & scatter_reduce_(int64_t dim, const at::Tensor & index, const at::Tensor & src, c10::string_view reduce, bool include_self=true) const; + at::Tensor & eq_(const at::Scalar & other) const; + at::Tensor & eq_(const at::Tensor & other) const; + at::Tensor bitwise_and(const at::Scalar & other) const; + at::Tensor bitwise_and(const at::Tensor & other) const; + at::Tensor & bitwise_and_(const at::Scalar & other) const; + at::Tensor & bitwise_and_(const at::Tensor & other) const; + at::Tensor __and__(const at::Scalar & other) const; + at::Tensor __and__(const at::Tensor & other) const; + at::Tensor & __iand__(const at::Scalar & other) const; + at::Tensor & __iand__(const at::Tensor & other) const; + at::Tensor bitwise_or(const at::Scalar & other) const; + at::Tensor bitwise_or(const at::Tensor & other) const; + at::Tensor & bitwise_or_(const at::Scalar & other) const; + at::Tensor & bitwise_or_(const at::Tensor & other) const; + at::Tensor __or__(const at::Scalar & other) const; + at::Tensor __or__(const at::Tensor & other) const; + at::Tensor & __ior__(const at::Scalar & other) const; + at::Tensor & __ior__(const at::Tensor & other) const; + at::Tensor bitwise_xor(const at::Scalar & other) const; + at::Tensor bitwise_xor(const at::Tensor & other) const; + at::Tensor & bitwise_xor_(const at::Scalar & other) const; + at::Tensor & bitwise_xor_(const at::Tensor & other) const; + at::Tensor __xor__(const at::Scalar & other) const; + at::Tensor __xor__(const at::Tensor & other) const; + at::Tensor & __ixor__(const at::Scalar & other) const; + at::Tensor & __ixor__(const at::Tensor & other) const; + at::Tensor __lshift__(const at::Scalar & other) const; + at::Tensor __lshift__(const at::Tensor & other) const; + at::Tensor & __ilshift__(const at::Scalar & other) const; + at::Tensor & __ilshift__(const at::Tensor & other) const; + at::Tensor bitwise_left_shift(const at::Tensor & other) const; + at::Tensor & bitwise_left_shift_(const at::Tensor & other) const; + at::Tensor bitwise_left_shift(const at::Scalar & other) const; + at::Tensor & bitwise_left_shift_(const at::Scalar & other) const; + at::Tensor __rshift__(const at::Scalar & other) const; + at::Tensor __rshift__(const at::Tensor & other) const; + at::Tensor & __irshift__(const at::Scalar & other) const; + at::Tensor & __irshift__(const at::Tensor & other) const; + at::Tensor bitwise_right_shift(const at::Tensor & other) const; + at::Tensor & bitwise_right_shift_(const at::Tensor & other) const; + at::Tensor bitwise_right_shift(const at::Scalar & other) const; + at::Tensor & bitwise_right_shift_(const at::Scalar & other) const; + at::Tensor & tril_(int64_t diagonal=0) const; + at::Tensor & triu_(int64_t diagonal=0) const; + at::Tensor & digamma_() const; + at::Tensor & lerp_(const at::Tensor & end, const at::Scalar & weight) const; + at::Tensor & lerp_(const at::Tensor & end, const at::Tensor & weight) const; + at::Tensor & addbmm_(const at::Tensor & batch1, const at::Tensor & batch2, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor addbmm(const at::Tensor & batch1, const at::Tensor & batch2, const at::Scalar & beta=1, const at::Scalar & alpha=1) const; + at::Tensor & random_(int64_t from, ::std::optional to, ::std::optional generator=::std::nullopt) const; + at::Tensor & random_(int64_t to, ::std::optional generator=::std::nullopt) const; + at::Tensor & random_(::std::optional generator=::std::nullopt) const; + at::Tensor & uniform_(double from=0, double to=1, ::std::optional generator=::std::nullopt) const; + at::Tensor & cauchy_(double median=0, double sigma=1, ::std::optional generator=::std::nullopt) const; + at::Tensor & log_normal_(double mean=1, double std=2, ::std::optional generator=::std::nullopt) const; + at::Tensor & exponential_(double lambd=1, ::std::optional generator=::std::nullopt) const; + at::Tensor & geometric_(double p, ::std::optional generator=::std::nullopt) const; + at::Tensor diag(int64_t diagonal=0) const; + at::Tensor cross(const at::Tensor & other, ::std::optional dim=::std::nullopt) const; + at::Tensor triu(int64_t diagonal=0) const; + at::Tensor tril(int64_t diagonal=0) const; + at::Tensor trace() const; + at::Tensor ne(const at::Scalar & other) const; + at::Tensor ne(const at::Tensor & other) const; + at::Tensor & ne_(const at::Scalar & other) const; + at::Tensor & ne_(const at::Tensor & other) const; + at::Tensor not_equal(const at::Scalar & other) const; + at::Tensor not_equal(const at::Tensor & other) const; + at::Tensor & not_equal_(const at::Scalar & other) const; + at::Tensor & not_equal_(const at::Tensor & other) const; + at::Tensor eq(const at::Scalar & other) const; + at::Tensor eq(const at::Tensor & other) const; + at::Tensor ge(const at::Scalar & other) const; + at::Tensor ge(const at::Tensor & other) const; + at::Tensor & ge_(const at::Scalar & other) const; + at::Tensor & ge_(const at::Tensor & other) const; + at::Tensor greater_equal(const at::Scalar & other) const; + at::Tensor greater_equal(const at::Tensor & other) const; + at::Tensor & greater_equal_(const at::Scalar & other) const; + at::Tensor & greater_equal_(const at::Tensor & other) const; + at::Tensor le(const at::Scalar & other) const; + at::Tensor le(const at::Tensor & other) const; + at::Tensor & le_(const at::Scalar & other) const; + at::Tensor & le_(const at::Tensor & other) const; + at::Tensor less_equal(const at::Scalar & other) const; + at::Tensor less_equal(const at::Tensor & other) const; + at::Tensor & less_equal_(const at::Scalar & other) const; + at::Tensor & less_equal_(const at::Tensor & other) const; + at::Tensor gt(const at::Scalar & other) const; + at::Tensor gt(const at::Tensor & other) const; + at::Tensor & gt_(const at::Scalar & other) const; + at::Tensor & gt_(const at::Tensor & other) const; + at::Tensor greater(const at::Scalar & other) const; + at::Tensor greater(const at::Tensor & other) const; + at::Tensor & greater_(const at::Scalar & other) const; + at::Tensor & greater_(const at::Tensor & other) const; + at::Tensor lt(const at::Scalar & other) const; + at::Tensor lt(const at::Tensor & other) const; + at::Tensor & lt_(const at::Scalar & other) const; + at::Tensor & lt_(const at::Tensor & other) const; + at::Tensor less(const at::Scalar & other) const; + at::Tensor less(const at::Tensor & other) const; + at::Tensor & less_(const at::Scalar & other) const; + at::Tensor & less_(const at::Tensor & other) const; + at::Tensor take(const at::Tensor & index) const; + at::Tensor take_along_dim(const at::Tensor & indices, ::std::optional dim=::std::nullopt) const; + at::Tensor index_select(int64_t dim, const at::Tensor & index) const; + at::Tensor index_select(at::Dimname dim, const at::Tensor & index) const; + at::Tensor masked_select(const at::Tensor & mask) const; + at::Tensor nonzero() const; + at::Tensor nonzero_static(int64_t size, int64_t fill_value=-1) const; + at::Tensor nonzero_static_symint(c10::SymInt size, int64_t fill_value=-1) const; + ::std::vector nonzero_numpy() const; + at::Tensor argwhere() const; + at::Tensor gather(int64_t dim, const at::Tensor & index, bool sparse_grad=false) const; + at::Tensor gather(at::Dimname dim, const at::Tensor & index, bool sparse_grad=false) const; + at::Tensor addcmul(const at::Tensor & tensor1, const at::Tensor & tensor2, const at::Scalar & value=1) const; + at::Tensor & addcmul_(const at::Tensor & tensor1, const at::Tensor & tensor2, const at::Scalar & value=1) const; + at::Tensor addcdiv(const at::Tensor & tensor1, const at::Tensor & tensor2, const at::Scalar & value=1) const; + at::Tensor & addcdiv_(const at::Tensor & tensor1, const at::Tensor & tensor2, const at::Scalar & value=1) const; + ::std::tuple triangular_solve(const at::Tensor & A, bool upper=true, bool transpose=false, bool unitriangular=false) const; + ::std::tuple svd(bool some=true, bool compute_uv=true) const; + at::Tensor swapaxes(int64_t axis0, int64_t axis1) const; + at::Tensor & swapaxes_(int64_t axis0, int64_t axis1) const; + at::Tensor swapdims(int64_t dim0, int64_t dim1) const; + at::Tensor & swapdims_(int64_t dim0, int64_t dim1) const; + at::Tensor cholesky(bool upper=false) const; + at::Tensor cholesky_solve(const at::Tensor & input2, bool upper=false) const; + at::Tensor cholesky_inverse(bool upper=false) const; + ::std::tuple qr(bool some=true) const; + ::std::tuple geqrf() const; + at::Tensor orgqr(const at::Tensor & input2) const; + at::Tensor ormqr(const at::Tensor & input2, const at::Tensor & input3, bool left=true, bool transpose=false) const; + at::Tensor lu_solve(const at::Tensor & LU_data, const at::Tensor & LU_pivots) const; + at::Tensor multinomial(int64_t num_samples, bool replacement=false, ::std::optional generator=::std::nullopt) const; + at::Tensor & lgamma_() const; + at::Tensor lgamma() const; + at::Tensor digamma() const; + at::Tensor polygamma(int64_t n) const; + at::Tensor & polygamma_(int64_t n) const; + at::Tensor erfinv() const; + at::Tensor & erfinv_() const; + at::Tensor i0() const; + at::Tensor & i0_() const; + at::Tensor sign() const; + at::Tensor & sign_() const; + at::Tensor signbit() const; + at::Tensor dist(const at::Tensor & other, const at::Scalar & p=2) const; + at::Tensor & atan2_(const at::Tensor & other) const; + at::Tensor atan2(const at::Tensor & other) const; + at::Tensor arctan2(const at::Tensor & other) const; + at::Tensor & arctan2_(const at::Tensor & other) const; + at::Tensor lerp(const at::Tensor & end, const at::Scalar & weight) const; + at::Tensor lerp(const at::Tensor & end, const at::Tensor & weight) const; + at::Tensor histc(int64_t bins=100, const at::Scalar & min=0, const at::Scalar & max=0) const; + ::std::tuple histogram(const at::Tensor & bins, const ::std::optional & weight={}, bool density=false) const; + ::std::tuple histogram(int64_t bins=100, ::std::optional> range=::std::nullopt, const ::std::optional & weight={}, bool density=false) const; + at::Tensor fmod(const at::Scalar & other) const; + at::Tensor & fmod_(const at::Scalar & other) const; + at::Tensor fmod(const at::Tensor & other) const; + at::Tensor & fmod_(const at::Tensor & other) const; + at::Tensor hypot(const at::Tensor & other) const; + at::Tensor & hypot_(const at::Tensor & other) const; + at::Tensor igamma(const at::Tensor & other) const; + at::Tensor & igamma_(const at::Tensor & other) const; + at::Tensor igammac(const at::Tensor & other) const; + at::Tensor & igammac_(const at::Tensor & other) const; + at::Tensor nextafter(const at::Tensor & other) const; + at::Tensor & nextafter_(const at::Tensor & other) const; + at::Tensor remainder(const at::Scalar & other) const; + at::Tensor & remainder_(const at::Scalar & other) const; + at::Tensor remainder(const at::Tensor & other) const; + at::Tensor & remainder_(const at::Tensor & other) const; + at::Tensor min() const; + at::Tensor fmin(const at::Tensor & other) const; + at::Tensor max() const; + at::Tensor fmax(const at::Tensor & other) const; + at::Tensor maximum(const at::Tensor & other) const; + at::Tensor max(const at::Tensor & other) const; + at::Tensor minimum(const at::Tensor & other) const; + at::Tensor min(const at::Tensor & other) const; + at::Tensor quantile(const at::Tensor & q, ::std::optional dim=::std::nullopt, bool keepdim=false, c10::string_view interpolation="linear") const; + at::Tensor quantile(double q, ::std::optional dim=::std::nullopt, bool keepdim=false, c10::string_view interpolation="linear") const; + at::Tensor nanquantile(const at::Tensor & q, ::std::optional dim=::std::nullopt, bool keepdim=false, c10::string_view interpolation="linear") const; + at::Tensor nanquantile(double q, ::std::optional dim=::std::nullopt, bool keepdim=false, c10::string_view interpolation="linear") const; + ::std::tuple sort(int64_t dim=-1, bool descending=false) const; + ::std::tuple sort(::std::optional stable, int64_t dim=-1, bool descending=false) const; + ::std::tuple sort(at::Dimname dim, bool descending=false) const; + ::std::tuple sort(::std::optional stable, at::Dimname dim, bool descending=false) const; + at::Tensor msort() const; + at::Tensor argsort(int64_t dim=-1, bool descending=false) const; + at::Tensor argsort(bool stable, int64_t dim=-1, bool descending=false) const; + at::Tensor argsort(at::Dimname dim, bool descending=false) const; + ::std::tuple topk(int64_t k, int64_t dim=-1, bool largest=true, bool sorted=true) const; + ::std::tuple topk_symint(c10::SymInt k, int64_t dim=-1, bool largest=true, bool sorted=true) const; + at::Tensor all() const; + at::Tensor any() const; + at::Tensor renorm(const at::Scalar & p, int64_t dim, const at::Scalar & maxnorm) const; + at::Tensor & renorm_(const at::Scalar & p, int64_t dim, const at::Scalar & maxnorm) const; + at::Tensor unfold(int64_t dimension, int64_t size, int64_t step) const; + bool equal(const at::Tensor & other) const; + at::Tensor pow(const at::Tensor & exponent) const; + at::Tensor pow(const at::Scalar & exponent) const; + at::Tensor & pow_(const at::Scalar & exponent) const; + at::Tensor & pow_(const at::Tensor & exponent) const; + at::Tensor float_power(const at::Tensor & exponent) const; + at::Tensor float_power(const at::Scalar & exponent) const; + at::Tensor & float_power_(const at::Scalar & exponent) const; + at::Tensor & float_power_(const at::Tensor & exponent) const; + at::Tensor & normal_(double mean=0, double std=1, ::std::optional generator=::std::nullopt) const; + at::Tensor alias() const; + at::Tensor isfinite() const; + at::Tensor isinf() const; + void record_stream(at::Stream s) const; + at::Tensor isposinf() const; + at::Tensor isneginf() const; + at::Tensor det() const; + ::std::tuple slogdet() const; + at::Tensor logdet() const; + at::Tensor inverse() const; + at::Tensor inner(const at::Tensor & other) const; + at::Tensor outer(const at::Tensor & vec2) const; + at::Tensor ger(const at::Tensor & vec2) const; + at::Tensor to_padded_tensor(double padding, at::OptionalIntArrayRef output_size=::std::nullopt) const; + at::Tensor to_padded_tensor_symint(double padding, at::OptionalSymIntArrayRef output_size=::std::nullopt) const; + + // Special C++ only overloads for std()-like functions (See gh-40287) + // These are needed because int -> bool conversion takes precedence over int -> IntArrayRef + // So, for example std(0) would select the std(unbiased=False) overload + + Tensor var(int dim) const { + return var(IntArrayRef{dim}); + } + + Tensor std(int dim) const { + return std(IntArrayRef{dim}); + } + + // We changed .dtype() to return a TypeMeta in #12766. Ideally, we want the + // at::kDouble and its friends to be TypeMeta's, but that hasn't happened yet. + // Before that change, we make this method to maintain BC for C++ usage like + // `x.to(y.dtype)`. + // TODO: remove following two after at::kDouble and its friends are TypeMeta's. + inline Tensor to(caffe2::TypeMeta type_meta, bool non_blocking=false, bool copy=false) const { + return this->to(/*scalar_type=*/typeMetaToScalarType(type_meta), non_blocking, copy); + } + inline Tensor to(Device device, caffe2::TypeMeta type_meta, bool non_blocking=false, bool copy=false) const { + return this->to(device, /*scalar_type=*/typeMetaToScalarType(type_meta), non_blocking, copy); + } + + template + decltype(auto) m(F func, Args&&... params) const { + return func(*this, std::forward(params)...); + } + + /// NOTE: This is similar to the legacy `.data()` function on `Variable`, and is intended + /// to be used from functions that need to access the `Variable`'s equivalent `Tensor` + /// (i.e. `Tensor` that shares the same storage and tensor metadata with the `Variable`). + /// + /// One notable difference with the legacy `.data()` function is that changes to the + /// returned `Tensor`'s tensor metadata (e.g. sizes / strides / storage / storage_offset) + /// will not update the original `Variable`, due to the fact that this function + /// shallow-copies the `Variable`'s underlying TensorImpl. + at::Tensor tensor_data() const { + return TensorBase::tensor_data(); + } + + /// NOTE: `var.variable_data()` in C++ has the same semantics as `tensor.data` + /// in Python, which create a new `Variable` that shares the same storage and + /// tensor metadata with the original `Variable`, but with a completely new + /// autograd history. + /// + /// NOTE: If we change the tensor metadata (e.g. sizes / strides / + /// storage / storage_offset) of a variable created from `var.variable_data()`, those + /// changes will not update the original variable `var`. In `.variable_data()`, we set + /// `allow_tensor_metadata_change_` to false to make such changes explicitly illegal, + /// in order to prevent users from changing metadata of `var.variable_data()` + /// and expecting the original variable `var` to also be updated. + at::Tensor variable_data() const { + return TensorBase::variable_data(); + } + + // Hooks + //~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + + template + using hook_return_void_t = std::enable_if_t>::value, unsigned>; + template + using hook_return_var_t = std::enable_if_t, Tensor>, unsigned>; + + /// Registers a backward hook. + /// + /// The hook will be called every time a gradient with respect to the Tensor is computed. + /// The hook should have one of the following signature: + /// ``` + /// hook(Tensor grad) -> Tensor + /// ``` + /// ``` + /// hook(Tensor grad) -> void + /// ``` + /// The hook should not modify its argument, but it can optionally return a new gradient + /// which will be used in place of `grad`. + /// + /// This function returns the index of the hook in the list which can be used to remove hook. + /// + /// Example: + /// @code + /// auto v = torch::tensor({0., 0., 0.}, torch::requires_grad()); + /// auto h = v.register_hook([](torch::Tensor grad){ return grad * 2; }); // double the gradient + /// v.backward(torch::tensor({1., 2., 3.})); + /// // This prints: + /// // ``` + /// // 2 + /// // 4 + /// // 6 + /// // [ CPUFloatType{3} ] + /// // ``` + /// std::cout << v.grad() << std::endl; + /// v.remove_hook(h); // removes the hook + /// @endcode + template + hook_return_void_t register_hook(T&& hook) const; + template + hook_return_var_t register_hook(T&& hook) const; + + // Variable methods + //~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + + Tensor data() const { + return TensorBase::data(); + } + + void _backward(TensorList inputs, const std::optional& gradient, std::optional keep_graph, bool create_graph) const; + + const Tensor& requires_grad_(bool _requires_grad=true) const { + TensorBase::requires_grad_(_requires_grad); + return *this; + } +}; + +namespace detail { +// Helper creator for Tensor class which doesn't requires the users to pass +// in an intrusive_ptr instead it just converts the argument passed to +// requested intrusive_ptr type. +template +Tensor make_tensor(Args&&... args) { + return Tensor(c10::make_intrusive(std::forward(args)...)); +} + +} // namespace detail + +} // namespace at + + +namespace at { + +// aten::_backward(Tensor self, Tensor[] inputs, Tensor? gradient=None, bool? retain_graph=None, bool create_graph=False) -> () +inline void Tensor::__dispatch__backward(at::TensorList inputs, const ::std::optional & gradient, ::std::optional retain_graph, bool create_graph) const { + return at::_ops::_backward::call(const_cast(*this), inputs, gradient, retain_graph, create_graph); +} + +// aten::set_data(Tensor(a!) self, Tensor new_data) -> () +inline void Tensor::__dispatch_set_data(const at::Tensor & new_data) const { + return at::_ops::set_data::call(const_cast(*this), new_data); +} + +// aten::data(Tensor self) -> Tensor +inline at::Tensor Tensor::__dispatch_data() const { + return at::_ops::data::call(const_cast(*this)); +} + +// aten::is_leaf(Tensor self) -> bool +inline bool Tensor::__dispatch_is_leaf() const { + return at::_ops::is_leaf::call(const_cast(*this)); +} + +// aten::output_nr(Tensor self) -> int +inline int64_t Tensor::__dispatch_output_nr() const { + return at::_ops::output_nr::call(const_cast(*this)); +} + +// aten::_version(Tensor self) -> int +inline int64_t Tensor::__dispatch__version() const { + return at::_ops::_version::call(const_cast(*this)); +} + +// aten::requires_grad_(Tensor(a!) self, bool requires_grad=True) -> Tensor(a!) +inline at::Tensor & Tensor::__dispatch_requires_grad_(bool requires_grad) const { + return at::_ops::requires_grad_::call(const_cast(*this), requires_grad); +} + +// aten::retain_grad(Tensor(a!) self) -> () +inline void Tensor::__dispatch_retain_grad() const { + return at::_ops::retain_grad::call(const_cast(*this)); +} + +// aten::retains_grad(Tensor self) -> bool +inline bool Tensor::__dispatch_retains_grad() const { + return at::_ops::retains_grad::call(const_cast(*this)); +} + +// aten::_fw_primal(Tensor(a) self, int level) -> Tensor(a) +inline at::Tensor Tensor::_fw_primal(int64_t level) const { + return at::_ops::_fw_primal::call(const_cast(*this), level); +} + +// aten::rename_(Tensor(a!) self, Dimname[]? names) -> Tensor(a!) +inline at::Tensor & Tensor::rename_(::std::optional names) const { + return at::_ops::rename_::call(const_cast(*this), names); +} + +// aten::rename(Tensor(a) self, Dimname[]? names) -> Tensor(a) +inline at::Tensor Tensor::rename(::std::optional names) const { + return at::_ops::rename::call(const_cast(*this), names); +} + +// aten::align_to(Tensor(a) self, Dimname[] names) -> Tensor(a) +inline at::Tensor Tensor::align_to(at::DimnameList names) const { + return at::_ops::align_to::call(const_cast(*this), names); +} + +// aten::align_to.ellipsis_idx(Tensor(a) self, Dimname[] order, int ellipsis_idx) -> Tensor(a) +inline at::Tensor Tensor::align_to(at::DimnameList order, int64_t ellipsis_idx) const { + return at::_ops::align_to_ellipsis_idx::call(const_cast(*this), order, ellipsis_idx); +} + +// aten::align_as(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::align_as(const at::Tensor & other) const { + return at::_ops::align_as::call(const_cast(*this), other); +} + +// aten::refine_names(Tensor(a) self, Dimname[] names) -> Tensor(a) +inline at::Tensor Tensor::refine_names(at::DimnameList names) const { + return at::_ops::refine_names::call(const_cast(*this), names); +} + +// aten::abs(Tensor self) -> Tensor +inline at::Tensor Tensor::abs() const { + return at::_ops::abs::call(const_cast(*this)); +} + +// aten::abs_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::abs_() const { + return at::_ops::abs_::call(const_cast(*this)); +} + +// aten::absolute(Tensor self) -> Tensor +inline at::Tensor Tensor::absolute() const { + return at::_ops::absolute::call(const_cast(*this)); +} + +// aten::absolute_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::absolute_() const { + return at::_ops::absolute_::call(const_cast(*this)); +} + +// aten::angle(Tensor self) -> Tensor +inline at::Tensor Tensor::angle() const { + return at::_ops::angle::call(const_cast(*this)); +} + +// aten::sgn(Tensor self) -> Tensor +inline at::Tensor Tensor::sgn() const { + return at::_ops::sgn::call(const_cast(*this)); +} + +// aten::sgn_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::sgn_() const { + return at::_ops::sgn_::call(const_cast(*this)); +} + +// aten::chalf(Tensor self, *, MemoryFormat? memory_format=None) -> Tensor +inline at::Tensor Tensor::chalf(::std::optional memory_format) const { + return at::_ops::chalf::call(const_cast(*this), memory_format); +} + +// aten::_conj(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::_conj() const { + return at::_ops::_conj::call(const_cast(*this)); +} + +// aten::conj(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::__dispatch_conj() const { + return at::_ops::conj::call(const_cast(*this)); +} + +// aten::_conj_physical(Tensor self) -> Tensor +inline at::Tensor Tensor::_conj_physical() const { + return at::_ops::_conj_physical::call(const_cast(*this)); +} + +// aten::conj_physical(Tensor self) -> Tensor +inline at::Tensor Tensor::conj_physical() const { + return at::_ops::conj_physical::call(const_cast(*this)); +} + +// aten::conj_physical_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::conj_physical_() const { + return at::_ops::conj_physical_::call(const_cast(*this)); +} + +// aten::resolve_conj(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::resolve_conj() const { + return at::_ops::resolve_conj::call(const_cast(*this)); +} + +// aten::resolve_neg(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::resolve_neg() const { + return at::_ops::resolve_neg::call(const_cast(*this)); +} + +// aten::_neg_view(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::_neg_view() const { + return at::_ops::_neg_view::call(const_cast(*this)); +} + +// aten::acos(Tensor self) -> Tensor +inline at::Tensor Tensor::acos() const { + return at::_ops::acos::call(const_cast(*this)); +} + +// aten::acos_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::acos_() const { + return at::_ops::acos_::call(const_cast(*this)); +} + +// aten::arccos(Tensor self) -> Tensor +inline at::Tensor Tensor::arccos() const { + return at::_ops::arccos::call(const_cast(*this)); +} + +// aten::arccos_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::arccos_() const { + return at::_ops::arccos_::call(const_cast(*this)); +} + +// aten::add.Tensor(Tensor self, Tensor other, *, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::add(const at::Tensor & other, const at::Scalar & alpha) const { + return at::_ops::add_Tensor::call(const_cast(*this), other, alpha); +} + +// aten::add_.Tensor(Tensor(a!) self, Tensor other, *, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::add_(const at::Tensor & other, const at::Scalar & alpha) const { + return at::_ops::add__Tensor::call(const_cast(*this), other, alpha); +} + +// aten::add.Scalar(Tensor self, Scalar other, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::add(const at::Scalar & other, const at::Scalar & alpha) const { + return at::_ops::add_Scalar::call(const_cast(*this), other, alpha); +} + +// aten::add_.Scalar(Tensor(a!) self, Scalar other, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::add_(const at::Scalar & other, const at::Scalar & alpha) const { + return at::_ops::add__Scalar::call(const_cast(*this), other, alpha); +} + +// aten::addmv(Tensor self, Tensor mat, Tensor vec, *, Scalar beta=1, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::addmv(const at::Tensor & mat, const at::Tensor & vec, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::addmv::call(const_cast(*this), mat, vec, beta, alpha); +} + +// aten::addmv_(Tensor(a!) self, Tensor mat, Tensor vec, *, Scalar beta=1, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::addmv_(const at::Tensor & mat, const at::Tensor & vec, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::addmv_::call(const_cast(*this), mat, vec, beta, alpha); +} + +// aten::addr(Tensor self, Tensor vec1, Tensor vec2, *, Scalar beta=1, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::addr(const at::Tensor & vec1, const at::Tensor & vec2, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::addr::call(const_cast(*this), vec1, vec2, beta, alpha); +} + +// aten::addr_(Tensor(a!) self, Tensor vec1, Tensor vec2, *, Scalar beta=1, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::addr_(const at::Tensor & vec1, const at::Tensor & vec2, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::addr_::call(const_cast(*this), vec1, vec2, beta, alpha); +} + +// aten::_is_all_true(Tensor self) -> Tensor +inline at::Tensor Tensor::_is_all_true() const { + return at::_ops::_is_all_true::call(const_cast(*this)); +} + +// aten::_is_any_true(Tensor self) -> Tensor +inline at::Tensor Tensor::_is_any_true() const { + return at::_ops::_is_any_true::call(const_cast(*this)); +} + +// aten::all.dim(Tensor self, int dim, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::all(int64_t dim, bool keepdim) const { + return at::_ops::all_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::all.dims(Tensor self, int[]? dim=None, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::all(at::OptionalIntArrayRef dim, bool keepdim) const { + return at::_ops::all_dims::call(const_cast(*this), dim, keepdim); +} + +// aten::all.dimname(Tensor self, Dimname dim, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::all(at::Dimname dim, bool keepdim) const { + return at::_ops::all_dimname::call(const_cast(*this), dim, keepdim); +} + +// aten::allclose(Tensor self, Tensor other, float rtol=1e-05, float atol=1e-08, bool equal_nan=False) -> bool +inline bool Tensor::allclose(const at::Tensor & other, double rtol, double atol, bool equal_nan) const { + return at::_ops::allclose::call(const_cast(*this), other, rtol, atol, equal_nan); +} + +// aten::any.dim(Tensor self, int dim, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::any(int64_t dim, bool keepdim) const { + return at::_ops::any_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::any.dims(Tensor self, int[]? dim=None, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::any(at::OptionalIntArrayRef dim, bool keepdim) const { + return at::_ops::any_dims::call(const_cast(*this), dim, keepdim); +} + +// aten::any.dimname(Tensor self, Dimname dim, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::any(at::Dimname dim, bool keepdim) const { + return at::_ops::any_dimname::call(const_cast(*this), dim, keepdim); +} + +// aten::argmax(Tensor self, int? dim=None, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::argmax(::std::optional dim, bool keepdim) const { + return at::_ops::argmax::call(const_cast(*this), dim, keepdim); +} + +// aten::argmin(Tensor self, int? dim=None, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::argmin(::std::optional dim, bool keepdim) const { + return at::_ops::argmin::call(const_cast(*this), dim, keepdim); +} + +// aten::acosh(Tensor self) -> Tensor +inline at::Tensor Tensor::acosh() const { + return at::_ops::acosh::call(const_cast(*this)); +} + +// aten::acosh_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::acosh_() const { + return at::_ops::acosh_::call(const_cast(*this)); +} + +// aten::arccosh(Tensor self) -> Tensor +inline at::Tensor Tensor::arccosh() const { + return at::_ops::arccosh::call(const_cast(*this)); +} + +// aten::arccosh_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::arccosh_() const { + return at::_ops::arccosh_::call(const_cast(*this)); +} + +// aten::asinh(Tensor self) -> Tensor +inline at::Tensor Tensor::asinh() const { + return at::_ops::asinh::call(const_cast(*this)); +} + +// aten::asinh_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::asinh_() const { + return at::_ops::asinh_::call(const_cast(*this)); +} + +// aten::arcsinh(Tensor self) -> Tensor +inline at::Tensor Tensor::arcsinh() const { + return at::_ops::arcsinh::call(const_cast(*this)); +} + +// aten::arcsinh_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::arcsinh_() const { + return at::_ops::arcsinh_::call(const_cast(*this)); +} + +// aten::atanh(Tensor self) -> Tensor +inline at::Tensor Tensor::atanh() const { + return at::_ops::atanh::call(const_cast(*this)); +} + +// aten::atanh_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::atanh_() const { + return at::_ops::atanh_::call(const_cast(*this)); +} + +// aten::arctanh(Tensor self) -> Tensor +inline at::Tensor Tensor::arctanh() const { + return at::_ops::arctanh::call(const_cast(*this)); +} + +// aten::arctanh_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::arctanh_() const { + return at::_ops::arctanh_::call(const_cast(*this)); +} + +// aten::as_strided(Tensor(a) self, SymInt[] size, SymInt[] stride, SymInt? storage_offset=None) -> Tensor(a) +inline at::Tensor Tensor::as_strided(at::IntArrayRef size, at::IntArrayRef stride, ::std::optional storage_offset) const { + return at::_ops::as_strided::call(const_cast(*this), c10::fromIntArrayRefSlow(size), c10::fromIntArrayRefSlow(stride), storage_offset.has_value() ? ::std::make_optional(c10::SymInt(*storage_offset)) : ::std::nullopt); +} + +// aten::as_strided(Tensor(a) self, SymInt[] size, SymInt[] stride, SymInt? storage_offset=None) -> Tensor(a) +inline at::Tensor Tensor::as_strided_symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride, ::std::optional storage_offset) const { + return at::_ops::as_strided::call(const_cast(*this), size, stride, storage_offset); +} + +// aten::as_strided_(Tensor(a!) self, SymInt[] size, SymInt[] stride, SymInt? storage_offset=None) -> Tensor(a!) +inline const at::Tensor & Tensor::as_strided_(at::IntArrayRef size, at::IntArrayRef stride, ::std::optional storage_offset) const { + return at::_ops::as_strided_::call(const_cast(*this), c10::fromIntArrayRefSlow(size), c10::fromIntArrayRefSlow(stride), storage_offset.has_value() ? ::std::make_optional(c10::SymInt(*storage_offset)) : ::std::nullopt); +} + +// aten::as_strided_(Tensor(a!) self, SymInt[] size, SymInt[] stride, SymInt? storage_offset=None) -> Tensor(a!) +inline const at::Tensor & Tensor::as_strided__symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride, ::std::optional storage_offset) const { + return at::_ops::as_strided_::call(const_cast(*this), size, stride, storage_offset); +} + +// aten::asin(Tensor self) -> Tensor +inline at::Tensor Tensor::asin() const { + return at::_ops::asin::call(const_cast(*this)); +} + +// aten::asin_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::asin_() const { + return at::_ops::asin_::call(const_cast(*this)); +} + +// aten::arcsin(Tensor self) -> Tensor +inline at::Tensor Tensor::arcsin() const { + return at::_ops::arcsin::call(const_cast(*this)); +} + +// aten::arcsin_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::arcsin_() const { + return at::_ops::arcsin_::call(const_cast(*this)); +} + +// aten::atan(Tensor self) -> Tensor +inline at::Tensor Tensor::atan() const { + return at::_ops::atan::call(const_cast(*this)); +} + +// aten::atan_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::atan_() const { + return at::_ops::atan_::call(const_cast(*this)); +} + +// aten::arctan(Tensor self) -> Tensor +inline at::Tensor Tensor::arctan() const { + return at::_ops::arctan::call(const_cast(*this)); +} + +// aten::arctan_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::arctan_() const { + return at::_ops::arctan_::call(const_cast(*this)); +} + +// aten::baddbmm(Tensor self, Tensor batch1, Tensor batch2, *, Scalar beta=1, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::baddbmm(const at::Tensor & batch1, const at::Tensor & batch2, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::baddbmm::call(const_cast(*this), batch1, batch2, beta, alpha); +} + +// aten::baddbmm_(Tensor(a!) self, Tensor batch1, Tensor batch2, *, Scalar beta=1, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::baddbmm_(const at::Tensor & batch1, const at::Tensor & batch2, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::baddbmm_::call(const_cast(*this), batch1, batch2, beta, alpha); +} + +// aten::bernoulli(Tensor self, *, Generator? generator=None) -> Tensor +inline at::Tensor Tensor::bernoulli(::std::optional generator) const { + return at::_ops::bernoulli::call(const_cast(*this), generator); +} + +// aten::bernoulli_.Tensor(Tensor(a!) self, Tensor p, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::bernoulli_(const at::Tensor & p, ::std::optional generator) const { + return at::_ops::bernoulli__Tensor::call(const_cast(*this), p, generator); +} + +// aten::bernoulli_.float(Tensor(a!) self, float p=0.5, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::bernoulli_(double p, ::std::optional generator) const { + return at::_ops::bernoulli__float::call(const_cast(*this), p, generator); +} + +// aten::bernoulli.p(Tensor self, float p, *, Generator? generator=None) -> Tensor +inline at::Tensor Tensor::bernoulli(double p, ::std::optional generator) const { + return at::_ops::bernoulli_p::call(const_cast(*this), p, generator); +} + +// aten::bincount(Tensor self, Tensor? weights=None, int minlength=0) -> Tensor +inline at::Tensor Tensor::bincount(const ::std::optional & weights, int64_t minlength) const { + return at::_ops::bincount::call(const_cast(*this), weights, minlength); +} + +// aten::bitwise_not(Tensor self) -> Tensor +inline at::Tensor Tensor::bitwise_not() const { + return at::_ops::bitwise_not::call(const_cast(*this)); +} + +// aten::bitwise_not_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_not_() const { + return at::_ops::bitwise_not_::call(const_cast(*this)); +} + +// aten::copysign.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::copysign(const at::Tensor & other) const { + return at::_ops::copysign_Tensor::call(const_cast(*this), other); +} + +// aten::copysign_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::copysign_(const at::Tensor & other) const { + return at::_ops::copysign__Tensor::call(const_cast(*this), other); +} + +// aten::copysign.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::copysign(const at::Scalar & other) const { + return at::_ops::copysign_Scalar::call(const_cast(*this), other); +} + +// aten::copysign_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::copysign_(const at::Scalar & other) const { + return at::_ops::copysign__Scalar::call(const_cast(*this), other); +} + +// aten::_lazy_clone(Tensor self) -> Tensor +inline at::Tensor Tensor::_lazy_clone() const { + return at::_ops::_lazy_clone::call(const_cast(*this)); +} + +// aten::logical_not(Tensor self) -> Tensor +inline at::Tensor Tensor::logical_not() const { + return at::_ops::logical_not::call(const_cast(*this)); +} + +// aten::logical_not_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::logical_not_() const { + return at::_ops::logical_not_::call(const_cast(*this)); +} + +// aten::logical_xor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::logical_xor(const at::Tensor & other) const { + return at::_ops::logical_xor::call(const_cast(*this), other); +} + +// aten::logical_xor_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::logical_xor_(const at::Tensor & other) const { + return at::_ops::logical_xor_::call(const_cast(*this), other); +} + +// aten::logical_and(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::logical_and(const at::Tensor & other) const { + return at::_ops::logical_and::call(const_cast(*this), other); +} + +// aten::logical_and_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::logical_and_(const at::Tensor & other) const { + return at::_ops::logical_and_::call(const_cast(*this), other); +} + +// aten::logical_or(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::logical_or(const at::Tensor & other) const { + return at::_ops::logical_or::call(const_cast(*this), other); +} + +// aten::logical_or_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::logical_or_(const at::Tensor & other) const { + return at::_ops::logical_or_::call(const_cast(*this), other); +} + +// aten::bmm(Tensor self, Tensor mat2) -> Tensor +inline at::Tensor Tensor::bmm(const at::Tensor & mat2) const { + return at::_ops::bmm::call(const_cast(*this), mat2); +} + +// aten::broadcast_to(Tensor(a) self, SymInt[] size) -> Tensor(a) +inline at::Tensor Tensor::broadcast_to(at::IntArrayRef size) const { + return at::_ops::broadcast_to::call(const_cast(*this), c10::fromIntArrayRefSlow(size)); +} + +// aten::broadcast_to(Tensor(a) self, SymInt[] size) -> Tensor(a) +inline at::Tensor Tensor::broadcast_to_symint(c10::SymIntArrayRef size) const { + return at::_ops::broadcast_to::call(const_cast(*this), size); +} + +// aten::ceil(Tensor self) -> Tensor +inline at::Tensor Tensor::ceil() const { + return at::_ops::ceil::call(const_cast(*this)); +} + +// aten::ceil_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::ceil_() const { + return at::_ops::ceil_::call(const_cast(*this)); +} + +// aten::unsafe_chunk(Tensor self, int chunks, int dim=0) -> Tensor[] +inline ::std::vector Tensor::unsafe_chunk(int64_t chunks, int64_t dim) const { + return at::_ops::unsafe_chunk::call(const_cast(*this), chunks, dim); +} + +// aten::chunk(Tensor(a -> *) self, int chunks, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::chunk(int64_t chunks, int64_t dim) const { + return at::_ops::chunk::call(const_cast(*this), chunks, dim); +} + +// aten::tensor_split.sections(Tensor(a -> *) self, SymInt sections, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::tensor_split(int64_t sections, int64_t dim) const { + return at::_ops::tensor_split_sections::call(const_cast(*this), sections, dim); +} + +// aten::tensor_split.sections(Tensor(a -> *) self, SymInt sections, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::tensor_split_symint(c10::SymInt sections, int64_t dim) const { + return at::_ops::tensor_split_sections::call(const_cast(*this), sections, dim); +} + +// aten::tensor_split.indices(Tensor(a -> *) self, SymInt[] indices, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::tensor_split(at::IntArrayRef indices, int64_t dim) const { + return at::_ops::tensor_split_indices::call(const_cast(*this), c10::fromIntArrayRefSlow(indices), dim); +} + +// aten::tensor_split.indices(Tensor(a -> *) self, SymInt[] indices, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::tensor_split_symint(c10::SymIntArrayRef indices, int64_t dim) const { + return at::_ops::tensor_split_indices::call(const_cast(*this), indices, dim); +} + +// aten::tensor_split.tensor_indices_or_sections(Tensor(a -> *) self, Tensor tensor_indices_or_sections, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::tensor_split(const at::Tensor & tensor_indices_or_sections, int64_t dim) const { + return at::_ops::tensor_split_tensor_indices_or_sections::call(const_cast(*this), tensor_indices_or_sections, dim); +} + +// aten::clamp(Tensor self, Scalar? min=None, Scalar? max=None) -> Tensor +inline at::Tensor Tensor::clamp(const ::std::optional & min, const ::std::optional & max) const { + return at::_ops::clamp::call(const_cast(*this), min, max); +} + +// aten::clamp.Tensor(Tensor self, Tensor? min=None, Tensor? max=None) -> Tensor +inline at::Tensor Tensor::clamp(const ::std::optional & min, const ::std::optional & max) const { + return at::_ops::clamp_Tensor::call(const_cast(*this), min, max); +} + +// aten::clamp_(Tensor(a!) self, Scalar? min=None, Scalar? max=None) -> Tensor(a!) +inline at::Tensor & Tensor::clamp_(const ::std::optional & min, const ::std::optional & max) const { + return at::_ops::clamp_::call(const_cast(*this), min, max); +} + +// aten::clamp_.Tensor(Tensor(a!) self, Tensor? min=None, Tensor? max=None) -> Tensor(a!) +inline at::Tensor & Tensor::clamp_(const ::std::optional & min, const ::std::optional & max) const { + return at::_ops::clamp__Tensor::call(const_cast(*this), min, max); +} + +// aten::clamp_max(Tensor self, Scalar max) -> Tensor +inline at::Tensor Tensor::clamp_max(const at::Scalar & max) const { + return at::_ops::clamp_max::call(const_cast(*this), max); +} + +// aten::clamp_max.Tensor(Tensor self, Tensor max) -> Tensor +inline at::Tensor Tensor::clamp_max(const at::Tensor & max) const { + return at::_ops::clamp_max_Tensor::call(const_cast(*this), max); +} + +// aten::clamp_max_(Tensor(a!) self, Scalar max) -> Tensor(a!) +inline at::Tensor & Tensor::clamp_max_(const at::Scalar & max) const { + return at::_ops::clamp_max_::call(const_cast(*this), max); +} + +// aten::clamp_max_.Tensor(Tensor(a!) self, Tensor max) -> Tensor(a!) +inline at::Tensor & Tensor::clamp_max_(const at::Tensor & max) const { + return at::_ops::clamp_max__Tensor::call(const_cast(*this), max); +} + +// aten::clamp_min(Tensor self, Scalar min) -> Tensor +inline at::Tensor Tensor::clamp_min(const at::Scalar & min) const { + return at::_ops::clamp_min::call(const_cast(*this), min); +} + +// aten::clamp_min.Tensor(Tensor self, Tensor min) -> Tensor +inline at::Tensor Tensor::clamp_min(const at::Tensor & min) const { + return at::_ops::clamp_min_Tensor::call(const_cast(*this), min); +} + +// aten::clamp_min_(Tensor(a!) self, Scalar min) -> Tensor(a!) +inline at::Tensor & Tensor::clamp_min_(const at::Scalar & min) const { + return at::_ops::clamp_min_::call(const_cast(*this), min); +} + +// aten::clamp_min_.Tensor(Tensor(a!) self, Tensor min) -> Tensor(a!) +inline at::Tensor & Tensor::clamp_min_(const at::Tensor & min) const { + return at::_ops::clamp_min__Tensor::call(const_cast(*this), min); +} + +// aten::clip(Tensor self, Scalar? min=None, Scalar? max=None) -> Tensor +inline at::Tensor Tensor::clip(const ::std::optional & min, const ::std::optional & max) const { + return at::_ops::clip::call(const_cast(*this), min, max); +} + +// aten::clip.Tensor(Tensor self, Tensor? min=None, Tensor? max=None) -> Tensor +inline at::Tensor Tensor::clip(const ::std::optional & min, const ::std::optional & max) const { + return at::_ops::clip_Tensor::call(const_cast(*this), min, max); +} + +// aten::clip_(Tensor(a!) self, Scalar? min=None, Scalar? max=None) -> Tensor(a!) +inline at::Tensor & Tensor::clip_(const ::std::optional & min, const ::std::optional & max) const { + return at::_ops::clip_::call(const_cast(*this), min, max); +} + +// aten::clip_.Tensor(Tensor(a!) self, Tensor? min=None, Tensor? max=None) -> Tensor(a!) +inline at::Tensor & Tensor::clip_(const ::std::optional & min, const ::std::optional & max) const { + return at::_ops::clip__Tensor::call(const_cast(*this), min, max); +} + +// aten::contiguous(Tensor(a) self, *, MemoryFormat memory_format=contiguous_format) -> Tensor(a) +inline at::Tensor Tensor::__dispatch_contiguous(at::MemoryFormat memory_format) const { + return at::_ops::contiguous::call(const_cast(*this), memory_format); +} + +// aten::copy_(Tensor(a!) self, Tensor src, bool non_blocking=False) -> Tensor(a!) +inline at::Tensor & Tensor::copy_(const at::Tensor & src, bool non_blocking) const { + return at::_ops::copy_::call(const_cast(*this), src, non_blocking); +} + +// aten::cos(Tensor self) -> Tensor +inline at::Tensor Tensor::cos() const { + return at::_ops::cos::call(const_cast(*this)); +} + +// aten::cos_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::cos_() const { + return at::_ops::cos_::call(const_cast(*this)); +} + +// aten::cosh(Tensor self) -> Tensor +inline at::Tensor Tensor::cosh() const { + return at::_ops::cosh::call(const_cast(*this)); +} + +// aten::cosh_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::cosh_() const { + return at::_ops::cosh_::call(const_cast(*this)); +} + +// aten::count_nonzero.dim_IntList(Tensor self, int[] dim) -> Tensor +inline at::Tensor Tensor::count_nonzero(at::IntArrayRef dim) const { + return at::_ops::count_nonzero_dim_IntList::call(const_cast(*this), dim); +} + +// aten::count_nonzero(Tensor self, int? dim=None) -> Tensor +inline at::Tensor Tensor::count_nonzero(::std::optional dim) const { + return at::_ops::count_nonzero::call(const_cast(*this), dim); +} + +// aten::cov(Tensor self, *, int correction=1, Tensor? fweights=None, Tensor? aweights=None) -> Tensor +inline at::Tensor Tensor::cov(int64_t correction, const ::std::optional & fweights, const ::std::optional & aweights) const { + return at::_ops::cov::call(const_cast(*this), correction, fweights, aweights); +} + +// aten::corrcoef(Tensor self) -> Tensor +inline at::Tensor Tensor::corrcoef() const { + return at::_ops::corrcoef::call(const_cast(*this)); +} + +// aten::cummax(Tensor self, int dim) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::cummax(int64_t dim) const { + return at::_ops::cummax::call(const_cast(*this), dim); +} + +// aten::cummax.dimname(Tensor self, Dimname dim) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::cummax(at::Dimname dim) const { + return at::_ops::cummax_dimname::call(const_cast(*this), dim); +} + +// aten::cummin(Tensor self, int dim) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::cummin(int64_t dim) const { + return at::_ops::cummin::call(const_cast(*this), dim); +} + +// aten::cummin.dimname(Tensor self, Dimname dim) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::cummin(at::Dimname dim) const { + return at::_ops::cummin_dimname::call(const_cast(*this), dim); +} + +// aten::cumprod(Tensor self, int dim, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::cumprod(int64_t dim, ::std::optional dtype) const { + return at::_ops::cumprod::call(const_cast(*this), dim, dtype); +} + +// aten::cumprod_(Tensor(a!) self, int dim, *, ScalarType? dtype=None) -> Tensor(a!) +inline at::Tensor & Tensor::cumprod_(int64_t dim, ::std::optional dtype) const { + return at::_ops::cumprod_::call(const_cast(*this), dim, dtype); +} + +// aten::cumprod.dimname(Tensor self, Dimname dim, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::cumprod(at::Dimname dim, ::std::optional dtype) const { + return at::_ops::cumprod_dimname::call(const_cast(*this), dim, dtype); +} + +// aten::cumprod_.dimname(Tensor(a!) self, Dimname dim, *, ScalarType? dtype=None) -> Tensor(a!) +inline at::Tensor & Tensor::cumprod_(at::Dimname dim, ::std::optional dtype) const { + return at::_ops::cumprod__dimname::call(const_cast(*this), dim, dtype); +} + +// aten::cumsum(Tensor self, int dim, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::cumsum(int64_t dim, ::std::optional dtype) const { + return at::_ops::cumsum::call(const_cast(*this), dim, dtype); +} + +// aten::cumsum_(Tensor(a!) self, int dim, *, ScalarType? dtype=None) -> Tensor(a!) +inline at::Tensor & Tensor::cumsum_(int64_t dim, ::std::optional dtype) const { + return at::_ops::cumsum_::call(const_cast(*this), dim, dtype); +} + +// aten::cumsum.dimname(Tensor self, Dimname dim, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::cumsum(at::Dimname dim, ::std::optional dtype) const { + return at::_ops::cumsum_dimname::call(const_cast(*this), dim, dtype); +} + +// aten::cumsum_.dimname(Tensor(a!) self, Dimname dim, *, ScalarType? dtype=None) -> Tensor(a!) +inline at::Tensor & Tensor::cumsum_(at::Dimname dim, ::std::optional dtype) const { + return at::_ops::cumsum__dimname::call(const_cast(*this), dim, dtype); +} + +// aten::diag_embed(Tensor self, int offset=0, int dim1=-2, int dim2=-1) -> Tensor +inline at::Tensor Tensor::diag_embed(int64_t offset, int64_t dim1, int64_t dim2) const { + return at::_ops::diag_embed::call(const_cast(*this), offset, dim1, dim2); +} + +// aten::diagflat(Tensor self, int offset=0) -> Tensor +inline at::Tensor Tensor::diagflat(int64_t offset) const { + return at::_ops::diagflat::call(const_cast(*this), offset); +} + +// aten::diagonal(Tensor(a) self, int offset=0, int dim1=0, int dim2=1) -> Tensor(a) +inline at::Tensor Tensor::diagonal(int64_t offset, int64_t dim1, int64_t dim2) const { + return at::_ops::diagonal::call(const_cast(*this), offset, dim1, dim2); +} + +// aten::diagonal.Dimname(Tensor(a) self, *, Dimname outdim, Dimname dim1, Dimname dim2, int offset=0) -> Tensor(a) +inline at::Tensor Tensor::diagonal(at::Dimname outdim, at::Dimname dim1, at::Dimname dim2, int64_t offset) const { + return at::_ops::diagonal_Dimname::call(const_cast(*this), outdim, dim1, dim2, offset); +} + +// aten::fill_diagonal_(Tensor(a!) self, Scalar fill_value, bool wrap=False) -> Tensor(a!) +inline at::Tensor & Tensor::fill_diagonal_(const at::Scalar & fill_value, bool wrap) const { + return at::_ops::fill_diagonal_::call(const_cast(*this), fill_value, wrap); +} + +// aten::diff(Tensor self, int n=1, int dim=-1, Tensor? prepend=None, Tensor? append=None) -> Tensor +inline at::Tensor Tensor::diff(int64_t n, int64_t dim, const ::std::optional & prepend, const ::std::optional & append) const { + return at::_ops::diff::call(const_cast(*this), n, dim, prepend, append); +} + +// aten::div.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::div(const at::Tensor & other) const { + return at::_ops::div_Tensor::call(const_cast(*this), other); +} + +// aten::div_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::div_(const at::Tensor & other) const { + return at::_ops::div__Tensor::call(const_cast(*this), other); +} + +// aten::div.Tensor_mode(Tensor self, Tensor other, *, str? rounding_mode) -> Tensor +inline at::Tensor Tensor::div(const at::Tensor & other, ::std::optional rounding_mode) const { + return at::_ops::div_Tensor_mode::call(const_cast(*this), other, rounding_mode); +} + +// aten::div_.Tensor_mode(Tensor(a!) self, Tensor other, *, str? rounding_mode) -> Tensor(a!) +inline at::Tensor & Tensor::div_(const at::Tensor & other, ::std::optional rounding_mode) const { + return at::_ops::div__Tensor_mode::call(const_cast(*this), other, rounding_mode); +} + +// aten::div.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::div(const at::Scalar & other) const { + return at::_ops::div_Scalar::call(const_cast(*this), other); +} + +// aten::div_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::div_(const at::Scalar & other) const { + return at::_ops::div__Scalar::call(const_cast(*this), other); +} + +// aten::div.Scalar_mode(Tensor self, Scalar other, *, str? rounding_mode) -> Tensor +inline at::Tensor Tensor::div(const at::Scalar & other, ::std::optional rounding_mode) const { + return at::_ops::div_Scalar_mode::call(const_cast(*this), other, rounding_mode); +} + +// aten::div_.Scalar_mode(Tensor(a!) self, Scalar other, *, str? rounding_mode) -> Tensor(a!) +inline at::Tensor & Tensor::div_(const at::Scalar & other, ::std::optional rounding_mode) const { + return at::_ops::div__Scalar_mode::call(const_cast(*this), other, rounding_mode); +} + +// aten::divide.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::divide(const at::Tensor & other) const { + return at::_ops::divide_Tensor::call(const_cast(*this), other); +} + +// aten::divide_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::divide_(const at::Tensor & other) const { + return at::_ops::divide__Tensor::call(const_cast(*this), other); +} + +// aten::divide.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::divide(const at::Scalar & other) const { + return at::_ops::divide_Scalar::call(const_cast(*this), other); +} + +// aten::divide_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::divide_(const at::Scalar & other) const { + return at::_ops::divide__Scalar::call(const_cast(*this), other); +} + +// aten::divide.Tensor_mode(Tensor self, Tensor other, *, str? rounding_mode) -> Tensor +inline at::Tensor Tensor::divide(const at::Tensor & other, ::std::optional rounding_mode) const { + return at::_ops::divide_Tensor_mode::call(const_cast(*this), other, rounding_mode); +} + +// aten::divide_.Tensor_mode(Tensor(a!) self, Tensor other, *, str? rounding_mode) -> Tensor(a!) +inline at::Tensor & Tensor::divide_(const at::Tensor & other, ::std::optional rounding_mode) const { + return at::_ops::divide__Tensor_mode::call(const_cast(*this), other, rounding_mode); +} + +// aten::divide.Scalar_mode(Tensor self, Scalar other, *, str? rounding_mode) -> Tensor +inline at::Tensor Tensor::divide(const at::Scalar & other, ::std::optional rounding_mode) const { + return at::_ops::divide_Scalar_mode::call(const_cast(*this), other, rounding_mode); +} + +// aten::divide_.Scalar_mode(Tensor(a!) self, Scalar other, *, str? rounding_mode) -> Tensor(a!) +inline at::Tensor & Tensor::divide_(const at::Scalar & other, ::std::optional rounding_mode) const { + return at::_ops::divide__Scalar_mode::call(const_cast(*this), other, rounding_mode); +} + +// aten::true_divide.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::true_divide(const at::Tensor & other) const { + return at::_ops::true_divide_Tensor::call(const_cast(*this), other); +} + +// aten::true_divide_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::true_divide_(const at::Tensor & other) const { + return at::_ops::true_divide__Tensor::call(const_cast(*this), other); +} + +// aten::true_divide.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::true_divide(const at::Scalar & other) const { + return at::_ops::true_divide_Scalar::call(const_cast(*this), other); +} + +// aten::true_divide_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::true_divide_(const at::Scalar & other) const { + return at::_ops::true_divide__Scalar::call(const_cast(*this), other); +} + +// aten::dot(Tensor self, Tensor tensor) -> Tensor +inline at::Tensor Tensor::dot(const at::Tensor & tensor) const { + return at::_ops::dot::call(const_cast(*this), tensor); +} + +// aten::vdot(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::vdot(const at::Tensor & other) const { + return at::_ops::vdot::call(const_cast(*this), other); +} + +// aten::new_empty(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_empty(at::IntArrayRef size, at::TensorOptions options) const { + return at::_ops::new_empty::call(const_cast(*this), c10::fromIntArrayRefSlow(size), c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_empty(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_empty(at::IntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_empty::call(const_cast(*this), c10::fromIntArrayRefSlow(size), dtype, layout, device, pin_memory); +} + +// aten::new_empty(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_empty_symint(c10::SymIntArrayRef size, at::TensorOptions options) const { + return at::_ops::new_empty::call(const_cast(*this), size, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_empty(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_empty_symint(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_empty::call(const_cast(*this), size, dtype, layout, device, pin_memory); +} + +// aten::new_empty_strided(Tensor self, SymInt[] size, SymInt[] stride, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_empty_strided(at::IntArrayRef size, at::IntArrayRef stride, at::TensorOptions options) const { + return at::_ops::new_empty_strided::call(const_cast(*this), c10::fromIntArrayRefSlow(size), c10::fromIntArrayRefSlow(stride), c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_empty_strided(Tensor self, SymInt[] size, SymInt[] stride, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_empty_strided(at::IntArrayRef size, at::IntArrayRef stride, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_empty_strided::call(const_cast(*this), c10::fromIntArrayRefSlow(size), c10::fromIntArrayRefSlow(stride), dtype, layout, device, pin_memory); +} + +// aten::new_empty_strided(Tensor self, SymInt[] size, SymInt[] stride, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_empty_strided_symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride, at::TensorOptions options) const { + return at::_ops::new_empty_strided::call(const_cast(*this), size, stride, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_empty_strided(Tensor self, SymInt[] size, SymInt[] stride, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_empty_strided_symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_empty_strided::call(const_cast(*this), size, stride, dtype, layout, device, pin_memory); +} + +// aten::new_full(Tensor self, SymInt[] size, Scalar fill_value, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_full(at::IntArrayRef size, const at::Scalar & fill_value, at::TensorOptions options) const { + return at::_ops::new_full::call(const_cast(*this), c10::fromIntArrayRefSlow(size), fill_value, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_full(Tensor self, SymInt[] size, Scalar fill_value, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_full(at::IntArrayRef size, const at::Scalar & fill_value, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_full::call(const_cast(*this), c10::fromIntArrayRefSlow(size), fill_value, dtype, layout, device, pin_memory); +} + +// aten::new_full(Tensor self, SymInt[] size, Scalar fill_value, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_full_symint(c10::SymIntArrayRef size, const at::Scalar & fill_value, at::TensorOptions options) const { + return at::_ops::new_full::call(const_cast(*this), size, fill_value, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_full(Tensor self, SymInt[] size, Scalar fill_value, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_full_symint(c10::SymIntArrayRef size, const at::Scalar & fill_value, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_full::call(const_cast(*this), size, fill_value, dtype, layout, device, pin_memory); +} + +// aten::new_zeros(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_zeros(at::IntArrayRef size, at::TensorOptions options) const { + return at::_ops::new_zeros::call(const_cast(*this), c10::fromIntArrayRefSlow(size), c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_zeros(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_zeros(at::IntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_zeros::call(const_cast(*this), c10::fromIntArrayRefSlow(size), dtype, layout, device, pin_memory); +} + +// aten::new_zeros(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_zeros_symint(c10::SymIntArrayRef size, at::TensorOptions options) const { + return at::_ops::new_zeros::call(const_cast(*this), size, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_zeros(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_zeros_symint(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_zeros::call(const_cast(*this), size, dtype, layout, device, pin_memory); +} + +// aten::new_ones(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_ones(at::IntArrayRef size, at::TensorOptions options) const { + return at::_ops::new_ones::call(const_cast(*this), c10::fromIntArrayRefSlow(size), c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_ones(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_ones(at::IntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_ones::call(const_cast(*this), c10::fromIntArrayRefSlow(size), dtype, layout, device, pin_memory); +} + +// aten::new_ones(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_ones_symint(c10::SymIntArrayRef size, at::TensorOptions options) const { + return at::_ops::new_ones::call(const_cast(*this), size, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} + +// aten::new_ones(Tensor self, SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor Tensor::new_ones_symint(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) const { + return at::_ops::new_ones::call(const_cast(*this), size, dtype, layout, device, pin_memory); +} + +// aten::resize_(Tensor(a!) self, SymInt[] size, *, MemoryFormat? memory_format=None) -> Tensor(a!) +inline const at::Tensor & Tensor::resize_(at::IntArrayRef size, ::std::optional memory_format) const { + return at::_ops::resize_::call(const_cast(*this), c10::fromIntArrayRefSlow(size), memory_format); +} + +// aten::resize_(Tensor(a!) self, SymInt[] size, *, MemoryFormat? memory_format=None) -> Tensor(a!) +inline const at::Tensor & Tensor::resize__symint(c10::SymIntArrayRef size, ::std::optional memory_format) const { + return at::_ops::resize_::call(const_cast(*this), size, memory_format); +} + +// aten::erf(Tensor self) -> Tensor +inline at::Tensor Tensor::erf() const { + return at::_ops::erf::call(const_cast(*this)); +} + +// aten::erf_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::erf_() const { + return at::_ops::erf_::call(const_cast(*this)); +} + +// aten::erfc(Tensor self) -> Tensor +inline at::Tensor Tensor::erfc() const { + return at::_ops::erfc::call(const_cast(*this)); +} + +// aten::erfc_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::erfc_() const { + return at::_ops::erfc_::call(const_cast(*this)); +} + +// aten::exp(Tensor self) -> Tensor +inline at::Tensor Tensor::exp() const { + return at::_ops::exp::call(const_cast(*this)); +} + +// aten::exp_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::exp_() const { + return at::_ops::exp_::call(const_cast(*this)); +} + +// aten::exp2(Tensor self) -> Tensor +inline at::Tensor Tensor::exp2() const { + return at::_ops::exp2::call(const_cast(*this)); +} + +// aten::exp2_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::exp2_() const { + return at::_ops::exp2_::call(const_cast(*this)); +} + +// aten::expm1(Tensor self) -> Tensor +inline at::Tensor Tensor::expm1() const { + return at::_ops::expm1::call(const_cast(*this)); +} + +// aten::expm1_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::expm1_() const { + return at::_ops::expm1_::call(const_cast(*this)); +} + +// aten::expand(Tensor(a) self, SymInt[] size, *, bool implicit=False) -> Tensor(a) +inline at::Tensor Tensor::expand(at::IntArrayRef size, bool implicit) const { + return at::_ops::expand::call(const_cast(*this), c10::fromIntArrayRefSlow(size), implicit); +} + +// aten::expand(Tensor(a) self, SymInt[] size, *, bool implicit=False) -> Tensor(a) +inline at::Tensor Tensor::expand_symint(c10::SymIntArrayRef size, bool implicit) const { + return at::_ops::expand::call(const_cast(*this), size, implicit); +} + +// aten::expand_as(Tensor(a) self, Tensor other) -> Tensor(a) +inline at::Tensor Tensor::expand_as(const at::Tensor & other) const { + return at::_ops::expand_as::call(const_cast(*this), other); +} + +// aten::flatten.using_ints(Tensor(a) self, int start_dim=0, int end_dim=-1) -> Tensor(a) +inline at::Tensor Tensor::flatten(int64_t start_dim, int64_t end_dim) const { + return at::_ops::flatten_using_ints::call(const_cast(*this), start_dim, end_dim); +} + +// aten::flatten.named_out_dim(Tensor(a) self, int start_dim, int end_dim, Dimname out_dim) -> Tensor(a) +inline at::Tensor Tensor::flatten(int64_t start_dim, int64_t end_dim, at::Dimname out_dim) const { + return at::_ops::flatten_named_out_dim::call(const_cast(*this), start_dim, end_dim, out_dim); +} + +// aten::flatten.using_names(Tensor(a) self, Dimname start_dim, Dimname end_dim, Dimname out_dim) -> Tensor(a) +inline at::Tensor Tensor::flatten(at::Dimname start_dim, at::Dimname end_dim, at::Dimname out_dim) const { + return at::_ops::flatten_using_names::call(const_cast(*this), start_dim, end_dim, out_dim); +} + +// aten::flatten.DimnameList(Tensor(a) self, Dimname[] dims, Dimname out_dim) -> Tensor(a) +inline at::Tensor Tensor::flatten(at::DimnameList dims, at::Dimname out_dim) const { + return at::_ops::flatten_DimnameList::call(const_cast(*this), dims, out_dim); +} + +// aten::unflatten.int(Tensor(a) self, int dim, SymInt[] sizes) -> Tensor(a) +inline at::Tensor Tensor::unflatten(int64_t dim, at::IntArrayRef sizes) const { + return at::_ops::unflatten_int::call(const_cast(*this), dim, c10::fromIntArrayRefSlow(sizes)); +} + +// aten::unflatten.int(Tensor(a) self, int dim, SymInt[] sizes) -> Tensor(a) +inline at::Tensor Tensor::unflatten_symint(int64_t dim, c10::SymIntArrayRef sizes) const { + return at::_ops::unflatten_int::call(const_cast(*this), dim, sizes); +} + +// aten::unflatten.Dimname(Tensor(a) self, Dimname dim, SymInt[] sizes, Dimname[] names) -> Tensor(a) +inline at::Tensor Tensor::unflatten(at::Dimname dim, at::IntArrayRef sizes, at::DimnameList names) const { + return at::_ops::unflatten_Dimname::call(const_cast(*this), dim, c10::fromIntArrayRefSlow(sizes), names); +} + +// aten::unflatten.Dimname(Tensor(a) self, Dimname dim, SymInt[] sizes, Dimname[] names) -> Tensor(a) +inline at::Tensor Tensor::unflatten_symint(at::Dimname dim, c10::SymIntArrayRef sizes, at::DimnameList names) const { + return at::_ops::unflatten_Dimname::call(const_cast(*this), dim, sizes, names); +} + +// aten::fill_.Scalar(Tensor(a!) self, Scalar value) -> Tensor(a!) +inline at::Tensor & Tensor::fill_(const at::Scalar & value) const { + return at::_ops::fill__Scalar::call(const_cast(*this), value); +} + +// aten::fill_.Tensor(Tensor(a!) self, Tensor value) -> Tensor(a!) +inline at::Tensor & Tensor::fill_(const at::Tensor & value) const { + return at::_ops::fill__Tensor::call(const_cast(*this), value); +} + +// aten::floor(Tensor self) -> Tensor +inline at::Tensor Tensor::floor() const { + return at::_ops::floor::call(const_cast(*this)); +} + +// aten::floor_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::floor_() const { + return at::_ops::floor_::call(const_cast(*this)); +} + +// aten::floor_divide(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::floor_divide(const at::Tensor & other) const { + return at::_ops::floor_divide::call(const_cast(*this), other); +} + +// aten::floor_divide_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::floor_divide_(const at::Tensor & other) const { + return at::_ops::floor_divide__Tensor::call(const_cast(*this), other); +} + +// aten::floor_divide.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::floor_divide(const at::Scalar & other) const { + return at::_ops::floor_divide_Scalar::call(const_cast(*this), other); +} + +// aten::floor_divide_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::floor_divide_(const at::Scalar & other) const { + return at::_ops::floor_divide__Scalar::call(const_cast(*this), other); +} + +// aten::frac(Tensor self) -> Tensor +inline at::Tensor Tensor::frac() const { + return at::_ops::frac::call(const_cast(*this)); +} + +// aten::frac_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::frac_() const { + return at::_ops::frac_::call(const_cast(*this)); +} + +// aten::gcd(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::gcd(const at::Tensor & other) const { + return at::_ops::gcd::call(const_cast(*this), other); +} + +// aten::gcd_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::gcd_(const at::Tensor & other) const { + return at::_ops::gcd_::call(const_cast(*this), other); +} + +// aten::lcm(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::lcm(const at::Tensor & other) const { + return at::_ops::lcm::call(const_cast(*this), other); +} + +// aten::lcm_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::lcm_(const at::Tensor & other) const { + return at::_ops::lcm_::call(const_cast(*this), other); +} + +// aten::index.Tensor(Tensor self, Tensor?[] indices) -> Tensor +inline at::Tensor Tensor::index(const c10::List<::std::optional> & indices) const { + return at::_ops::index_Tensor::call(const_cast(*this), indices); +} + +// aten::index_copy_(Tensor(a!) self, int dim, Tensor index, Tensor source) -> Tensor(a!) +inline at::Tensor & Tensor::index_copy_(int64_t dim, const at::Tensor & index, const at::Tensor & source) const { + return at::_ops::index_copy_::call(const_cast(*this), dim, index, source); +} + +// aten::index_copy(Tensor self, int dim, Tensor index, Tensor source) -> Tensor +inline at::Tensor Tensor::index_copy(int64_t dim, const at::Tensor & index, const at::Tensor & source) const { + return at::_ops::index_copy::call(const_cast(*this), dim, index, source); +} + +// aten::index_copy_.dimname(Tensor(a!) self, Dimname dim, Tensor index, Tensor source) -> Tensor(a!) +inline at::Tensor & Tensor::index_copy_(at::Dimname dim, const at::Tensor & index, const at::Tensor & source) const { + return at::_ops::index_copy__dimname::call(const_cast(*this), dim, index, source); +} + +// aten::index_copy.dimname(Tensor self, Dimname dim, Tensor index, Tensor source) -> Tensor +inline at::Tensor Tensor::index_copy(at::Dimname dim, const at::Tensor & index, const at::Tensor & source) const { + return at::_ops::index_copy_dimname::call(const_cast(*this), dim, index, source); +} + +// aten::index_put_(Tensor(a!) self, Tensor?[] indices, Tensor values, bool accumulate=False) -> Tensor(a!) +inline at::Tensor & Tensor::index_put_(const c10::List<::std::optional> & indices, const at::Tensor & values, bool accumulate) const { + return at::_ops::index_put_::call(const_cast(*this), indices, values, accumulate); +} + +// aten::index_put(Tensor self, Tensor?[] indices, Tensor values, bool accumulate=False) -> Tensor +inline at::Tensor Tensor::index_put(const c10::List<::std::optional> & indices, const at::Tensor & values, bool accumulate) const { + return at::_ops::index_put::call(const_cast(*this), indices, values, accumulate); +} + +// aten::isclose(Tensor self, Tensor other, float rtol=1e-05, float atol=1e-08, bool equal_nan=False) -> Tensor +inline at::Tensor Tensor::isclose(const at::Tensor & other, double rtol, double atol, bool equal_nan) const { + return at::_ops::isclose::call(const_cast(*this), other, rtol, atol, equal_nan); +} + +// aten::isnan(Tensor self) -> Tensor +inline at::Tensor Tensor::isnan() const { + return at::_ops::isnan::call(const_cast(*this)); +} + +// aten::is_distributed(Tensor self) -> bool +inline bool Tensor::is_distributed() const { + return at::_ops::is_distributed::call(const_cast(*this)); +} + +// aten::is_floating_point(Tensor self) -> bool +inline bool Tensor::__dispatch_is_floating_point() const { + return at::_ops::is_floating_point::call(const_cast(*this)); +} + +// aten::is_complex(Tensor self) -> bool +inline bool Tensor::__dispatch_is_complex() const { + return at::_ops::is_complex::call(const_cast(*this)); +} + +// aten::is_conj(Tensor self) -> bool +inline bool Tensor::__dispatch_is_conj() const { + return at::_ops::is_conj::call(const_cast(*this)); +} + +// aten::_is_zerotensor(Tensor self) -> bool +inline bool Tensor::__dispatch__is_zerotensor() const { + return at::_ops::_is_zerotensor::call(const_cast(*this)); +} + +// aten::is_neg(Tensor self) -> bool +inline bool Tensor::__dispatch_is_neg() const { + return at::_ops::is_neg::call(const_cast(*this)); +} + +// aten::isreal(Tensor self) -> Tensor +inline at::Tensor Tensor::isreal() const { + return at::_ops::isreal::call(const_cast(*this)); +} + +// aten::is_nonzero(Tensor self) -> bool +inline bool Tensor::is_nonzero() const { + return at::_ops::is_nonzero::call(const_cast(*this)); +} + +// aten::is_same_size(Tensor self, Tensor other) -> bool +inline bool Tensor::is_same_size(const at::Tensor & other) const { + return at::_ops::is_same_size::call(const_cast(*this), other); +} + +// aten::is_signed(Tensor self) -> bool +inline bool Tensor::__dispatch_is_signed() const { + return at::_ops::is_signed::call(const_cast(*this)); +} + +// aten::is_inference(Tensor self) -> bool +inline bool Tensor::__dispatch_is_inference() const { + return at::_ops::is_inference::call(const_cast(*this)); +} + +// aten::kron(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::kron(const at::Tensor & other) const { + return at::_ops::kron::call(const_cast(*this), other); +} + +// aten::kthvalue(Tensor self, int k, int dim=-1, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::kthvalue(int64_t k, int64_t dim, bool keepdim) const { + return at::_ops::kthvalue::call(const_cast(*this), k, dim, keepdim); +} + +// aten::kthvalue.dimname(Tensor self, int k, Dimname dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::kthvalue(int64_t k, at::Dimname dim, bool keepdim) const { + return at::_ops::kthvalue_dimname::call(const_cast(*this), k, dim, keepdim); +} + +// aten::nan_to_num(Tensor self, float? nan=None, float? posinf=None, float? neginf=None) -> Tensor +inline at::Tensor Tensor::nan_to_num(::std::optional nan, ::std::optional posinf, ::std::optional neginf) const { + return at::_ops::nan_to_num::call(const_cast(*this), nan, posinf, neginf); +} + +// aten::nan_to_num_(Tensor(a!) self, float? nan=None, float? posinf=None, float? neginf=None) -> Tensor(a!) +inline at::Tensor & Tensor::nan_to_num_(::std::optional nan, ::std::optional posinf, ::std::optional neginf) const { + return at::_ops::nan_to_num_::call(const_cast(*this), nan, posinf, neginf); +} + +// aten::ldexp.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::ldexp(const at::Tensor & other) const { + return at::_ops::ldexp_Tensor::call(const_cast(*this), other); +} + +// aten::ldexp_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::ldexp_(const at::Tensor & other) const { + return at::_ops::ldexp_::call(const_cast(*this), other); +} + +// aten::log(Tensor self) -> Tensor +inline at::Tensor Tensor::log() const { + return at::_ops::log::call(const_cast(*this)); +} + +// aten::log_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::log_() const { + return at::_ops::log_::call(const_cast(*this)); +} + +// aten::log10(Tensor self) -> Tensor +inline at::Tensor Tensor::log10() const { + return at::_ops::log10::call(const_cast(*this)); +} + +// aten::log10_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::log10_() const { + return at::_ops::log10_::call(const_cast(*this)); +} + +// aten::log1p(Tensor self) -> Tensor +inline at::Tensor Tensor::log1p() const { + return at::_ops::log1p::call(const_cast(*this)); +} + +// aten::log1p_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::log1p_() const { + return at::_ops::log1p_::call(const_cast(*this)); +} + +// aten::log2(Tensor self) -> Tensor +inline at::Tensor Tensor::log2() const { + return at::_ops::log2::call(const_cast(*this)); +} + +// aten::log2_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::log2_() const { + return at::_ops::log2_::call(const_cast(*this)); +} + +// aten::logaddexp(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::logaddexp(const at::Tensor & other) const { + return at::_ops::logaddexp::call(const_cast(*this), other); +} + +// aten::logaddexp2(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::logaddexp2(const at::Tensor & other) const { + return at::_ops::logaddexp2::call(const_cast(*this), other); +} + +// aten::xlogy.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::xlogy(const at::Tensor & other) const { + return at::_ops::xlogy_Tensor::call(const_cast(*this), other); +} + +// aten::xlogy.Scalar_Other(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::xlogy(const at::Scalar & other) const { + return at::_ops::xlogy_Scalar_Other::call(const_cast(*this), other); +} + +// aten::xlogy_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::xlogy_(const at::Tensor & other) const { + return at::_ops::xlogy__Tensor::call(const_cast(*this), other); +} + +// aten::xlogy_.Scalar_Other(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::xlogy_(const at::Scalar & other) const { + return at::_ops::xlogy__Scalar_Other::call(const_cast(*this), other); +} + +// aten::log_softmax.int(Tensor self, int dim, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::log_softmax(int64_t dim, ::std::optional dtype) const { + return at::_ops::log_softmax_int::call(const_cast(*this), dim, dtype); +} + +// aten::log_softmax.Dimname(Tensor self, Dimname dim, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::log_softmax(at::Dimname dim, ::std::optional dtype) const { + return at::_ops::log_softmax_Dimname::call(const_cast(*this), dim, dtype); +} + +// aten::logcumsumexp(Tensor self, int dim) -> Tensor +inline at::Tensor Tensor::logcumsumexp(int64_t dim) const { + return at::_ops::logcumsumexp::call(const_cast(*this), dim); +} + +// aten::logcumsumexp.dimname(Tensor self, Dimname dim) -> Tensor +inline at::Tensor Tensor::logcumsumexp(at::Dimname dim) const { + return at::_ops::logcumsumexp_dimname::call(const_cast(*this), dim); +} + +// aten::logsumexp(Tensor self, int[1] dim, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::logsumexp(at::IntArrayRef dim, bool keepdim) const { + return at::_ops::logsumexp::call(const_cast(*this), dim, keepdim); +} + +// aten::logsumexp.names(Tensor self, Dimname[1] dim, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::logsumexp(at::DimnameList dim, bool keepdim) const { + return at::_ops::logsumexp_names::call(const_cast(*this), dim, keepdim); +} + +// aten::matmul(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::matmul(const at::Tensor & other) const { + return at::_ops::matmul::call(const_cast(*this), other); +} + +// aten::matrix_power(Tensor self, int n) -> Tensor +inline at::Tensor Tensor::matrix_power(int64_t n) const { + return at::_ops::matrix_power::call(const_cast(*this), n); +} + +// aten::matrix_exp(Tensor self) -> Tensor +inline at::Tensor Tensor::matrix_exp() const { + return at::_ops::matrix_exp::call(const_cast(*this)); +} + +// aten::aminmax(Tensor self, *, int? dim=None, bool keepdim=False) -> (Tensor min, Tensor max) +inline ::std::tuple Tensor::aminmax(::std::optional dim, bool keepdim) const { + return at::_ops::aminmax::call(const_cast(*this), dim, keepdim); +} + +// aten::max.dim(Tensor self, int dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::max(int64_t dim, bool keepdim) const { + return at::_ops::max_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::max.names_dim(Tensor self, Dimname dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::max(at::Dimname dim, bool keepdim) const { + return at::_ops::max_names_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::amax(Tensor self, int[1] dim=[], bool keepdim=False) -> Tensor +inline at::Tensor Tensor::amax(at::IntArrayRef dim, bool keepdim) const { + return at::_ops::amax::call(const_cast(*this), dim, keepdim); +} + +// aten::mean(Tensor self, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::mean(::std::optional dtype) const { + return at::_ops::mean::call(const_cast(*this), dtype); +} + +// aten::mean.dim(Tensor self, int[1]? dim, bool keepdim=False, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::mean(at::OptionalIntArrayRef dim, bool keepdim, ::std::optional dtype) const { + return at::_ops::mean_dim::call(const_cast(*this), dim, keepdim, dtype); +} + +// aten::mean.names_dim(Tensor self, Dimname[1] dim, bool keepdim=False, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::mean(at::DimnameList dim, bool keepdim, ::std::optional dtype) const { + return at::_ops::mean_names_dim::call(const_cast(*this), dim, keepdim, dtype); +} + +// aten::nanmean(Tensor self, int[1]? dim=None, bool keepdim=False, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::nanmean(at::OptionalIntArrayRef dim, bool keepdim, ::std::optional dtype) const { + return at::_ops::nanmean::call(const_cast(*this), dim, keepdim, dtype); +} + +// aten::median(Tensor self) -> Tensor +inline at::Tensor Tensor::median() const { + return at::_ops::median::call(const_cast(*this)); +} + +// aten::median.dim(Tensor self, int dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::median(int64_t dim, bool keepdim) const { + return at::_ops::median_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::median.names_dim(Tensor self, Dimname dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::median(at::Dimname dim, bool keepdim) const { + return at::_ops::median_names_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::nanmedian(Tensor self) -> Tensor +inline at::Tensor Tensor::nanmedian() const { + return at::_ops::nanmedian::call(const_cast(*this)); +} + +// aten::nanmedian.dim(Tensor self, int dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::nanmedian(int64_t dim, bool keepdim) const { + return at::_ops::nanmedian_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::nanmedian.names_dim(Tensor self, Dimname dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::nanmedian(at::Dimname dim, bool keepdim) const { + return at::_ops::nanmedian_names_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::min.dim(Tensor self, int dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::min(int64_t dim, bool keepdim) const { + return at::_ops::min_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::min.names_dim(Tensor self, Dimname dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::min(at::Dimname dim, bool keepdim) const { + return at::_ops::min_names_dim::call(const_cast(*this), dim, keepdim); +} + +// aten::amin(Tensor self, int[1] dim=[], bool keepdim=False) -> Tensor +inline at::Tensor Tensor::amin(at::IntArrayRef dim, bool keepdim) const { + return at::_ops::amin::call(const_cast(*this), dim, keepdim); +} + +// aten::mm(Tensor self, Tensor mat2) -> Tensor +inline at::Tensor Tensor::mm(const at::Tensor & mat2) const { + return at::_ops::mm::call(const_cast(*this), mat2); +} + +// aten::mode(Tensor self, int dim=-1, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::mode(int64_t dim, bool keepdim) const { + return at::_ops::mode::call(const_cast(*this), dim, keepdim); +} + +// aten::mode.dimname(Tensor self, Dimname dim, bool keepdim=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::mode(at::Dimname dim, bool keepdim) const { + return at::_ops::mode_dimname::call(const_cast(*this), dim, keepdim); +} + +// aten::mul.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::mul(const at::Tensor & other) const { + return at::_ops::mul_Tensor::call(const_cast(*this), other); +} + +// aten::mul_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::mul_(const at::Tensor & other) const { + return at::_ops::mul__Tensor::call(const_cast(*this), other); +} + +// aten::mul.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::mul(const at::Scalar & other) const { + return at::_ops::mul_Scalar::call(const_cast(*this), other); +} + +// aten::mul_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::mul_(const at::Scalar & other) const { + return at::_ops::mul__Scalar::call(const_cast(*this), other); +} + +// aten::multiply.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::multiply(const at::Tensor & other) const { + return at::_ops::multiply_Tensor::call(const_cast(*this), other); +} + +// aten::multiply_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::multiply_(const at::Tensor & other) const { + return at::_ops::multiply__Tensor::call(const_cast(*this), other); +} + +// aten::multiply.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::multiply(const at::Scalar & other) const { + return at::_ops::multiply_Scalar::call(const_cast(*this), other); +} + +// aten::multiply_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::multiply_(const at::Scalar & other) const { + return at::_ops::multiply__Scalar::call(const_cast(*this), other); +} + +// aten::mv(Tensor self, Tensor vec) -> Tensor +inline at::Tensor Tensor::mv(const at::Tensor & vec) const { + return at::_ops::mv::call(const_cast(*this), vec); +} + +// aten::mvlgamma(Tensor self, int p) -> Tensor +inline at::Tensor Tensor::mvlgamma(int64_t p) const { + return at::_ops::mvlgamma::call(const_cast(*this), p); +} + +// aten::mvlgamma_(Tensor(a!) self, int p) -> Tensor(a!) +inline at::Tensor & Tensor::mvlgamma_(int64_t p) const { + return at::_ops::mvlgamma_::call(const_cast(*this), p); +} + +// aten::narrow_copy(Tensor self, int dim, SymInt start, SymInt length) -> Tensor +inline at::Tensor Tensor::narrow_copy(int64_t dim, int64_t start, int64_t length) const { + return at::_ops::narrow_copy::call(const_cast(*this), dim, start, length); +} + +// aten::narrow_copy(Tensor self, int dim, SymInt start, SymInt length) -> Tensor +inline at::Tensor Tensor::narrow_copy_symint(int64_t dim, c10::SymInt start, c10::SymInt length) const { + return at::_ops::narrow_copy::call(const_cast(*this), dim, start, length); +} + +// aten::narrow(Tensor(a) self, int dim, SymInt start, SymInt length) -> Tensor(a) +inline at::Tensor Tensor::narrow(int64_t dim, int64_t start, int64_t length) const { + return at::_ops::narrow::call(const_cast(*this), dim, start, length); +} + +// aten::narrow(Tensor(a) self, int dim, SymInt start, SymInt length) -> Tensor(a) +inline at::Tensor Tensor::narrow_symint(int64_t dim, c10::SymInt start, c10::SymInt length) const { + return at::_ops::narrow::call(const_cast(*this), dim, start, length); +} + +// aten::narrow.Tensor(Tensor(a) self, int dim, Tensor start, SymInt length) -> Tensor(a) +inline at::Tensor Tensor::narrow(int64_t dim, const at::Tensor & start, int64_t length) const { + return at::_ops::narrow_Tensor::call(const_cast(*this), dim, start, length); +} + +// aten::narrow.Tensor(Tensor(a) self, int dim, Tensor start, SymInt length) -> Tensor(a) +inline at::Tensor Tensor::narrow_symint(int64_t dim, const at::Tensor & start, c10::SymInt length) const { + return at::_ops::narrow_Tensor::call(const_cast(*this), dim, start, length); +} + +// aten::permute(Tensor(a) self, int[] dims) -> Tensor(a) +inline at::Tensor Tensor::permute(at::IntArrayRef dims) const { + return at::_ops::permute::call(const_cast(*this), dims); +} + +// aten::movedim.intlist(Tensor(a) self, int[] source, int[] destination) -> Tensor(a) +inline at::Tensor Tensor::movedim(at::IntArrayRef source, at::IntArrayRef destination) const { + return at::_ops::movedim_intlist::call(const_cast(*this), source, destination); +} + +// aten::movedim.int(Tensor(a) self, int source, int destination) -> Tensor(a) +inline at::Tensor Tensor::movedim(int64_t source, int64_t destination) const { + return at::_ops::movedim_int::call(const_cast(*this), source, destination); +} + +// aten::moveaxis.intlist(Tensor(a) self, int[] source, int[] destination) -> Tensor(a) +inline at::Tensor Tensor::moveaxis(at::IntArrayRef source, at::IntArrayRef destination) const { + return at::_ops::moveaxis_intlist::call(const_cast(*this), source, destination); +} + +// aten::moveaxis.int(Tensor(a) self, int source, int destination) -> Tensor(a) +inline at::Tensor Tensor::moveaxis(int64_t source, int64_t destination) const { + return at::_ops::moveaxis_int::call(const_cast(*this), source, destination); +} + +// aten::numpy_T(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::numpy_T() const { + return at::_ops::numpy_T::call(const_cast(*this)); +} + +// aten::matrix_H(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::matrix_H() const { + return at::_ops::matrix_H::call(const_cast(*this)); +} + +// aten::mT(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::mT() const { + return at::_ops::mT::call(const_cast(*this)); +} + +// aten::mH(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::mH() const { + return at::_ops::mH::call(const_cast(*this)); +} + +// aten::adjoint(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::adjoint() const { + return at::_ops::adjoint::call(const_cast(*this)); +} + +// aten::is_pinned(Tensor self, Device? device=None) -> bool +inline bool Tensor::is_pinned(::std::optional device) const { + return at::_ops::is_pinned::call(const_cast(*this), device); +} + +// aten::pin_memory(Tensor(a) self, Device? device=None) -> Tensor(a) +inline at::Tensor Tensor::pin_memory(::std::optional device) const { + return at::_ops::pin_memory::call(const_cast(*this), device); +} + +// aten::pinverse(Tensor self, float rcond=1e-15) -> Tensor +inline at::Tensor Tensor::pinverse(double rcond) const { + return at::_ops::pinverse::call(const_cast(*this), rcond); +} + +// aten::rad2deg(Tensor self) -> Tensor +inline at::Tensor Tensor::rad2deg() const { + return at::_ops::rad2deg::call(const_cast(*this)); +} + +// aten::rad2deg_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::rad2deg_() const { + return at::_ops::rad2deg_::call(const_cast(*this)); +} + +// aten::deg2rad(Tensor self) -> Tensor +inline at::Tensor Tensor::deg2rad() const { + return at::_ops::deg2rad::call(const_cast(*this)); +} + +// aten::deg2rad_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::deg2rad_() const { + return at::_ops::deg2rad_::call(const_cast(*this)); +} + +// aten::ravel(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::ravel() const { + return at::_ops::ravel::call(const_cast(*this)); +} + +// aten::reciprocal(Tensor self) -> Tensor +inline at::Tensor Tensor::reciprocal() const { + return at::_ops::reciprocal::call(const_cast(*this)); +} + +// aten::reciprocal_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::reciprocal_() const { + return at::_ops::reciprocal_::call(const_cast(*this)); +} + +// aten::neg(Tensor self) -> Tensor +inline at::Tensor Tensor::neg() const { + return at::_ops::neg::call(const_cast(*this)); +} + +// aten::neg_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::neg_() const { + return at::_ops::neg_::call(const_cast(*this)); +} + +// aten::negative(Tensor self) -> Tensor +inline at::Tensor Tensor::negative() const { + return at::_ops::negative::call(const_cast(*this)); +} + +// aten::negative_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::negative_() const { + return at::_ops::negative_::call(const_cast(*this)); +} + +// aten::repeat(Tensor self, SymInt[] repeats) -> Tensor +inline at::Tensor Tensor::repeat(at::IntArrayRef repeats) const { + return at::_ops::repeat::call(const_cast(*this), c10::fromIntArrayRefSlow(repeats)); +} + +// aten::repeat(Tensor self, SymInt[] repeats) -> Tensor +inline at::Tensor Tensor::repeat_symint(c10::SymIntArrayRef repeats) const { + return at::_ops::repeat::call(const_cast(*this), repeats); +} + +// aten::repeat_interleave.self_Tensor(Tensor self, Tensor repeats, int? dim=None, *, SymInt? output_size=None) -> Tensor +inline at::Tensor Tensor::repeat_interleave(const at::Tensor & repeats, ::std::optional dim, ::std::optional output_size) const { + return at::_ops::repeat_interleave_self_Tensor::call(const_cast(*this), repeats, dim, output_size.has_value() ? ::std::make_optional(c10::SymInt(*output_size)) : ::std::nullopt); +} + +// aten::repeat_interleave.self_Tensor(Tensor self, Tensor repeats, int? dim=None, *, SymInt? output_size=None) -> Tensor +inline at::Tensor Tensor::repeat_interleave_symint(const at::Tensor & repeats, ::std::optional dim, ::std::optional output_size) const { + return at::_ops::repeat_interleave_self_Tensor::call(const_cast(*this), repeats, dim, output_size); +} + +// aten::repeat_interleave.self_int(Tensor self, SymInt repeats, int? dim=None, *, SymInt? output_size=None) -> Tensor +inline at::Tensor Tensor::repeat_interleave(int64_t repeats, ::std::optional dim, ::std::optional output_size) const { + return at::_ops::repeat_interleave_self_int::call(const_cast(*this), repeats, dim, output_size.has_value() ? ::std::make_optional(c10::SymInt(*output_size)) : ::std::nullopt); +} + +// aten::repeat_interleave.self_int(Tensor self, SymInt repeats, int? dim=None, *, SymInt? output_size=None) -> Tensor +inline at::Tensor Tensor::repeat_interleave_symint(c10::SymInt repeats, ::std::optional dim, ::std::optional output_size) const { + return at::_ops::repeat_interleave_self_int::call(const_cast(*this), repeats, dim, output_size); +} + +// aten::reshape(Tensor(a) self, SymInt[] shape) -> Tensor(a) +inline at::Tensor Tensor::reshape(at::IntArrayRef shape) const { + return at::_ops::reshape::call(const_cast(*this), c10::fromIntArrayRefSlow(shape)); +} + +// aten::reshape(Tensor(a) self, SymInt[] shape) -> Tensor(a) +inline at::Tensor Tensor::reshape_symint(c10::SymIntArrayRef shape) const { + return at::_ops::reshape::call(const_cast(*this), shape); +} + +// aten::_reshape_alias(Tensor(a) self, SymInt[] size, SymInt[] stride) -> Tensor(a) +inline at::Tensor Tensor::_reshape_alias(at::IntArrayRef size, at::IntArrayRef stride) const { + return at::_ops::_reshape_alias::call(const_cast(*this), c10::fromIntArrayRefSlow(size), c10::fromIntArrayRefSlow(stride)); +} + +// aten::_reshape_alias(Tensor(a) self, SymInt[] size, SymInt[] stride) -> Tensor(a) +inline at::Tensor Tensor::_reshape_alias_symint(c10::SymIntArrayRef size, c10::SymIntArrayRef stride) const { + return at::_ops::_reshape_alias::call(const_cast(*this), size, stride); +} + +// aten::reshape_as(Tensor(a) self, Tensor other) -> Tensor(a) +inline at::Tensor Tensor::reshape_as(const at::Tensor & other) const { + return at::_ops::reshape_as::call(const_cast(*this), other); +} + +// aten::round(Tensor self) -> Tensor +inline at::Tensor Tensor::round() const { + return at::_ops::round::call(const_cast(*this)); +} + +// aten::round_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::round_() const { + return at::_ops::round_::call(const_cast(*this)); +} + +// aten::round.decimals(Tensor self, *, int decimals) -> Tensor +inline at::Tensor Tensor::round(int64_t decimals) const { + return at::_ops::round_decimals::call(const_cast(*this), decimals); +} + +// aten::round_.decimals(Tensor(a!) self, *, int decimals) -> Tensor(a!) +inline at::Tensor & Tensor::round_(int64_t decimals) const { + return at::_ops::round__decimals::call(const_cast(*this), decimals); +} + +// aten::relu(Tensor self) -> Tensor +inline at::Tensor Tensor::relu() const { + return at::_ops::relu::call(const_cast(*this)); +} + +// aten::relu_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::relu_() const { + return at::_ops::relu_::call(const_cast(*this)); +} + +// aten::prelu(Tensor self, Tensor weight) -> Tensor +inline at::Tensor Tensor::prelu(const at::Tensor & weight) const { + return at::_ops::prelu::call(const_cast(*this), weight); +} + +// aten::hardshrink(Tensor self, Scalar lambd=0.5) -> Tensor +inline at::Tensor Tensor::hardshrink(const at::Scalar & lambd) const { + return at::_ops::hardshrink::call(const_cast(*this), lambd); +} + +// aten::hardshrink_backward(Tensor grad_out, Tensor self, Scalar lambd) -> Tensor +inline at::Tensor Tensor::hardshrink_backward(const at::Tensor & grad_out, const at::Scalar & lambd) const { + return at::_ops::hardshrink_backward::call(grad_out, const_cast(*this), lambd); +} + +// aten::rsqrt(Tensor self) -> Tensor +inline at::Tensor Tensor::rsqrt() const { + return at::_ops::rsqrt::call(const_cast(*this)); +} + +// aten::rsqrt_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::rsqrt_() const { + return at::_ops::rsqrt_::call(const_cast(*this)); +} + +// aten::select.Dimname(Tensor(a) self, Dimname dim, int index) -> Tensor(a) +inline at::Tensor Tensor::select(at::Dimname dim, int64_t index) const { + return at::_ops::select_Dimname::call(const_cast(*this), dim, index); +} + +// aten::select.int(Tensor(a) self, int dim, SymInt index) -> Tensor(a) +inline at::Tensor Tensor::select(int64_t dim, int64_t index) const { + return at::_ops::select_int::call(const_cast(*this), dim, index); +} + +// aten::select.int(Tensor(a) self, int dim, SymInt index) -> Tensor(a) +inline at::Tensor Tensor::select_symint(int64_t dim, c10::SymInt index) const { + return at::_ops::select_int::call(const_cast(*this), dim, index); +} + +// aten::sigmoid(Tensor self) -> Tensor +inline at::Tensor Tensor::sigmoid() const { + return at::_ops::sigmoid::call(const_cast(*this)); +} + +// aten::sigmoid_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::sigmoid_() const { + return at::_ops::sigmoid_::call(const_cast(*this)); +} + +// aten::logit(Tensor self, float? eps=None) -> Tensor +inline at::Tensor Tensor::logit(::std::optional eps) const { + return at::_ops::logit::call(const_cast(*this), eps); +} + +// aten::logit_(Tensor(a!) self, float? eps=None) -> Tensor(a!) +inline at::Tensor & Tensor::logit_(::std::optional eps) const { + return at::_ops::logit_::call(const_cast(*this), eps); +} + +// aten::sin(Tensor self) -> Tensor +inline at::Tensor Tensor::sin() const { + return at::_ops::sin::call(const_cast(*this)); +} + +// aten::sin_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::sin_() const { + return at::_ops::sin_::call(const_cast(*this)); +} + +// aten::sinc(Tensor self) -> Tensor +inline at::Tensor Tensor::sinc() const { + return at::_ops::sinc::call(const_cast(*this)); +} + +// aten::sinc_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::sinc_() const { + return at::_ops::sinc_::call(const_cast(*this)); +} + +// aten::sinh(Tensor self) -> Tensor +inline at::Tensor Tensor::sinh() const { + return at::_ops::sinh::call(const_cast(*this)); +} + +// aten::sinh_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::sinh_() const { + return at::_ops::sinh_::call(const_cast(*this)); +} + +// aten::detach(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::detach() const { + return at::_ops::detach::call(const_cast(*this)); +} + +// aten::detach_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::detach_() const { + return at::_ops::detach_::call(const_cast(*this)); +} + +// aten::size.Dimname(Tensor self, Dimname dim) -> int +inline int64_t Tensor::size(at::Dimname dim) const { + return at::_ops::size_Dimname::call(const_cast(*this), dim); +} + +// aten::slice.Tensor(Tensor(a) self, int dim=0, SymInt? start=None, SymInt? end=None, SymInt step=1) -> Tensor(a) +inline at::Tensor Tensor::slice(int64_t dim, ::std::optional start, ::std::optional end, int64_t step) const { + return at::_ops::slice_Tensor::call(const_cast(*this), dim, start.has_value() ? ::std::make_optional(c10::SymInt(*start)) : ::std::nullopt, end.has_value() ? ::std::make_optional(c10::SymInt(*end)) : ::std::nullopt, step); +} + +// aten::slice.Tensor(Tensor(a) self, int dim=0, SymInt? start=None, SymInt? end=None, SymInt step=1) -> Tensor(a) +inline at::Tensor Tensor::slice_symint(int64_t dim, ::std::optional start, ::std::optional end, c10::SymInt step) const { + return at::_ops::slice_Tensor::call(const_cast(*this), dim, start, end, step); +} + +// aten::slice_inverse(Tensor(a) self, Tensor src, int dim=0, SymInt? start=None, SymInt? end=None, SymInt step=1) -> Tensor(a) +inline at::Tensor Tensor::slice_inverse(const at::Tensor & src, int64_t dim, ::std::optional start, ::std::optional end, int64_t step) const { + return at::_ops::slice_inverse::call(const_cast(*this), src, dim, start.has_value() ? ::std::make_optional(c10::SymInt(*start)) : ::std::nullopt, end.has_value() ? ::std::make_optional(c10::SymInt(*end)) : ::std::nullopt, step); +} + +// aten::slice_inverse(Tensor(a) self, Tensor src, int dim=0, SymInt? start=None, SymInt? end=None, SymInt step=1) -> Tensor(a) +inline at::Tensor Tensor::slice_inverse_symint(const at::Tensor & src, int64_t dim, ::std::optional start, ::std::optional end, c10::SymInt step) const { + return at::_ops::slice_inverse::call(const_cast(*this), src, dim, start, end, step); +} + +// aten::slice_scatter(Tensor self, Tensor src, int dim=0, SymInt? start=None, SymInt? end=None, SymInt step=1) -> Tensor +inline at::Tensor Tensor::slice_scatter(const at::Tensor & src, int64_t dim, ::std::optional start, ::std::optional end, int64_t step) const { + return at::_ops::slice_scatter::call(const_cast(*this), src, dim, start.has_value() ? ::std::make_optional(c10::SymInt(*start)) : ::std::nullopt, end.has_value() ? ::std::make_optional(c10::SymInt(*end)) : ::std::nullopt, step); +} + +// aten::slice_scatter(Tensor self, Tensor src, int dim=0, SymInt? start=None, SymInt? end=None, SymInt step=1) -> Tensor +inline at::Tensor Tensor::slice_scatter_symint(const at::Tensor & src, int64_t dim, ::std::optional start, ::std::optional end, c10::SymInt step) const { + return at::_ops::slice_scatter::call(const_cast(*this), src, dim, start, end, step); +} + +// aten::select_scatter(Tensor self, Tensor src, int dim, SymInt index) -> Tensor +inline at::Tensor Tensor::select_scatter(const at::Tensor & src, int64_t dim, int64_t index) const { + return at::_ops::select_scatter::call(const_cast(*this), src, dim, index); +} + +// aten::select_scatter(Tensor self, Tensor src, int dim, SymInt index) -> Tensor +inline at::Tensor Tensor::select_scatter_symint(const at::Tensor & src, int64_t dim, c10::SymInt index) const { + return at::_ops::select_scatter::call(const_cast(*this), src, dim, index); +} + +// aten::diagonal_scatter(Tensor self, Tensor src, int offset=0, int dim1=0, int dim2=1) -> Tensor +inline at::Tensor Tensor::diagonal_scatter(const at::Tensor & src, int64_t offset, int64_t dim1, int64_t dim2) const { + return at::_ops::diagonal_scatter::call(const_cast(*this), src, offset, dim1, dim2); +} + +// aten::as_strided_scatter(Tensor self, Tensor src, SymInt[] size, SymInt[] stride, SymInt? storage_offset=None) -> Tensor +inline at::Tensor Tensor::as_strided_scatter(const at::Tensor & src, at::IntArrayRef size, at::IntArrayRef stride, ::std::optional storage_offset) const { + return at::_ops::as_strided_scatter::call(const_cast(*this), src, c10::fromIntArrayRefSlow(size), c10::fromIntArrayRefSlow(stride), storage_offset.has_value() ? ::std::make_optional(c10::SymInt(*storage_offset)) : ::std::nullopt); +} + +// aten::as_strided_scatter(Tensor self, Tensor src, SymInt[] size, SymInt[] stride, SymInt? storage_offset=None) -> Tensor +inline at::Tensor Tensor::as_strided_scatter_symint(const at::Tensor & src, c10::SymIntArrayRef size, c10::SymIntArrayRef stride, ::std::optional storage_offset) const { + return at::_ops::as_strided_scatter::call(const_cast(*this), src, size, stride, storage_offset); +} + +// aten::smm(Tensor self, Tensor mat2) -> Tensor +inline at::Tensor Tensor::smm(const at::Tensor & mat2) const { + return at::_ops::smm::call(const_cast(*this), mat2); +} + +// aten::softmax.int(Tensor self, int dim, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::softmax(int64_t dim, ::std::optional dtype) const { + return at::_ops::softmax_int::call(const_cast(*this), dim, dtype); +} + +// aten::softmax.Dimname(Tensor self, Dimname dim, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::softmax(at::Dimname dim, ::std::optional dtype) const { + return at::_ops::softmax_Dimname::call(const_cast(*this), dim, dtype); +} + +// aten::unsafe_split.Tensor(Tensor self, SymInt split_size, int dim=0) -> Tensor[] +inline ::std::vector Tensor::unsafe_split(int64_t split_size, int64_t dim) const { + return at::_ops::unsafe_split_Tensor::call(const_cast(*this), split_size, dim); +} + +// aten::unsafe_split.Tensor(Tensor self, SymInt split_size, int dim=0) -> Tensor[] +inline ::std::vector Tensor::unsafe_split_symint(c10::SymInt split_size, int64_t dim) const { + return at::_ops::unsafe_split_Tensor::call(const_cast(*this), split_size, dim); +} + +// aten::split.Tensor(Tensor(a -> *) self, SymInt split_size, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::split(int64_t split_size, int64_t dim) const { + return at::_ops::split_Tensor::call(const_cast(*this), split_size, dim); +} + +// aten::split.Tensor(Tensor(a -> *) self, SymInt split_size, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::split_symint(c10::SymInt split_size, int64_t dim) const { + return at::_ops::split_Tensor::call(const_cast(*this), split_size, dim); +} + +// aten::split.sizes(Tensor(a -> *) self, SymInt[] split_size, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::split(at::IntArrayRef split_size, int64_t dim) const { + return at::_ops::split_sizes::call(const_cast(*this), c10::fromIntArrayRefSlow(split_size), dim); +} + +// aten::split.sizes(Tensor(a -> *) self, SymInt[] split_size, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::split_symint(c10::SymIntArrayRef split_size, int64_t dim) const { + return at::_ops::split_sizes::call(const_cast(*this), split_size, dim); +} + +// aten::unsafe_split_with_sizes(Tensor self, SymInt[] split_sizes, int dim=0) -> Tensor[] +inline ::std::vector Tensor::unsafe_split_with_sizes(at::IntArrayRef split_sizes, int64_t dim) const { + return at::_ops::unsafe_split_with_sizes::call(const_cast(*this), c10::fromIntArrayRefSlow(split_sizes), dim); +} + +// aten::unsafe_split_with_sizes(Tensor self, SymInt[] split_sizes, int dim=0) -> Tensor[] +inline ::std::vector Tensor::unsafe_split_with_sizes_symint(c10::SymIntArrayRef split_sizes, int64_t dim) const { + return at::_ops::unsafe_split_with_sizes::call(const_cast(*this), split_sizes, dim); +} + +// aten::split_with_sizes(Tensor(a -> *) self, SymInt[] split_sizes, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::split_with_sizes(at::IntArrayRef split_sizes, int64_t dim) const { + return at::_ops::split_with_sizes::call(const_cast(*this), c10::fromIntArrayRefSlow(split_sizes), dim); +} + +// aten::split_with_sizes(Tensor(a -> *) self, SymInt[] split_sizes, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::split_with_sizes_symint(c10::SymIntArrayRef split_sizes, int64_t dim) const { + return at::_ops::split_with_sizes::call(const_cast(*this), split_sizes, dim); +} + +// aten::hsplit.int(Tensor(a -> *) self, int sections) -> Tensor(a)[] +inline ::std::vector Tensor::hsplit(int64_t sections) const { + return at::_ops::hsplit_int::call(const_cast(*this), sections); +} + +// aten::hsplit.array(Tensor(a -> *) self, int[] indices) -> Tensor(a)[] +inline ::std::vector Tensor::hsplit(at::IntArrayRef indices) const { + return at::_ops::hsplit_array::call(const_cast(*this), indices); +} + +// aten::vsplit.int(Tensor(a -> *) self, int sections) -> Tensor(a)[] +inline ::std::vector Tensor::vsplit(int64_t sections) const { + return at::_ops::vsplit_int::call(const_cast(*this), sections); +} + +// aten::vsplit.array(Tensor(a -> *) self, int[] indices) -> Tensor(a)[] +inline ::std::vector Tensor::vsplit(at::IntArrayRef indices) const { + return at::_ops::vsplit_array::call(const_cast(*this), indices); +} + +// aten::dsplit.int(Tensor(a -> *) self, int sections) -> Tensor(a)[] +inline ::std::vector Tensor::dsplit(int64_t sections) const { + return at::_ops::dsplit_int::call(const_cast(*this), sections); +} + +// aten::dsplit.array(Tensor(a -> *) self, int[] indices) -> Tensor(a)[] +inline ::std::vector Tensor::dsplit(at::IntArrayRef indices) const { + return at::_ops::dsplit_array::call(const_cast(*this), indices); +} + +// aten::squeeze(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::squeeze() const { + return at::_ops::squeeze::call(const_cast(*this)); +} + +// aten::squeeze.dim(Tensor(a) self, int dim) -> Tensor(a) +inline at::Tensor Tensor::squeeze(int64_t dim) const { + return at::_ops::squeeze_dim::call(const_cast(*this), dim); +} + +// aten::squeeze.dimname(Tensor(a) self, Dimname dim) -> Tensor(a) +inline at::Tensor Tensor::squeeze(at::Dimname dim) const { + return at::_ops::squeeze_dimname::call(const_cast(*this), dim); +} + +// aten::squeeze.dims(Tensor(a) self, int[] dim) -> Tensor(a) +inline at::Tensor Tensor::squeeze(at::IntArrayRef dim) const { + return at::_ops::squeeze_dims::call(const_cast(*this), dim); +} + +// aten::squeeze_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::squeeze_() const { + return at::_ops::squeeze_::call(const_cast(*this)); +} + +// aten::squeeze_.dim(Tensor(a!) self, int dim) -> Tensor(a!) +inline at::Tensor & Tensor::squeeze_(int64_t dim) const { + return at::_ops::squeeze__dim::call(const_cast(*this), dim); +} + +// aten::squeeze_.dims(Tensor(a!) self, int[] dim) -> Tensor(a!) +inline at::Tensor & Tensor::squeeze_(at::IntArrayRef dim) const { + return at::_ops::squeeze__dims::call(const_cast(*this), dim); +} + +// aten::squeeze_.dimname(Tensor(a!) self, Dimname dim) -> Tensor(a!) +inline at::Tensor & Tensor::squeeze_(at::Dimname dim) const { + return at::_ops::squeeze__dimname::call(const_cast(*this), dim); +} + +// aten::sspaddmm(Tensor self, Tensor mat1, Tensor mat2, *, Scalar beta=1, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::sspaddmm(const at::Tensor & mat1, const at::Tensor & mat2, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::sspaddmm::call(const_cast(*this), mat1, mat2, beta, alpha); +} + +// aten::stft(Tensor self, int n_fft, int? hop_length=None, int? win_length=None, Tensor? window=None, bool normalized=False, bool? onesided=None, bool? return_complex=None, bool? align_to_window=None) -> Tensor +inline at::Tensor Tensor::stft(int64_t n_fft, ::std::optional hop_length, ::std::optional win_length, const ::std::optional & window, bool normalized, ::std::optional onesided, ::std::optional return_complex, ::std::optional align_to_window) const { + return at::_ops::stft::call(const_cast(*this), n_fft, hop_length, win_length, window, normalized, onesided, return_complex, align_to_window); +} + +// aten::stft.center(Tensor self, int n_fft, int? hop_length=None, int? win_length=None, Tensor? window=None, bool center=True, str pad_mode="reflect", bool normalized=False, bool? onesided=None, bool? return_complex=None, bool? align_to_window=None) -> Tensor +inline at::Tensor Tensor::stft(int64_t n_fft, ::std::optional hop_length, ::std::optional win_length, const ::std::optional & window, bool center, c10::string_view pad_mode, bool normalized, ::std::optional onesided, ::std::optional return_complex, ::std::optional align_to_window) const { + return at::_ops::stft_center::call(const_cast(*this), n_fft, hop_length, win_length, window, center, pad_mode, normalized, onesided, return_complex, align_to_window); +} + +// aten::istft(Tensor self, int n_fft, int? hop_length=None, int? win_length=None, Tensor? window=None, bool center=True, bool normalized=False, bool? onesided=None, int? length=None, bool return_complex=False) -> Tensor +inline at::Tensor Tensor::istft(int64_t n_fft, ::std::optional hop_length, ::std::optional win_length, const ::std::optional & window, bool center, bool normalized, ::std::optional onesided, ::std::optional length, bool return_complex) const { + return at::_ops::istft::call(const_cast(*this), n_fft, hop_length, win_length, window, center, normalized, onesided, length, return_complex); +} + +// aten::stride.Dimname(Tensor self, Dimname dim) -> int +inline int64_t Tensor::stride(at::Dimname dim) const { + return at::_ops::stride_Dimname::call(const_cast(*this), dim); +} + +// aten::sum(Tensor self, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::sum(::std::optional dtype) const { + return at::_ops::sum::call(const_cast(*this), dtype); +} + +// aten::sum.dim_IntList(Tensor self, int[1]? dim, bool keepdim=False, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::sum(at::OptionalIntArrayRef dim, bool keepdim, ::std::optional dtype) const { + return at::_ops::sum_dim_IntList::call(const_cast(*this), dim, keepdim, dtype); +} + +// aten::sum.dim_DimnameList(Tensor self, Dimname[1] dim, bool keepdim=False, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::sum(at::DimnameList dim, bool keepdim, ::std::optional dtype) const { + return at::_ops::sum_dim_DimnameList::call(const_cast(*this), dim, keepdim, dtype); +} + +// aten::nansum(Tensor self, int[1]? dim=None, bool keepdim=False, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::nansum(at::OptionalIntArrayRef dim, bool keepdim, ::std::optional dtype) const { + return at::_ops::nansum::call(const_cast(*this), dim, keepdim, dtype); +} + +// aten::sum_to_size(Tensor self, SymInt[] size) -> Tensor +inline at::Tensor Tensor::sum_to_size(at::IntArrayRef size) const { + return at::_ops::sum_to_size::call(const_cast(*this), c10::fromIntArrayRefSlow(size)); +} + +// aten::sum_to_size(Tensor self, SymInt[] size) -> Tensor +inline at::Tensor Tensor::sum_to_size_symint(c10::SymIntArrayRef size) const { + return at::_ops::sum_to_size::call(const_cast(*this), size); +} + +// aten::sqrt(Tensor self) -> Tensor +inline at::Tensor Tensor::sqrt() const { + return at::_ops::sqrt::call(const_cast(*this)); +} + +// aten::sqrt_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::sqrt_() const { + return at::_ops::sqrt_::call(const_cast(*this)); +} + +// aten::square(Tensor self) -> Tensor +inline at::Tensor Tensor::square() const { + return at::_ops::square::call(const_cast(*this)); +} + +// aten::square_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::square_() const { + return at::_ops::square_::call(const_cast(*this)); +} + +// aten::std(Tensor self, bool unbiased=True) -> Tensor +inline at::Tensor Tensor::std(bool unbiased) const { + return at::_ops::std::call(const_cast(*this), unbiased); +} + +// aten::std.dim(Tensor self, int[1]? dim, bool unbiased=True, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::std(at::OptionalIntArrayRef dim, bool unbiased, bool keepdim) const { + return at::_ops::std_dim::call(const_cast(*this), dim, unbiased, keepdim); +} + +// aten::std.correction(Tensor self, int[1]? dim=None, *, Scalar? correction=None, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::std(at::OptionalIntArrayRef dim, const ::std::optional & correction, bool keepdim) const { + return at::_ops::std_correction::call(const_cast(*this), dim, correction, keepdim); +} + +// aten::std.names_dim(Tensor self, Dimname[1] dim, bool unbiased=True, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::std(at::DimnameList dim, bool unbiased, bool keepdim) const { + return at::_ops::std_names_dim::call(const_cast(*this), dim, unbiased, keepdim); +} + +// aten::std.correction_names(Tensor self, Dimname[1] dim, *, Scalar? correction=None, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::std(at::DimnameList dim, const ::std::optional & correction, bool keepdim) const { + return at::_ops::std_correction_names::call(const_cast(*this), dim, correction, keepdim); +} + +// aten::prod(Tensor self, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::prod(::std::optional dtype) const { + return at::_ops::prod::call(const_cast(*this), dtype); +} + +// aten::prod.dim_int(Tensor self, int dim, bool keepdim=False, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::prod(int64_t dim, bool keepdim, ::std::optional dtype) const { + return at::_ops::prod_dim_int::call(const_cast(*this), dim, keepdim, dtype); +} + +// aten::prod.dim_Dimname(Tensor self, Dimname dim, bool keepdim=False, *, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::prod(at::Dimname dim, bool keepdim, ::std::optional dtype) const { + return at::_ops::prod_dim_Dimname::call(const_cast(*this), dim, keepdim, dtype); +} + +// aten::t(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::t() const { + return at::_ops::t::call(const_cast(*this)); +} + +// aten::t_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::t_() const { + return at::_ops::t_::call(const_cast(*this)); +} + +// aten::tan(Tensor self) -> Tensor +inline at::Tensor Tensor::tan() const { + return at::_ops::tan::call(const_cast(*this)); +} + +// aten::tan_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::tan_() const { + return at::_ops::tan_::call(const_cast(*this)); +} + +// aten::tanh(Tensor self) -> Tensor +inline at::Tensor Tensor::tanh() const { + return at::_ops::tanh::call(const_cast(*this)); +} + +// aten::tanh_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::tanh_() const { + return at::_ops::tanh_::call(const_cast(*this)); +} + +// aten::tile(Tensor self, SymInt[] dims) -> Tensor +inline at::Tensor Tensor::tile(at::IntArrayRef dims) const { + return at::_ops::tile::call(const_cast(*this), c10::fromIntArrayRefSlow(dims)); +} + +// aten::tile(Tensor self, SymInt[] dims) -> Tensor +inline at::Tensor Tensor::tile_symint(c10::SymIntArrayRef dims) const { + return at::_ops::tile::call(const_cast(*this), dims); +} + +// aten::transpose.int(Tensor(a) self, int dim0, int dim1) -> Tensor(a) +inline at::Tensor Tensor::transpose(int64_t dim0, int64_t dim1) const { + return at::_ops::transpose_int::call(const_cast(*this), dim0, dim1); +} + +// aten::transpose.Dimname(Tensor(a) self, Dimname dim0, Dimname dim1) -> Tensor(a) +inline at::Tensor Tensor::transpose(at::Dimname dim0, at::Dimname dim1) const { + return at::_ops::transpose_Dimname::call(const_cast(*this), dim0, dim1); +} + +// aten::transpose_(Tensor(a!) self, int dim0, int dim1) -> Tensor(a!) +inline at::Tensor & Tensor::transpose_(int64_t dim0, int64_t dim1) const { + return at::_ops::transpose_::call(const_cast(*this), dim0, dim1); +} + +// aten::flip(Tensor self, int[] dims) -> Tensor +inline at::Tensor Tensor::flip(at::IntArrayRef dims) const { + return at::_ops::flip::call(const_cast(*this), dims); +} + +// aten::fliplr(Tensor self) -> Tensor +inline at::Tensor Tensor::fliplr() const { + return at::_ops::fliplr::call(const_cast(*this)); +} + +// aten::flipud(Tensor self) -> Tensor +inline at::Tensor Tensor::flipud() const { + return at::_ops::flipud::call(const_cast(*this)); +} + +// aten::roll(Tensor self, SymInt[1] shifts, int[1] dims=[]) -> Tensor +inline at::Tensor Tensor::roll(at::IntArrayRef shifts, at::IntArrayRef dims) const { + return at::_ops::roll::call(const_cast(*this), c10::fromIntArrayRefSlow(shifts), dims); +} + +// aten::roll(Tensor self, SymInt[1] shifts, int[1] dims=[]) -> Tensor +inline at::Tensor Tensor::roll_symint(c10::SymIntArrayRef shifts, at::IntArrayRef dims) const { + return at::_ops::roll::call(const_cast(*this), shifts, dims); +} + +// aten::rot90(Tensor self, int k=1, int[] dims=[0,1]) -> Tensor +inline at::Tensor Tensor::rot90(int64_t k, at::IntArrayRef dims) const { + return at::_ops::rot90::call(const_cast(*this), k, dims); +} + +// aten::_nested_tensor_size(Tensor self) -> Tensor +inline at::Tensor Tensor::_nested_tensor_size() const { + return at::_ops::_nested_tensor_size::call(const_cast(*this)); +} + +// aten::_nested_tensor_strides(Tensor self) -> Tensor +inline at::Tensor Tensor::_nested_tensor_strides() const { + return at::_ops::_nested_tensor_strides::call(const_cast(*this)); +} + +// aten::_nested_tensor_storage_offsets(Tensor self) -> Tensor +inline at::Tensor Tensor::_nested_tensor_storage_offsets() const { + return at::_ops::_nested_tensor_storage_offsets::call(const_cast(*this)); +} + +// aten::trunc(Tensor self) -> Tensor +inline at::Tensor Tensor::trunc() const { + return at::_ops::trunc::call(const_cast(*this)); +} + +// aten::trunc_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::trunc_() const { + return at::_ops::trunc_::call(const_cast(*this)); +} + +// aten::fix(Tensor self) -> Tensor +inline at::Tensor Tensor::fix() const { + return at::_ops::fix::call(const_cast(*this)); +} + +// aten::fix_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::fix_() const { + return at::_ops::fix_::call(const_cast(*this)); +} + +// aten::type_as(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::type_as(const at::Tensor & other) const { + return at::_ops::type_as::call(const_cast(*this), other); +} + +// aten::unsqueeze(Tensor(a) self, int dim) -> Tensor(a) +inline at::Tensor Tensor::unsqueeze(int64_t dim) const { + return at::_ops::unsqueeze::call(const_cast(*this), dim); +} + +// aten::unsqueeze_(Tensor(a!) self, int dim) -> Tensor(a!) +inline at::Tensor & Tensor::unsqueeze_(int64_t dim) const { + return at::_ops::unsqueeze_::call(const_cast(*this), dim); +} + +// aten::var(Tensor self, bool unbiased=True) -> Tensor +inline at::Tensor Tensor::var(bool unbiased) const { + return at::_ops::var::call(const_cast(*this), unbiased); +} + +// aten::var.dim(Tensor self, int[1]? dim, bool unbiased=True, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::var(at::OptionalIntArrayRef dim, bool unbiased, bool keepdim) const { + return at::_ops::var_dim::call(const_cast(*this), dim, unbiased, keepdim); +} + +// aten::var.correction(Tensor self, int[1]? dim=None, *, Scalar? correction=None, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::var(at::OptionalIntArrayRef dim, const ::std::optional & correction, bool keepdim) const { + return at::_ops::var_correction::call(const_cast(*this), dim, correction, keepdim); +} + +// aten::var.names_dim(Tensor self, Dimname[1] dim, bool unbiased=True, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::var(at::DimnameList dim, bool unbiased, bool keepdim) const { + return at::_ops::var_names_dim::call(const_cast(*this), dim, unbiased, keepdim); +} + +// aten::var.correction_names(Tensor self, Dimname[1] dim, *, Scalar? correction=None, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::var(at::DimnameList dim, const ::std::optional & correction, bool keepdim) const { + return at::_ops::var_correction_names::call(const_cast(*this), dim, correction, keepdim); +} + +// aten::view_as(Tensor(a) self, Tensor other) -> Tensor(a) +inline at::Tensor Tensor::view_as(const at::Tensor & other) const { + return at::_ops::view_as::call(const_cast(*this), other); +} + +// aten::where.self(Tensor condition, Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::where(const at::Tensor & condition, const at::Tensor & other) const { + return at::_ops::where_self::call(condition, const_cast(*this), other); +} + +// aten::where.ScalarOther(Tensor condition, Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::where(const at::Tensor & condition, const at::Scalar & other) const { + return at::_ops::where_ScalarOther::call(condition, const_cast(*this), other); +} + +// aten::norm.ScalarOpt_dtype(Tensor self, Scalar? p, *, ScalarType dtype) -> Tensor +inline at::Tensor Tensor::norm(const ::std::optional & p, at::ScalarType dtype) const { + return at::_ops::norm_ScalarOpt_dtype::call(const_cast(*this), p, dtype); +} + +// aten::norm.Scalar(Tensor self, Scalar p=2) -> Tensor +inline at::Tensor Tensor::norm(const at::Scalar & p) const { + return at::_ops::norm_Scalar::call(const_cast(*this), p); +} + +// aten::norm.ScalarOpt_dim_dtype(Tensor self, Scalar? p, int[1] dim, bool keepdim, *, ScalarType dtype) -> Tensor +inline at::Tensor Tensor::norm(const ::std::optional & p, at::IntArrayRef dim, bool keepdim, at::ScalarType dtype) const { + return at::_ops::norm_ScalarOpt_dim_dtype::call(const_cast(*this), p, dim, keepdim, dtype); +} + +// aten::norm.ScalarOpt_dim(Tensor self, Scalar? p, int[1] dim, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::norm(const ::std::optional & p, at::IntArrayRef dim, bool keepdim) const { + return at::_ops::norm_ScalarOpt_dim::call(const_cast(*this), p, dim, keepdim); +} + +// aten::norm.names_ScalarOpt_dim_dtype(Tensor self, Scalar? p, Dimname[1] dim, bool keepdim, *, ScalarType dtype) -> Tensor +inline at::Tensor Tensor::norm(const ::std::optional & p, at::DimnameList dim, bool keepdim, at::ScalarType dtype) const { + return at::_ops::norm_names_ScalarOpt_dim_dtype::call(const_cast(*this), p, dim, keepdim, dtype); +} + +// aten::norm.names_ScalarOpt_dim(Tensor self, Scalar? p, Dimname[1] dim, bool keepdim=False) -> Tensor +inline at::Tensor Tensor::norm(const ::std::optional & p, at::DimnameList dim, bool keepdim) const { + return at::_ops::norm_names_ScalarOpt_dim::call(const_cast(*this), p, dim, keepdim); +} + +// aten::frexp.Tensor(Tensor self) -> (Tensor mantissa, Tensor exponent) +inline ::std::tuple Tensor::frexp() const { + return at::_ops::frexp_Tensor::call(const_cast(*this)); +} + +// aten::clone(Tensor self, *, MemoryFormat? memory_format=None) -> Tensor +inline at::Tensor Tensor::clone(::std::optional memory_format) const { + return at::_ops::clone::call(const_cast(*this), memory_format); +} + +// aten::positive(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::positive() const { + return at::_ops::positive::call(const_cast(*this)); +} + +// aten::resize_as_(Tensor(a!) self, Tensor the_template, *, MemoryFormat? memory_format=None) -> Tensor(a!) +inline const at::Tensor & Tensor::resize_as_(const at::Tensor & the_template, ::std::optional memory_format) const { + return at::_ops::resize_as_::call(const_cast(*this), the_template, memory_format); +} + +// aten::resize_as_sparse_(Tensor(a!) self, Tensor the_template) -> Tensor(a!) +inline const at::Tensor & Tensor::resize_as_sparse_(const at::Tensor & the_template) const { + return at::_ops::resize_as_sparse_::call(const_cast(*this), the_template); +} + +// aten::zero_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::zero_() const { + return at::_ops::zero_::call(const_cast(*this)); +} + +// aten::sub.Tensor(Tensor self, Tensor other, *, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::sub(const at::Tensor & other, const at::Scalar & alpha) const { + return at::_ops::sub_Tensor::call(const_cast(*this), other, alpha); +} + +// aten::sub_.Tensor(Tensor(a!) self, Tensor other, *, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::sub_(const at::Tensor & other, const at::Scalar & alpha) const { + return at::_ops::sub__Tensor::call(const_cast(*this), other, alpha); +} + +// aten::sub.Scalar(Tensor self, Scalar other, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::sub(const at::Scalar & other, const at::Scalar & alpha) const { + return at::_ops::sub_Scalar::call(const_cast(*this), other, alpha); +} + +// aten::sub_.Scalar(Tensor(a!) self, Scalar other, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::sub_(const at::Scalar & other, const at::Scalar & alpha) const { + return at::_ops::sub__Scalar::call(const_cast(*this), other, alpha); +} + +// aten::subtract.Tensor(Tensor self, Tensor other, *, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::subtract(const at::Tensor & other, const at::Scalar & alpha) const { + return at::_ops::subtract_Tensor::call(const_cast(*this), other, alpha); +} + +// aten::subtract_.Tensor(Tensor(a!) self, Tensor other, *, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::subtract_(const at::Tensor & other, const at::Scalar & alpha) const { + return at::_ops::subtract__Tensor::call(const_cast(*this), other, alpha); +} + +// aten::subtract.Scalar(Tensor self, Scalar other, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::subtract(const at::Scalar & other, const at::Scalar & alpha) const { + return at::_ops::subtract_Scalar::call(const_cast(*this), other, alpha); +} + +// aten::subtract_.Scalar(Tensor(a!) self, Scalar other, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::subtract_(const at::Scalar & other, const at::Scalar & alpha) const { + return at::_ops::subtract__Scalar::call(const_cast(*this), other, alpha); +} + +// aten::heaviside(Tensor self, Tensor values) -> Tensor +inline at::Tensor Tensor::heaviside(const at::Tensor & values) const { + return at::_ops::heaviside::call(const_cast(*this), values); +} + +// aten::heaviside_(Tensor(a!) self, Tensor values) -> Tensor(a!) +inline at::Tensor & Tensor::heaviside_(const at::Tensor & values) const { + return at::_ops::heaviside_::call(const_cast(*this), values); +} + +// aten::addmm(Tensor self, Tensor mat1, Tensor mat2, *, Scalar beta=1, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::addmm(const at::Tensor & mat1, const at::Tensor & mat2, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::addmm::call(const_cast(*this), mat1, mat2, beta, alpha); +} + +// aten::addmm_(Tensor(a!) self, Tensor mat1, Tensor mat2, *, Scalar beta=1, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::addmm_(const at::Tensor & mat1, const at::Tensor & mat2, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::addmm_::call(const_cast(*this), mat1, mat2, beta, alpha); +} + +// aten::_addmm_activation(Tensor self, Tensor mat1, Tensor mat2, *, Scalar beta=1, Scalar alpha=1, bool use_gelu=False) -> Tensor +inline at::Tensor Tensor::_addmm_activation(const at::Tensor & mat1, const at::Tensor & mat2, const at::Scalar & beta, const at::Scalar & alpha, bool use_gelu) const { + return at::_ops::_addmm_activation::call(const_cast(*this), mat1, mat2, beta, alpha, use_gelu); +} + +// aten::sparse_resize_(Tensor(a!) self, int[] size, int sparse_dim, int dense_dim) -> Tensor(a!) +inline const at::Tensor & Tensor::sparse_resize_(at::IntArrayRef size, int64_t sparse_dim, int64_t dense_dim) const { + return at::_ops::sparse_resize_::call(const_cast(*this), size, sparse_dim, dense_dim); +} + +// aten::sparse_resize_and_clear_(Tensor(a!) self, int[] size, int sparse_dim, int dense_dim) -> Tensor(a!) +inline const at::Tensor & Tensor::sparse_resize_and_clear_(at::IntArrayRef size, int64_t sparse_dim, int64_t dense_dim) const { + return at::_ops::sparse_resize_and_clear_::call(const_cast(*this), size, sparse_dim, dense_dim); +} + +// aten::sparse_mask(Tensor self, Tensor mask) -> Tensor +inline at::Tensor Tensor::sparse_mask(const at::Tensor & mask) const { + return at::_ops::sparse_mask::call(const_cast(*this), mask); +} + +// aten::_sparse_mask_projection(Tensor self, Tensor mask, bool accumulate_matches=False) -> Tensor +inline at::Tensor Tensor::_sparse_mask_projection(const at::Tensor & mask, bool accumulate_matches) const { + return at::_ops::_sparse_mask_projection::call(const_cast(*this), mask, accumulate_matches); +} + +// aten::to_dense(Tensor self, ScalarType? dtype=None, *, bool? masked_grad=None) -> Tensor +inline at::Tensor Tensor::to_dense(::std::optional dtype, ::std::optional masked_grad) const { + return at::_ops::to_dense::call(const_cast(*this), dtype, masked_grad); +} + +// aten::_to_dense(Tensor self, ScalarType? dtype=None, bool? masked_grad=None) -> Tensor +inline at::Tensor Tensor::_to_dense(::std::optional dtype, ::std::optional masked_grad) const { + return at::_ops::_to_dense::call(const_cast(*this), dtype, masked_grad); +} + +// aten::sparse_dim(Tensor self) -> int +inline int64_t Tensor::sparse_dim() const { + return at::_ops::sparse_dim::call(const_cast(*this)); +} + +// aten::_dimI(Tensor self) -> int +inline int64_t Tensor::_dimI() const { + return at::_ops::_dimI::call(const_cast(*this)); +} + +// aten::dense_dim(Tensor self) -> int +inline int64_t Tensor::dense_dim() const { + return at::_ops::dense_dim::call(const_cast(*this)); +} + +// aten::_dimV(Tensor self) -> int +inline int64_t Tensor::_dimV() const { + return at::_ops::_dimV::call(const_cast(*this)); +} + +// aten::_nnz(Tensor self) -> int +inline int64_t Tensor::_nnz() const { + return at::_ops::_nnz::call(const_cast(*this)); +} + +// aten::coalesce(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::coalesce() const { + return at::_ops::coalesce::call(const_cast(*this)); +} + +// aten::is_coalesced(Tensor self) -> bool +inline bool Tensor::is_coalesced() const { + return at::_ops::is_coalesced::call(const_cast(*this)); +} + +// aten::_indices(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::_indices() const { + return at::_ops::_indices::call(const_cast(*this)); +} + +// aten::_values(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::_values() const { + return at::_ops::_values::call(const_cast(*this)); +} + +// aten::_coalesced_(Tensor(a!) self, bool coalesced) -> Tensor(a!) +inline at::Tensor & Tensor::_coalesced_(bool coalesced) const { + return at::_ops::_coalesced_::call(const_cast(*this), coalesced); +} + +// aten::indices(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::indices() const { + return at::_ops::indices::call(const_cast(*this)); +} + +// aten::values(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::values() const { + return at::_ops::values::call(const_cast(*this)); +} + +// aten::crow_indices(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::crow_indices() const { + return at::_ops::crow_indices::call(const_cast(*this)); +} + +// aten::col_indices(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::col_indices() const { + return at::_ops::col_indices::call(const_cast(*this)); +} + +// aten::ccol_indices(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::ccol_indices() const { + return at::_ops::ccol_indices::call(const_cast(*this)); +} + +// aten::row_indices(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::row_indices() const { + return at::_ops::row_indices::call(const_cast(*this)); +} + +// aten::unbind.int(Tensor(a -> *) self, int dim=0) -> Tensor(a)[] +inline ::std::vector Tensor::unbind(int64_t dim) const { + return at::_ops::unbind_int::call(const_cast(*this), dim); +} + +// aten::unbind.Dimname(Tensor(a -> *) self, Dimname dim) -> Tensor(a)[] +inline ::std::vector Tensor::unbind(at::Dimname dim) const { + return at::_ops::unbind_Dimname::call(const_cast(*this), dim); +} + +// aten::to_sparse.sparse_dim(Tensor self, int sparse_dim) -> Tensor +inline at::Tensor Tensor::to_sparse(int64_t sparse_dim) const { + return at::_ops::to_sparse_sparse_dim::call(const_cast(*this), sparse_dim); +} + +// aten::_to_sparse.sparse_dim(Tensor self, int sparse_dim) -> Tensor +inline at::Tensor Tensor::_to_sparse(int64_t sparse_dim) const { + return at::_ops::_to_sparse_sparse_dim::call(const_cast(*this), sparse_dim); +} + +// aten::to_sparse(Tensor self, *, Layout? layout=None, int[2]? blocksize=None, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::to_sparse(::std::optional layout, at::OptionalIntArrayRef blocksize, ::std::optional dense_dim) const { + return at::_ops::to_sparse::call(const_cast(*this), layout, blocksize, dense_dim); +} + +// aten::_to_sparse(Tensor self, *, Layout? layout=None, int[2]? blocksize=None, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::_to_sparse(::std::optional layout, at::OptionalIntArrayRef blocksize, ::std::optional dense_dim) const { + return at::_ops::_to_sparse::call(const_cast(*this), layout, blocksize, dense_dim); +} + +// aten::to_sparse_csr(Tensor self, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::to_sparse_csr(::std::optional dense_dim) const { + return at::_ops::to_sparse_csr::call(const_cast(*this), dense_dim); +} + +// aten::_to_sparse_csr(Tensor self, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::_to_sparse_csr(::std::optional dense_dim) const { + return at::_ops::_to_sparse_csr::call(const_cast(*this), dense_dim); +} + +// aten::to_sparse_csc(Tensor self, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::to_sparse_csc(::std::optional dense_dim) const { + return at::_ops::to_sparse_csc::call(const_cast(*this), dense_dim); +} + +// aten::_to_sparse_csc(Tensor self, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::_to_sparse_csc(::std::optional dense_dim) const { + return at::_ops::_to_sparse_csc::call(const_cast(*this), dense_dim); +} + +// aten::to_sparse_bsr(Tensor self, int[2] blocksize, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::to_sparse_bsr(at::IntArrayRef blocksize, ::std::optional dense_dim) const { + return at::_ops::to_sparse_bsr::call(const_cast(*this), blocksize, dense_dim); +} + +// aten::_to_sparse_bsr(Tensor self, int[2] blocksize, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::_to_sparse_bsr(at::IntArrayRef blocksize, ::std::optional dense_dim) const { + return at::_ops::_to_sparse_bsr::call(const_cast(*this), blocksize, dense_dim); +} + +// aten::to_sparse_bsc(Tensor self, int[2] blocksize, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::to_sparse_bsc(at::IntArrayRef blocksize, ::std::optional dense_dim) const { + return at::_ops::to_sparse_bsc::call(const_cast(*this), blocksize, dense_dim); +} + +// aten::_to_sparse_bsc(Tensor self, int[2] blocksize, int? dense_dim=None) -> Tensor +inline at::Tensor Tensor::_to_sparse_bsc(at::IntArrayRef blocksize, ::std::optional dense_dim) const { + return at::_ops::_to_sparse_bsc::call(const_cast(*this), blocksize, dense_dim); +} + +// aten::to_mkldnn(Tensor self, ScalarType? dtype=None) -> Tensor +inline at::Tensor Tensor::to_mkldnn(::std::optional dtype) const { + return at::_ops::to_mkldnn::call(const_cast(*this), dtype); +} + +// aten::dequantize.self(Tensor self) -> Tensor +inline at::Tensor Tensor::dequantize() const { + return at::_ops::dequantize_self::call(const_cast(*this)); +} + +// aten::q_scale(Tensor self) -> float +inline double Tensor::q_scale() const { + return at::_ops::q_scale::call(const_cast(*this)); +} + +// aten::q_zero_point(Tensor self) -> int +inline int64_t Tensor::q_zero_point() const { + return at::_ops::q_zero_point::call(const_cast(*this)); +} + +// aten::q_per_channel_scales(Tensor self) -> Tensor +inline at::Tensor Tensor::q_per_channel_scales() const { + return at::_ops::q_per_channel_scales::call(const_cast(*this)); +} + +// aten::q_per_channel_zero_points(Tensor self) -> Tensor +inline at::Tensor Tensor::q_per_channel_zero_points() const { + return at::_ops::q_per_channel_zero_points::call(const_cast(*this)); +} + +// aten::q_per_channel_axis(Tensor self) -> int +inline int64_t Tensor::q_per_channel_axis() const { + return at::_ops::q_per_channel_axis::call(const_cast(*this)); +} + +// aten::int_repr(Tensor self) -> Tensor +inline at::Tensor Tensor::int_repr() const { + return at::_ops::int_repr::call(const_cast(*this)); +} + +// aten::qscheme(Tensor self) -> QScheme +inline at::QScheme Tensor::qscheme() const { + return at::_ops::qscheme::call(const_cast(*this)); +} + +// aten::_autocast_to_reduced_precision(Tensor(a) self, bool cuda_enabled, bool cpu_enabled, ScalarType cuda_dtype, ScalarType cpu_dtype) -> Tensor(a) +inline at::Tensor Tensor::_autocast_to_reduced_precision(bool cuda_enabled, bool cpu_enabled, at::ScalarType cuda_dtype, at::ScalarType cpu_dtype) const { + return at::_ops::_autocast_to_reduced_precision::call(const_cast(*this), cuda_enabled, cpu_enabled, cuda_dtype, cpu_dtype); +} + +// aten::_autocast_to_full_precision(Tensor(a) self, bool cuda_enabled, bool cpu_enabled) -> Tensor(a) +inline at::Tensor Tensor::_autocast_to_full_precision(bool cuda_enabled, bool cpu_enabled) const { + return at::_ops::_autocast_to_full_precision::call(const_cast(*this), cuda_enabled, cpu_enabled); +} + +// aten::to.dtype_layout(Tensor(a) self, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None, bool non_blocking=False, bool copy=False, MemoryFormat? memory_format=None) -> Tensor(a) +inline at::Tensor Tensor::to(at::TensorOptions options, bool non_blocking, bool copy, ::std::optional memory_format) const { + return at::_ops::to_dtype_layout::call(const_cast(*this), c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt(), non_blocking, copy, c10::impl::check_tensor_options_and_extract_memory_format(options, memory_format)); +} + +// aten::to.dtype_layout(Tensor(a) self, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None, bool non_blocking=False, bool copy=False, MemoryFormat? memory_format=None) -> Tensor(a) +inline at::Tensor Tensor::to(::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory, bool non_blocking, bool copy, ::std::optional memory_format) const { + return at::_ops::to_dtype_layout::call(const_cast(*this), dtype, layout, device, pin_memory, non_blocking, copy, memory_format); +} + +// aten::to.device(Tensor(a) self, Device device, ScalarType dtype, bool non_blocking=False, bool copy=False, MemoryFormat? memory_format=None) -> Tensor(a) +inline at::Tensor Tensor::to(at::Device device, at::ScalarType dtype, bool non_blocking, bool copy, ::std::optional memory_format) const { + return at::_ops::to_device::call(const_cast(*this), device, dtype, non_blocking, copy, memory_format); +} + +// aten::to.dtype(Tensor(a) self, ScalarType dtype, bool non_blocking=False, bool copy=False, MemoryFormat? memory_format=None) -> Tensor(a) +inline at::Tensor Tensor::to(at::ScalarType dtype, bool non_blocking, bool copy, ::std::optional memory_format) const { + return at::_ops::to_dtype::call(const_cast(*this), dtype, non_blocking, copy, memory_format); +} + +// aten::to.other(Tensor(a) self, Tensor other, bool non_blocking=False, bool copy=False, MemoryFormat? memory_format=None) -> Tensor(a) +inline at::Tensor Tensor::to(const at::Tensor & other, bool non_blocking, bool copy, ::std::optional memory_format) const { + return at::_ops::to_other::call(const_cast(*this), other, non_blocking, copy, memory_format); +} + +// aten::item(Tensor self) -> Scalar +inline at::Scalar Tensor::item() const { + return at::_ops::item::call(const_cast(*this)); +} + +// aten::set_.source_Storage(Tensor(a!) self, Storage source) -> Tensor(a!) +inline at::Tensor & Tensor::set_(at::Storage source) const { + return at::_ops::set__source_Storage::call(const_cast(*this), source); +} + +// aten::set_.source_Storage_storage_offset(Tensor(a!) self, Storage source, SymInt storage_offset, SymInt[] size, SymInt[] stride=[]) -> Tensor(a!) +inline at::Tensor & Tensor::set_(at::Storage source, int64_t storage_offset, at::IntArrayRef size, at::IntArrayRef stride) const { + return at::_ops::set__source_Storage_storage_offset::call(const_cast(*this), source, storage_offset, c10::fromIntArrayRefSlow(size), c10::fromIntArrayRefSlow(stride)); +} + +// aten::set_.source_Storage_storage_offset(Tensor(a!) self, Storage source, SymInt storage_offset, SymInt[] size, SymInt[] stride=[]) -> Tensor(a!) +inline at::Tensor & Tensor::set__symint(at::Storage source, c10::SymInt storage_offset, c10::SymIntArrayRef size, c10::SymIntArrayRef stride) const { + return at::_ops::set__source_Storage_storage_offset::call(const_cast(*this), source, storage_offset, size, stride); +} + +// aten::set_.source_Tensor_storage_offset(Tensor(a!) self, Tensor source, SymInt storage_offset, SymInt[] size, SymInt[] stride=[]) -> Tensor(a!) +inline at::Tensor & Tensor::set_(const at::Tensor & source, int64_t storage_offset, at::IntArrayRef size, at::IntArrayRef stride) const { + return at::_ops::set__source_Tensor_storage_offset::call(const_cast(*this), source, storage_offset, c10::fromIntArrayRefSlow(size), c10::fromIntArrayRefSlow(stride)); +} + +// aten::set_.source_Tensor_storage_offset(Tensor(a!) self, Tensor source, SymInt storage_offset, SymInt[] size, SymInt[] stride=[]) -> Tensor(a!) +inline at::Tensor & Tensor::set__symint(const at::Tensor & source, c10::SymInt storage_offset, c10::SymIntArrayRef size, c10::SymIntArrayRef stride) const { + return at::_ops::set__source_Tensor_storage_offset::call(const_cast(*this), source, storage_offset, size, stride); +} + +// aten::set_.source_Tensor(Tensor(a!) self, Tensor source) -> Tensor(a!) +inline at::Tensor & Tensor::set_(const at::Tensor & source) const { + return at::_ops::set__source_Tensor::call(const_cast(*this), source); +} + +// aten::set_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::set_() const { + return at::_ops::set_::call(const_cast(*this)); +} + +// aten::is_set_to(Tensor self, Tensor tensor) -> bool +inline bool Tensor::is_set_to(const at::Tensor & tensor) const { + return at::_ops::is_set_to::call(const_cast(*this), tensor); +} + +// aten::masked_fill_.Scalar(Tensor(a!) self, Tensor mask, Scalar value) -> Tensor(a!) +inline at::Tensor & Tensor::masked_fill_(const at::Tensor & mask, const at::Scalar & value) const { + return at::_ops::masked_fill__Scalar::call(const_cast(*this), mask, value); +} + +// aten::masked_fill.Scalar(Tensor self, Tensor mask, Scalar value) -> Tensor +inline at::Tensor Tensor::masked_fill(const at::Tensor & mask, const at::Scalar & value) const { + return at::_ops::masked_fill_Scalar::call(const_cast(*this), mask, value); +} + +// aten::masked_fill_.Tensor(Tensor(a!) self, Tensor mask, Tensor value) -> Tensor(a!) +inline at::Tensor & Tensor::masked_fill_(const at::Tensor & mask, const at::Tensor & value) const { + return at::_ops::masked_fill__Tensor::call(const_cast(*this), mask, value); +} + +// aten::masked_fill.Tensor(Tensor self, Tensor mask, Tensor value) -> Tensor +inline at::Tensor Tensor::masked_fill(const at::Tensor & mask, const at::Tensor & value) const { + return at::_ops::masked_fill_Tensor::call(const_cast(*this), mask, value); +} + +// aten::masked_scatter_(Tensor(a!) self, Tensor mask, Tensor source) -> Tensor(a!) +inline at::Tensor & Tensor::masked_scatter_(const at::Tensor & mask, const at::Tensor & source) const { + return at::_ops::masked_scatter_::call(const_cast(*this), mask, source); +} + +// aten::masked_scatter(Tensor self, Tensor mask, Tensor source) -> Tensor +inline at::Tensor Tensor::masked_scatter(const at::Tensor & mask, const at::Tensor & source) const { + return at::_ops::masked_scatter::call(const_cast(*this), mask, source); +} + +// aten::view(Tensor(a) self, SymInt[] size) -> Tensor(a) +inline at::Tensor Tensor::view(at::IntArrayRef size) const { + return at::_ops::view::call(const_cast(*this), c10::fromIntArrayRefSlow(size)); +} + +// aten::view(Tensor(a) self, SymInt[] size) -> Tensor(a) +inline at::Tensor Tensor::view_symint(c10::SymIntArrayRef size) const { + return at::_ops::view::call(const_cast(*this), size); +} + +// aten::view.dtype(Tensor(a) self, ScalarType dtype) -> Tensor(a) +inline at::Tensor Tensor::view(at::ScalarType dtype) const { + return at::_ops::view_dtype::call(const_cast(*this), dtype); +} + +// aten::put_(Tensor(a!) self, Tensor index, Tensor source, bool accumulate=False) -> Tensor(a!) +inline at::Tensor & Tensor::put_(const at::Tensor & index, const at::Tensor & source, bool accumulate) const { + return at::_ops::put_::call(const_cast(*this), index, source, accumulate); +} + +// aten::put(Tensor self, Tensor index, Tensor source, bool accumulate=False) -> Tensor +inline at::Tensor Tensor::put(const at::Tensor & index, const at::Tensor & source, bool accumulate) const { + return at::_ops::put::call(const_cast(*this), index, source, accumulate); +} + +// aten::index_add_(Tensor(a!) self, int dim, Tensor index, Tensor source, *, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::index_add_(int64_t dim, const at::Tensor & index, const at::Tensor & source, const at::Scalar & alpha) const { + return at::_ops::index_add_::call(const_cast(*this), dim, index, source, alpha); +} + +// aten::index_add(Tensor self, int dim, Tensor index, Tensor source, *, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::index_add(int64_t dim, const at::Tensor & index, const at::Tensor & source, const at::Scalar & alpha) const { + return at::_ops::index_add::call(const_cast(*this), dim, index, source, alpha); +} + +// aten::index_add.dimname(Tensor self, Dimname dim, Tensor index, Tensor source, *, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::index_add(at::Dimname dim, const at::Tensor & index, const at::Tensor & source, const at::Scalar & alpha) const { + return at::_ops::index_add_dimname::call(const_cast(*this), dim, index, source, alpha); +} + +// aten::index_reduce_(Tensor(a!) self, int dim, Tensor index, Tensor source, str reduce, *, bool include_self=True) -> Tensor(a!) +inline at::Tensor & Tensor::index_reduce_(int64_t dim, const at::Tensor & index, const at::Tensor & source, c10::string_view reduce, bool include_self) const { + return at::_ops::index_reduce_::call(const_cast(*this), dim, index, source, reduce, include_self); +} + +// aten::index_reduce(Tensor self, int dim, Tensor index, Tensor source, str reduce, *, bool include_self=True) -> Tensor +inline at::Tensor Tensor::index_reduce(int64_t dim, const at::Tensor & index, const at::Tensor & source, c10::string_view reduce, bool include_self) const { + return at::_ops::index_reduce::call(const_cast(*this), dim, index, source, reduce, include_self); +} + +// aten::index_fill_.int_Scalar(Tensor(a!) self, int dim, Tensor index, Scalar value) -> Tensor(a!) +inline at::Tensor & Tensor::index_fill_(int64_t dim, const at::Tensor & index, const at::Scalar & value) const { + return at::_ops::index_fill__int_Scalar::call(const_cast(*this), dim, index, value); +} + +// aten::index_fill.int_Scalar(Tensor self, int dim, Tensor index, Scalar value) -> Tensor +inline at::Tensor Tensor::index_fill(int64_t dim, const at::Tensor & index, const at::Scalar & value) const { + return at::_ops::index_fill_int_Scalar::call(const_cast(*this), dim, index, value); +} + +// aten::index_fill_.int_Tensor(Tensor(a!) self, int dim, Tensor index, Tensor value) -> Tensor(a!) +inline at::Tensor & Tensor::index_fill_(int64_t dim, const at::Tensor & index, const at::Tensor & value) const { + return at::_ops::index_fill__int_Tensor::call(const_cast(*this), dim, index, value); +} + +// aten::index_fill.int_Tensor(Tensor self, int dim, Tensor index, Tensor value) -> Tensor +inline at::Tensor Tensor::index_fill(int64_t dim, const at::Tensor & index, const at::Tensor & value) const { + return at::_ops::index_fill_int_Tensor::call(const_cast(*this), dim, index, value); +} + +// aten::index_fill_.Dimname_Scalar(Tensor(a!) self, Dimname dim, Tensor index, Scalar value) -> Tensor(a!) +inline at::Tensor & Tensor::index_fill_(at::Dimname dim, const at::Tensor & index, const at::Scalar & value) const { + return at::_ops::index_fill__Dimname_Scalar::call(const_cast(*this), dim, index, value); +} + +// aten::index_fill_.Dimname_Tensor(Tensor(a!) self, Dimname dim, Tensor index, Tensor value) -> Tensor(a!) +inline at::Tensor & Tensor::index_fill_(at::Dimname dim, const at::Tensor & index, const at::Tensor & value) const { + return at::_ops::index_fill__Dimname_Tensor::call(const_cast(*this), dim, index, value); +} + +// aten::index_fill.Dimname_Scalar(Tensor self, Dimname dim, Tensor index, Scalar value) -> Tensor +inline at::Tensor Tensor::index_fill(at::Dimname dim, const at::Tensor & index, const at::Scalar & value) const { + return at::_ops::index_fill_Dimname_Scalar::call(const_cast(*this), dim, index, value); +} + +// aten::index_fill.Dimname_Tensor(Tensor self, Dimname dim, Tensor index, Tensor value) -> Tensor +inline at::Tensor Tensor::index_fill(at::Dimname dim, const at::Tensor & index, const at::Tensor & value) const { + return at::_ops::index_fill_Dimname_Tensor::call(const_cast(*this), dim, index, value); +} + +// aten::scatter.src(Tensor self, int dim, Tensor index, Tensor src) -> Tensor +inline at::Tensor Tensor::scatter(int64_t dim, const at::Tensor & index, const at::Tensor & src) const { + return at::_ops::scatter_src::call(const_cast(*this), dim, index, src); +} + +// aten::scatter_.src(Tensor(a!) self, int dim, Tensor index, Tensor src) -> Tensor(a!) +inline at::Tensor & Tensor::scatter_(int64_t dim, const at::Tensor & index, const at::Tensor & src) const { + return at::_ops::scatter__src::call(const_cast(*this), dim, index, src); +} + +// aten::scatter.value(Tensor self, int dim, Tensor index, Scalar value) -> Tensor +inline at::Tensor Tensor::scatter(int64_t dim, const at::Tensor & index, const at::Scalar & value) const { + return at::_ops::scatter_value::call(const_cast(*this), dim, index, value); +} + +// aten::scatter_.value(Tensor(a!) self, int dim, Tensor index, Scalar value) -> Tensor(a!) +inline at::Tensor & Tensor::scatter_(int64_t dim, const at::Tensor & index, const at::Scalar & value) const { + return at::_ops::scatter__value::call(const_cast(*this), dim, index, value); +} + +// aten::scatter.reduce(Tensor self, int dim, Tensor index, Tensor src, *, str reduce) -> Tensor +inline at::Tensor Tensor::scatter(int64_t dim, const at::Tensor & index, const at::Tensor & src, c10::string_view reduce) const { + return at::_ops::scatter_reduce::call(const_cast(*this), dim, index, src, reduce); +} + +// aten::scatter_.reduce(Tensor(a!) self, int dim, Tensor index, Tensor src, *, str reduce) -> Tensor(a!) +inline at::Tensor & Tensor::scatter_(int64_t dim, const at::Tensor & index, const at::Tensor & src, c10::string_view reduce) const { + return at::_ops::scatter__reduce::call(const_cast(*this), dim, index, src, reduce); +} + +// aten::scatter.value_reduce(Tensor self, int dim, Tensor index, Scalar value, *, str reduce) -> Tensor +inline at::Tensor Tensor::scatter(int64_t dim, const at::Tensor & index, const at::Scalar & value, c10::string_view reduce) const { + return at::_ops::scatter_value_reduce::call(const_cast(*this), dim, index, value, reduce); +} + +// aten::scatter_.value_reduce(Tensor(a!) self, int dim, Tensor index, Scalar value, *, str reduce) -> Tensor(a!) +inline at::Tensor & Tensor::scatter_(int64_t dim, const at::Tensor & index, const at::Scalar & value, c10::string_view reduce) const { + return at::_ops::scatter__value_reduce::call(const_cast(*this), dim, index, value, reduce); +} + +// aten::scatter.dimname_src(Tensor self, Dimname dim, Tensor index, Tensor src) -> Tensor +inline at::Tensor Tensor::scatter(at::Dimname dim, const at::Tensor & index, const at::Tensor & src) const { + return at::_ops::scatter_dimname_src::call(const_cast(*this), dim, index, src); +} + +// aten::scatter.dimname_value(Tensor self, Dimname dim, Tensor index, Scalar value) -> Tensor +inline at::Tensor Tensor::scatter(at::Dimname dim, const at::Tensor & index, const at::Scalar & value) const { + return at::_ops::scatter_dimname_value::call(const_cast(*this), dim, index, value); +} + +// aten::scatter_add(Tensor self, int dim, Tensor index, Tensor src) -> Tensor +inline at::Tensor Tensor::scatter_add(int64_t dim, const at::Tensor & index, const at::Tensor & src) const { + return at::_ops::scatter_add::call(const_cast(*this), dim, index, src); +} + +// aten::scatter_add_(Tensor(a!) self, int dim, Tensor index, Tensor src) -> Tensor(a!) +inline at::Tensor & Tensor::scatter_add_(int64_t dim, const at::Tensor & index, const at::Tensor & src) const { + return at::_ops::scatter_add_::call(const_cast(*this), dim, index, src); +} + +// aten::scatter_add.dimname(Tensor self, Dimname dim, Tensor index, Tensor src) -> Tensor +inline at::Tensor Tensor::scatter_add(at::Dimname dim, const at::Tensor & index, const at::Tensor & src) const { + return at::_ops::scatter_add_dimname::call(const_cast(*this), dim, index, src); +} + +// aten::scatter_reduce.two(Tensor self, int dim, Tensor index, Tensor src, str reduce, *, bool include_self=True) -> Tensor +inline at::Tensor Tensor::scatter_reduce(int64_t dim, const at::Tensor & index, const at::Tensor & src, c10::string_view reduce, bool include_self) const { + return at::_ops::scatter_reduce_two::call(const_cast(*this), dim, index, src, reduce, include_self); +} + +// aten::scatter_reduce_.two(Tensor(a!) self, int dim, Tensor index, Tensor src, str reduce, *, bool include_self=True) -> Tensor(a!) +inline at::Tensor & Tensor::scatter_reduce_(int64_t dim, const at::Tensor & index, const at::Tensor & src, c10::string_view reduce, bool include_self) const { + return at::_ops::scatter_reduce__two::call(const_cast(*this), dim, index, src, reduce, include_self); +} + +// aten::eq_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::eq_(const at::Scalar & other) const { + return at::_ops::eq__Scalar::call(const_cast(*this), other); +} + +// aten::eq_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::eq_(const at::Tensor & other) const { + return at::_ops::eq__Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_and.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::bitwise_and(const at::Scalar & other) const { + return at::_ops::bitwise_and_Scalar::call(const_cast(*this), other); +} + +// aten::bitwise_and.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::bitwise_and(const at::Tensor & other) const { + return at::_ops::bitwise_and_Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_and_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_and_(const at::Scalar & other) const { + return at::_ops::bitwise_and__Scalar::call(const_cast(*this), other); +} + +// aten::bitwise_and_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_and_(const at::Tensor & other) const { + return at::_ops::bitwise_and__Tensor::call(const_cast(*this), other); +} + +// aten::__and__.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::__and__(const at::Scalar & other) const { + return at::_ops::__and___Scalar::call(const_cast(*this), other); +} + +// aten::__and__.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::__and__(const at::Tensor & other) const { + return at::_ops::__and___Tensor::call(const_cast(*this), other); +} + +// aten::__iand__.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::__iand__(const at::Scalar & other) const { + return at::_ops::__iand___Scalar::call(const_cast(*this), other); +} + +// aten::__iand__.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::__iand__(const at::Tensor & other) const { + return at::_ops::__iand___Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_or.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::bitwise_or(const at::Scalar & other) const { + return at::_ops::bitwise_or_Scalar::call(const_cast(*this), other); +} + +// aten::bitwise_or.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::bitwise_or(const at::Tensor & other) const { + return at::_ops::bitwise_or_Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_or_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_or_(const at::Scalar & other) const { + return at::_ops::bitwise_or__Scalar::call(const_cast(*this), other); +} + +// aten::bitwise_or_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_or_(const at::Tensor & other) const { + return at::_ops::bitwise_or__Tensor::call(const_cast(*this), other); +} + +// aten::__or__.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::__or__(const at::Scalar & other) const { + return at::_ops::__or___Scalar::call(const_cast(*this), other); +} + +// aten::__or__.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::__or__(const at::Tensor & other) const { + return at::_ops::__or___Tensor::call(const_cast(*this), other); +} + +// aten::__ior__.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::__ior__(const at::Scalar & other) const { + return at::_ops::__ior___Scalar::call(const_cast(*this), other); +} + +// aten::__ior__.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::__ior__(const at::Tensor & other) const { + return at::_ops::__ior___Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_xor.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::bitwise_xor(const at::Scalar & other) const { + return at::_ops::bitwise_xor_Scalar::call(const_cast(*this), other); +} + +// aten::bitwise_xor.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::bitwise_xor(const at::Tensor & other) const { + return at::_ops::bitwise_xor_Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_xor_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_xor_(const at::Scalar & other) const { + return at::_ops::bitwise_xor__Scalar::call(const_cast(*this), other); +} + +// aten::bitwise_xor_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_xor_(const at::Tensor & other) const { + return at::_ops::bitwise_xor__Tensor::call(const_cast(*this), other); +} + +// aten::__xor__.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::__xor__(const at::Scalar & other) const { + return at::_ops::__xor___Scalar::call(const_cast(*this), other); +} + +// aten::__xor__.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::__xor__(const at::Tensor & other) const { + return at::_ops::__xor___Tensor::call(const_cast(*this), other); +} + +// aten::__ixor__.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::__ixor__(const at::Scalar & other) const { + return at::_ops::__ixor___Scalar::call(const_cast(*this), other); +} + +// aten::__ixor__.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::__ixor__(const at::Tensor & other) const { + return at::_ops::__ixor___Tensor::call(const_cast(*this), other); +} + +// aten::__lshift__.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::__lshift__(const at::Scalar & other) const { + return at::_ops::__lshift___Scalar::call(const_cast(*this), other); +} + +// aten::__lshift__.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::__lshift__(const at::Tensor & other) const { + return at::_ops::__lshift___Tensor::call(const_cast(*this), other); +} + +// aten::__ilshift__.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::__ilshift__(const at::Scalar & other) const { + return at::_ops::__ilshift___Scalar::call(const_cast(*this), other); +} + +// aten::__ilshift__.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::__ilshift__(const at::Tensor & other) const { + return at::_ops::__ilshift___Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_left_shift.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::bitwise_left_shift(const at::Tensor & other) const { + return at::_ops::bitwise_left_shift_Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_left_shift_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_left_shift_(const at::Tensor & other) const { + return at::_ops::bitwise_left_shift__Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_left_shift.Tensor_Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::bitwise_left_shift(const at::Scalar & other) const { + return at::_ops::bitwise_left_shift_Tensor_Scalar::call(const_cast(*this), other); +} + +// aten::bitwise_left_shift_.Tensor_Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_left_shift_(const at::Scalar & other) const { + return at::_ops::bitwise_left_shift__Tensor_Scalar::call(const_cast(*this), other); +} + +// aten::__rshift__.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::__rshift__(const at::Scalar & other) const { + return at::_ops::__rshift___Scalar::call(const_cast(*this), other); +} + +// aten::__rshift__.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::__rshift__(const at::Tensor & other) const { + return at::_ops::__rshift___Tensor::call(const_cast(*this), other); +} + +// aten::__irshift__.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::__irshift__(const at::Scalar & other) const { + return at::_ops::__irshift___Scalar::call(const_cast(*this), other); +} + +// aten::__irshift__.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::__irshift__(const at::Tensor & other) const { + return at::_ops::__irshift___Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_right_shift.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::bitwise_right_shift(const at::Tensor & other) const { + return at::_ops::bitwise_right_shift_Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_right_shift_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_right_shift_(const at::Tensor & other) const { + return at::_ops::bitwise_right_shift__Tensor::call(const_cast(*this), other); +} + +// aten::bitwise_right_shift.Tensor_Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::bitwise_right_shift(const at::Scalar & other) const { + return at::_ops::bitwise_right_shift_Tensor_Scalar::call(const_cast(*this), other); +} + +// aten::bitwise_right_shift_.Tensor_Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::bitwise_right_shift_(const at::Scalar & other) const { + return at::_ops::bitwise_right_shift__Tensor_Scalar::call(const_cast(*this), other); +} + +// aten::tril_(Tensor(a!) self, int diagonal=0) -> Tensor(a!) +inline at::Tensor & Tensor::tril_(int64_t diagonal) const { + return at::_ops::tril_::call(const_cast(*this), diagonal); +} + +// aten::triu_(Tensor(a!) self, int diagonal=0) -> Tensor(a!) +inline at::Tensor & Tensor::triu_(int64_t diagonal) const { + return at::_ops::triu_::call(const_cast(*this), diagonal); +} + +// aten::digamma_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::digamma_() const { + return at::_ops::digamma_::call(const_cast(*this)); +} + +// aten::lerp_.Scalar(Tensor(a!) self, Tensor end, Scalar weight) -> Tensor(a!) +inline at::Tensor & Tensor::lerp_(const at::Tensor & end, const at::Scalar & weight) const { + return at::_ops::lerp__Scalar::call(const_cast(*this), end, weight); +} + +// aten::lerp_.Tensor(Tensor(a!) self, Tensor end, Tensor weight) -> Tensor(a!) +inline at::Tensor & Tensor::lerp_(const at::Tensor & end, const at::Tensor & weight) const { + return at::_ops::lerp__Tensor::call(const_cast(*this), end, weight); +} + +// aten::addbmm_(Tensor(a!) self, Tensor batch1, Tensor batch2, *, Scalar beta=1, Scalar alpha=1) -> Tensor(a!) +inline at::Tensor & Tensor::addbmm_(const at::Tensor & batch1, const at::Tensor & batch2, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::addbmm_::call(const_cast(*this), batch1, batch2, beta, alpha); +} + +// aten::addbmm(Tensor self, Tensor batch1, Tensor batch2, *, Scalar beta=1, Scalar alpha=1) -> Tensor +inline at::Tensor Tensor::addbmm(const at::Tensor & batch1, const at::Tensor & batch2, const at::Scalar & beta, const at::Scalar & alpha) const { + return at::_ops::addbmm::call(const_cast(*this), batch1, batch2, beta, alpha); +} + +// aten::random_.from(Tensor(a!) self, int from, int? to, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::random_(int64_t from, ::std::optional to, ::std::optional generator) const { + return at::_ops::random__from::call(const_cast(*this), from, to, generator); +} + +// aten::random_.to(Tensor(a!) self, int to, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::random_(int64_t to, ::std::optional generator) const { + return at::_ops::random__to::call(const_cast(*this), to, generator); +} + +// aten::random_(Tensor(a!) self, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::random_(::std::optional generator) const { + return at::_ops::random_::call(const_cast(*this), generator); +} + +// aten::uniform_(Tensor(a!) self, float from=0, float to=1, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::uniform_(double from, double to, ::std::optional generator) const { + return at::_ops::uniform_::call(const_cast(*this), from, to, generator); +} + +// aten::cauchy_(Tensor(a!) self, float median=0, float sigma=1, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::cauchy_(double median, double sigma, ::std::optional generator) const { + return at::_ops::cauchy_::call(const_cast(*this), median, sigma, generator); +} + +// aten::log_normal_(Tensor(a!) self, float mean=1, float std=2, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::log_normal_(double mean, double std, ::std::optional generator) const { + return at::_ops::log_normal_::call(const_cast(*this), mean, std, generator); +} + +// aten::exponential_(Tensor(a!) self, float lambd=1, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::exponential_(double lambd, ::std::optional generator) const { + return at::_ops::exponential_::call(const_cast(*this), lambd, generator); +} + +// aten::geometric_(Tensor(a!) self, float p, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::geometric_(double p, ::std::optional generator) const { + return at::_ops::geometric_::call(const_cast(*this), p, generator); +} + +// aten::diag(Tensor self, int diagonal=0) -> Tensor +inline at::Tensor Tensor::diag(int64_t diagonal) const { + return at::_ops::diag::call(const_cast(*this), diagonal); +} + +// aten::cross(Tensor self, Tensor other, int? dim=None) -> Tensor +inline at::Tensor Tensor::cross(const at::Tensor & other, ::std::optional dim) const { + return at::_ops::cross::call(const_cast(*this), other, dim); +} + +// aten::triu(Tensor self, int diagonal=0) -> Tensor +inline at::Tensor Tensor::triu(int64_t diagonal) const { + return at::_ops::triu::call(const_cast(*this), diagonal); +} + +// aten::tril(Tensor self, int diagonal=0) -> Tensor +inline at::Tensor Tensor::tril(int64_t diagonal) const { + return at::_ops::tril::call(const_cast(*this), diagonal); +} + +// aten::trace(Tensor self) -> Tensor +inline at::Tensor Tensor::trace() const { + return at::_ops::trace::call(const_cast(*this)); +} + +// aten::ne.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::ne(const at::Scalar & other) const { + return at::_ops::ne_Scalar::call(const_cast(*this), other); +} + +// aten::ne.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::ne(const at::Tensor & other) const { + return at::_ops::ne_Tensor::call(const_cast(*this), other); +} + +// aten::ne_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::ne_(const at::Scalar & other) const { + return at::_ops::ne__Scalar::call(const_cast(*this), other); +} + +// aten::ne_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::ne_(const at::Tensor & other) const { + return at::_ops::ne__Tensor::call(const_cast(*this), other); +} + +// aten::not_equal.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::not_equal(const at::Scalar & other) const { + return at::_ops::not_equal_Scalar::call(const_cast(*this), other); +} + +// aten::not_equal.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::not_equal(const at::Tensor & other) const { + return at::_ops::not_equal_Tensor::call(const_cast(*this), other); +} + +// aten::not_equal_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::not_equal_(const at::Scalar & other) const { + return at::_ops::not_equal__Scalar::call(const_cast(*this), other); +} + +// aten::not_equal_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::not_equal_(const at::Tensor & other) const { + return at::_ops::not_equal__Tensor::call(const_cast(*this), other); +} + +// aten::eq.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::eq(const at::Scalar & other) const { + return at::_ops::eq_Scalar::call(const_cast(*this), other); +} + +// aten::eq.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::eq(const at::Tensor & other) const { + return at::_ops::eq_Tensor::call(const_cast(*this), other); +} + +// aten::ge.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::ge(const at::Scalar & other) const { + return at::_ops::ge_Scalar::call(const_cast(*this), other); +} + +// aten::ge.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::ge(const at::Tensor & other) const { + return at::_ops::ge_Tensor::call(const_cast(*this), other); +} + +// aten::ge_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::ge_(const at::Scalar & other) const { + return at::_ops::ge__Scalar::call(const_cast(*this), other); +} + +// aten::ge_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::ge_(const at::Tensor & other) const { + return at::_ops::ge__Tensor::call(const_cast(*this), other); +} + +// aten::greater_equal.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::greater_equal(const at::Scalar & other) const { + return at::_ops::greater_equal_Scalar::call(const_cast(*this), other); +} + +// aten::greater_equal.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::greater_equal(const at::Tensor & other) const { + return at::_ops::greater_equal_Tensor::call(const_cast(*this), other); +} + +// aten::greater_equal_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::greater_equal_(const at::Scalar & other) const { + return at::_ops::greater_equal__Scalar::call(const_cast(*this), other); +} + +// aten::greater_equal_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::greater_equal_(const at::Tensor & other) const { + return at::_ops::greater_equal__Tensor::call(const_cast(*this), other); +} + +// aten::le.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::le(const at::Scalar & other) const { + return at::_ops::le_Scalar::call(const_cast(*this), other); +} + +// aten::le.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::le(const at::Tensor & other) const { + return at::_ops::le_Tensor::call(const_cast(*this), other); +} + +// aten::le_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::le_(const at::Scalar & other) const { + return at::_ops::le__Scalar::call(const_cast(*this), other); +} + +// aten::le_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::le_(const at::Tensor & other) const { + return at::_ops::le__Tensor::call(const_cast(*this), other); +} + +// aten::less_equal.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::less_equal(const at::Scalar & other) const { + return at::_ops::less_equal_Scalar::call(const_cast(*this), other); +} + +// aten::less_equal.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::less_equal(const at::Tensor & other) const { + return at::_ops::less_equal_Tensor::call(const_cast(*this), other); +} + +// aten::less_equal_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::less_equal_(const at::Scalar & other) const { + return at::_ops::less_equal__Scalar::call(const_cast(*this), other); +} + +// aten::less_equal_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::less_equal_(const at::Tensor & other) const { + return at::_ops::less_equal__Tensor::call(const_cast(*this), other); +} + +// aten::gt.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::gt(const at::Scalar & other) const { + return at::_ops::gt_Scalar::call(const_cast(*this), other); +} + +// aten::gt.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::gt(const at::Tensor & other) const { + return at::_ops::gt_Tensor::call(const_cast(*this), other); +} + +// aten::gt_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::gt_(const at::Scalar & other) const { + return at::_ops::gt__Scalar::call(const_cast(*this), other); +} + +// aten::gt_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::gt_(const at::Tensor & other) const { + return at::_ops::gt__Tensor::call(const_cast(*this), other); +} + +// aten::greater.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::greater(const at::Scalar & other) const { + return at::_ops::greater_Scalar::call(const_cast(*this), other); +} + +// aten::greater.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::greater(const at::Tensor & other) const { + return at::_ops::greater_Tensor::call(const_cast(*this), other); +} + +// aten::greater_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::greater_(const at::Scalar & other) const { + return at::_ops::greater__Scalar::call(const_cast(*this), other); +} + +// aten::greater_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::greater_(const at::Tensor & other) const { + return at::_ops::greater__Tensor::call(const_cast(*this), other); +} + +// aten::lt.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::lt(const at::Scalar & other) const { + return at::_ops::lt_Scalar::call(const_cast(*this), other); +} + +// aten::lt.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::lt(const at::Tensor & other) const { + return at::_ops::lt_Tensor::call(const_cast(*this), other); +} + +// aten::lt_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::lt_(const at::Scalar & other) const { + return at::_ops::lt__Scalar::call(const_cast(*this), other); +} + +// aten::lt_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::lt_(const at::Tensor & other) const { + return at::_ops::lt__Tensor::call(const_cast(*this), other); +} + +// aten::less.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::less(const at::Scalar & other) const { + return at::_ops::less_Scalar::call(const_cast(*this), other); +} + +// aten::less.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::less(const at::Tensor & other) const { + return at::_ops::less_Tensor::call(const_cast(*this), other); +} + +// aten::less_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::less_(const at::Scalar & other) const { + return at::_ops::less__Scalar::call(const_cast(*this), other); +} + +// aten::less_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::less_(const at::Tensor & other) const { + return at::_ops::less__Tensor::call(const_cast(*this), other); +} + +// aten::take(Tensor self, Tensor index) -> Tensor +inline at::Tensor Tensor::take(const at::Tensor & index) const { + return at::_ops::take::call(const_cast(*this), index); +} + +// aten::take_along_dim(Tensor self, Tensor indices, int? dim=None) -> Tensor +inline at::Tensor Tensor::take_along_dim(const at::Tensor & indices, ::std::optional dim) const { + return at::_ops::take_along_dim::call(const_cast(*this), indices, dim); +} + +// aten::index_select(Tensor self, int dim, Tensor index) -> Tensor +inline at::Tensor Tensor::index_select(int64_t dim, const at::Tensor & index) const { + return at::_ops::index_select::call(const_cast(*this), dim, index); +} + +// aten::index_select.dimname(Tensor self, Dimname dim, Tensor index) -> Tensor +inline at::Tensor Tensor::index_select(at::Dimname dim, const at::Tensor & index) const { + return at::_ops::index_select_dimname::call(const_cast(*this), dim, index); +} + +// aten::masked_select(Tensor self, Tensor mask) -> Tensor +inline at::Tensor Tensor::masked_select(const at::Tensor & mask) const { + return at::_ops::masked_select::call(const_cast(*this), mask); +} + +// aten::nonzero(Tensor self) -> Tensor +inline at::Tensor Tensor::nonzero() const { + return at::_ops::nonzero::call(const_cast(*this)); +} + +// aten::nonzero_static(Tensor self, *, SymInt size, int fill_value=-1) -> Tensor +inline at::Tensor Tensor::nonzero_static(int64_t size, int64_t fill_value) const { + return at::_ops::nonzero_static::call(const_cast(*this), size, fill_value); +} + +// aten::nonzero_static(Tensor self, *, SymInt size, int fill_value=-1) -> Tensor +inline at::Tensor Tensor::nonzero_static_symint(c10::SymInt size, int64_t fill_value) const { + return at::_ops::nonzero_static::call(const_cast(*this), size, fill_value); +} + +// aten::nonzero_numpy(Tensor self) -> Tensor[] +inline ::std::vector Tensor::nonzero_numpy() const { + return at::_ops::nonzero_numpy::call(const_cast(*this)); +} + +// aten::argwhere(Tensor self) -> Tensor +inline at::Tensor Tensor::argwhere() const { + return at::_ops::argwhere::call(const_cast(*this)); +} + +// aten::gather(Tensor self, int dim, Tensor index, *, bool sparse_grad=False) -> Tensor +inline at::Tensor Tensor::gather(int64_t dim, const at::Tensor & index, bool sparse_grad) const { + return at::_ops::gather::call(const_cast(*this), dim, index, sparse_grad); +} + +// aten::gather.dimname(Tensor self, Dimname dim, Tensor index, *, bool sparse_grad=False) -> Tensor +inline at::Tensor Tensor::gather(at::Dimname dim, const at::Tensor & index, bool sparse_grad) const { + return at::_ops::gather_dimname::call(const_cast(*this), dim, index, sparse_grad); +} + +// aten::addcmul(Tensor self, Tensor tensor1, Tensor tensor2, *, Scalar value=1) -> Tensor +inline at::Tensor Tensor::addcmul(const at::Tensor & tensor1, const at::Tensor & tensor2, const at::Scalar & value) const { + return at::_ops::addcmul::call(const_cast(*this), tensor1, tensor2, value); +} + +// aten::addcmul_(Tensor(a!) self, Tensor tensor1, Tensor tensor2, *, Scalar value=1) -> Tensor(a!) +inline at::Tensor & Tensor::addcmul_(const at::Tensor & tensor1, const at::Tensor & tensor2, const at::Scalar & value) const { + return at::_ops::addcmul_::call(const_cast(*this), tensor1, tensor2, value); +} + +// aten::addcdiv(Tensor self, Tensor tensor1, Tensor tensor2, *, Scalar value=1) -> Tensor +inline at::Tensor Tensor::addcdiv(const at::Tensor & tensor1, const at::Tensor & tensor2, const at::Scalar & value) const { + return at::_ops::addcdiv::call(const_cast(*this), tensor1, tensor2, value); +} + +// aten::addcdiv_(Tensor(a!) self, Tensor tensor1, Tensor tensor2, *, Scalar value=1) -> Tensor(a!) +inline at::Tensor & Tensor::addcdiv_(const at::Tensor & tensor1, const at::Tensor & tensor2, const at::Scalar & value) const { + return at::_ops::addcdiv_::call(const_cast(*this), tensor1, tensor2, value); +} + +// aten::triangular_solve(Tensor self, Tensor A, bool upper=True, bool transpose=False, bool unitriangular=False) -> (Tensor solution, Tensor cloned_coefficient) +inline ::std::tuple Tensor::triangular_solve(const at::Tensor & A, bool upper, bool transpose, bool unitriangular) const { + return at::_ops::triangular_solve::call(const_cast(*this), A, upper, transpose, unitriangular); +} + +// aten::svd(Tensor self, bool some=True, bool compute_uv=True) -> (Tensor U, Tensor S, Tensor V) +inline ::std::tuple Tensor::svd(bool some, bool compute_uv) const { + return at::_ops::svd::call(const_cast(*this), some, compute_uv); +} + +// aten::swapaxes(Tensor(a) self, int axis0, int axis1) -> Tensor(a) +inline at::Tensor Tensor::swapaxes(int64_t axis0, int64_t axis1) const { + return at::_ops::swapaxes::call(const_cast(*this), axis0, axis1); +} + +// aten::swapaxes_(Tensor(a!) self, int axis0, int axis1) -> Tensor(a!) +inline at::Tensor & Tensor::swapaxes_(int64_t axis0, int64_t axis1) const { + return at::_ops::swapaxes_::call(const_cast(*this), axis0, axis1); +} + +// aten::swapdims(Tensor(a) self, int dim0, int dim1) -> Tensor(a) +inline at::Tensor Tensor::swapdims(int64_t dim0, int64_t dim1) const { + return at::_ops::swapdims::call(const_cast(*this), dim0, dim1); +} + +// aten::swapdims_(Tensor(a!) self, int dim0, int dim1) -> Tensor(a!) +inline at::Tensor & Tensor::swapdims_(int64_t dim0, int64_t dim1) const { + return at::_ops::swapdims_::call(const_cast(*this), dim0, dim1); +} + +// aten::cholesky(Tensor self, bool upper=False) -> Tensor +inline at::Tensor Tensor::cholesky(bool upper) const { + return at::_ops::cholesky::call(const_cast(*this), upper); +} + +// aten::cholesky_solve(Tensor self, Tensor input2, bool upper=False) -> Tensor +inline at::Tensor Tensor::cholesky_solve(const at::Tensor & input2, bool upper) const { + return at::_ops::cholesky_solve::call(const_cast(*this), input2, upper); +} + +// aten::cholesky_inverse(Tensor self, bool upper=False) -> Tensor +inline at::Tensor Tensor::cholesky_inverse(bool upper) const { + return at::_ops::cholesky_inverse::call(const_cast(*this), upper); +} + +// aten::qr(Tensor self, bool some=True) -> (Tensor Q, Tensor R) +inline ::std::tuple Tensor::qr(bool some) const { + return at::_ops::qr::call(const_cast(*this), some); +} + +// aten::geqrf(Tensor self) -> (Tensor a, Tensor tau) +inline ::std::tuple Tensor::geqrf() const { + return at::_ops::geqrf::call(const_cast(*this)); +} + +// aten::orgqr(Tensor self, Tensor input2) -> Tensor +inline at::Tensor Tensor::orgqr(const at::Tensor & input2) const { + return at::_ops::orgqr::call(const_cast(*this), input2); +} + +// aten::ormqr(Tensor self, Tensor input2, Tensor input3, bool left=True, bool transpose=False) -> Tensor +inline at::Tensor Tensor::ormqr(const at::Tensor & input2, const at::Tensor & input3, bool left, bool transpose) const { + return at::_ops::ormqr::call(const_cast(*this), input2, input3, left, transpose); +} + +// aten::lu_solve(Tensor self, Tensor LU_data, Tensor LU_pivots) -> Tensor +inline at::Tensor Tensor::lu_solve(const at::Tensor & LU_data, const at::Tensor & LU_pivots) const { + return at::_ops::lu_solve::call(const_cast(*this), LU_data, LU_pivots); +} + +// aten::multinomial(Tensor self, int num_samples, bool replacement=False, *, Generator? generator=None) -> Tensor +inline at::Tensor Tensor::multinomial(int64_t num_samples, bool replacement, ::std::optional generator) const { + return at::_ops::multinomial::call(const_cast(*this), num_samples, replacement, generator); +} + +// aten::lgamma_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::lgamma_() const { + return at::_ops::lgamma_::call(const_cast(*this)); +} + +// aten::lgamma(Tensor self) -> Tensor +inline at::Tensor Tensor::lgamma() const { + return at::_ops::lgamma::call(const_cast(*this)); +} + +// aten::digamma(Tensor self) -> Tensor +inline at::Tensor Tensor::digamma() const { + return at::_ops::digamma::call(const_cast(*this)); +} + +// aten::polygamma(int n, Tensor self) -> Tensor +inline at::Tensor Tensor::polygamma(int64_t n) const { + return at::_ops::polygamma::call(n, const_cast(*this)); +} + +// aten::polygamma_(Tensor(a!) self, int n) -> Tensor(a!) +inline at::Tensor & Tensor::polygamma_(int64_t n) const { + return at::_ops::polygamma_::call(const_cast(*this), n); +} + +// aten::erfinv(Tensor self) -> Tensor +inline at::Tensor Tensor::erfinv() const { + return at::_ops::erfinv::call(const_cast(*this)); +} + +// aten::erfinv_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::erfinv_() const { + return at::_ops::erfinv_::call(const_cast(*this)); +} + +// aten::i0(Tensor self) -> Tensor +inline at::Tensor Tensor::i0() const { + return at::_ops::i0::call(const_cast(*this)); +} + +// aten::i0_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::i0_() const { + return at::_ops::i0_::call(const_cast(*this)); +} + +// aten::sign(Tensor self) -> Tensor +inline at::Tensor Tensor::sign() const { + return at::_ops::sign::call(const_cast(*this)); +} + +// aten::sign_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & Tensor::sign_() const { + return at::_ops::sign_::call(const_cast(*this)); +} + +// aten::signbit(Tensor self) -> Tensor +inline at::Tensor Tensor::signbit() const { + return at::_ops::signbit::call(const_cast(*this)); +} + +// aten::dist(Tensor self, Tensor other, Scalar p=2) -> Tensor +inline at::Tensor Tensor::dist(const at::Tensor & other, const at::Scalar & p) const { + return at::_ops::dist::call(const_cast(*this), other, p); +} + +// aten::atan2_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::atan2_(const at::Tensor & other) const { + return at::_ops::atan2_::call(const_cast(*this), other); +} + +// aten::atan2(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::atan2(const at::Tensor & other) const { + return at::_ops::atan2::call(const_cast(*this), other); +} + +// aten::arctan2(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::arctan2(const at::Tensor & other) const { + return at::_ops::arctan2::call(const_cast(*this), other); +} + +// aten::arctan2_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::arctan2_(const at::Tensor & other) const { + return at::_ops::arctan2_::call(const_cast(*this), other); +} + +// aten::lerp.Scalar(Tensor self, Tensor end, Scalar weight) -> Tensor +inline at::Tensor Tensor::lerp(const at::Tensor & end, const at::Scalar & weight) const { + return at::_ops::lerp_Scalar::call(const_cast(*this), end, weight); +} + +// aten::lerp.Tensor(Tensor self, Tensor end, Tensor weight) -> Tensor +inline at::Tensor Tensor::lerp(const at::Tensor & end, const at::Tensor & weight) const { + return at::_ops::lerp_Tensor::call(const_cast(*this), end, weight); +} + +// aten::histc(Tensor self, int bins=100, Scalar min=0, Scalar max=0) -> Tensor +inline at::Tensor Tensor::histc(int64_t bins, const at::Scalar & min, const at::Scalar & max) const { + return at::_ops::histc::call(const_cast(*this), bins, min, max); +} + +// aten::histogram.bins_tensor(Tensor self, Tensor bins, *, Tensor? weight=None, bool density=False) -> (Tensor hist, Tensor bin_edges) +inline ::std::tuple Tensor::histogram(const at::Tensor & bins, const ::std::optional & weight, bool density) const { + return at::_ops::histogram_bins_tensor::call(const_cast(*this), bins, weight, density); +} + +// aten::histogram.bin_ct(Tensor self, int bins=100, *, float[]? range=None, Tensor? weight=None, bool density=False) -> (Tensor hist, Tensor bin_edges) +inline ::std::tuple Tensor::histogram(int64_t bins, ::std::optional> range, const ::std::optional & weight, bool density) const { + return at::_ops::histogram_bin_ct::call(const_cast(*this), bins, range, weight, density); +} + +// aten::fmod.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::fmod(const at::Scalar & other) const { + return at::_ops::fmod_Scalar::call(const_cast(*this), other); +} + +// aten::fmod_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::fmod_(const at::Scalar & other) const { + return at::_ops::fmod__Scalar::call(const_cast(*this), other); +} + +// aten::fmod.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::fmod(const at::Tensor & other) const { + return at::_ops::fmod_Tensor::call(const_cast(*this), other); +} + +// aten::fmod_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::fmod_(const at::Tensor & other) const { + return at::_ops::fmod__Tensor::call(const_cast(*this), other); +} + +// aten::hypot(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::hypot(const at::Tensor & other) const { + return at::_ops::hypot::call(const_cast(*this), other); +} + +// aten::hypot_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::hypot_(const at::Tensor & other) const { + return at::_ops::hypot_::call(const_cast(*this), other); +} + +// aten::igamma(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::igamma(const at::Tensor & other) const { + return at::_ops::igamma::call(const_cast(*this), other); +} + +// aten::igamma_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::igamma_(const at::Tensor & other) const { + return at::_ops::igamma_::call(const_cast(*this), other); +} + +// aten::igammac(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::igammac(const at::Tensor & other) const { + return at::_ops::igammac::call(const_cast(*this), other); +} + +// aten::igammac_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::igammac_(const at::Tensor & other) const { + return at::_ops::igammac_::call(const_cast(*this), other); +} + +// aten::nextafter(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::nextafter(const at::Tensor & other) const { + return at::_ops::nextafter::call(const_cast(*this), other); +} + +// aten::nextafter_(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::nextafter_(const at::Tensor & other) const { + return at::_ops::nextafter_::call(const_cast(*this), other); +} + +// aten::remainder.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor Tensor::remainder(const at::Scalar & other) const { + return at::_ops::remainder_Scalar::call(const_cast(*this), other); +} + +// aten::remainder_.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & Tensor::remainder_(const at::Scalar & other) const { + return at::_ops::remainder__Scalar::call(const_cast(*this), other); +} + +// aten::remainder.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::remainder(const at::Tensor & other) const { + return at::_ops::remainder_Tensor::call(const_cast(*this), other); +} + +// aten::remainder_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & Tensor::remainder_(const at::Tensor & other) const { + return at::_ops::remainder__Tensor::call(const_cast(*this), other); +} + +// aten::min(Tensor self) -> Tensor +inline at::Tensor Tensor::min() const { + return at::_ops::min::call(const_cast(*this)); +} + +// aten::fmin(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::fmin(const at::Tensor & other) const { + return at::_ops::fmin::call(const_cast(*this), other); +} + +// aten::max(Tensor self) -> Tensor +inline at::Tensor Tensor::max() const { + return at::_ops::max::call(const_cast(*this)); +} + +// aten::fmax(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::fmax(const at::Tensor & other) const { + return at::_ops::fmax::call(const_cast(*this), other); +} + +// aten::maximum(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::maximum(const at::Tensor & other) const { + return at::_ops::maximum::call(const_cast(*this), other); +} + +// aten::max.other(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::max(const at::Tensor & other) const { + return at::_ops::max_other::call(const_cast(*this), other); +} + +// aten::minimum(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::minimum(const at::Tensor & other) const { + return at::_ops::minimum::call(const_cast(*this), other); +} + +// aten::min.other(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::min(const at::Tensor & other) const { + return at::_ops::min_other::call(const_cast(*this), other); +} + +// aten::quantile(Tensor self, Tensor q, int? dim=None, bool keepdim=False, *, str interpolation='linear') -> Tensor +inline at::Tensor Tensor::quantile(const at::Tensor & q, ::std::optional dim, bool keepdim, c10::string_view interpolation) const { + return at::_ops::quantile::call(const_cast(*this), q, dim, keepdim, interpolation); +} + +// aten::quantile.scalar(Tensor self, float q, int? dim=None, bool keepdim=False, *, str interpolation='linear') -> Tensor +inline at::Tensor Tensor::quantile(double q, ::std::optional dim, bool keepdim, c10::string_view interpolation) const { + return at::_ops::quantile_scalar::call(const_cast(*this), q, dim, keepdim, interpolation); +} + +// aten::nanquantile(Tensor self, Tensor q, int? dim=None, bool keepdim=False, *, str interpolation='linear') -> Tensor +inline at::Tensor Tensor::nanquantile(const at::Tensor & q, ::std::optional dim, bool keepdim, c10::string_view interpolation) const { + return at::_ops::nanquantile::call(const_cast(*this), q, dim, keepdim, interpolation); +} + +// aten::nanquantile.scalar(Tensor self, float q, int? dim=None, bool keepdim=False, *, str interpolation='linear') -> Tensor +inline at::Tensor Tensor::nanquantile(double q, ::std::optional dim, bool keepdim, c10::string_view interpolation) const { + return at::_ops::nanquantile_scalar::call(const_cast(*this), q, dim, keepdim, interpolation); +} + +// aten::sort(Tensor self, int dim=-1, bool descending=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::sort(int64_t dim, bool descending) const { + return at::_ops::sort::call(const_cast(*this), dim, descending); +} + +// aten::sort.stable(Tensor self, *, bool? stable, int dim=-1, bool descending=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::sort(::std::optional stable, int64_t dim, bool descending) const { + return at::_ops::sort_stable::call(const_cast(*this), stable, dim, descending); +} + +// aten::sort.dimname(Tensor self, Dimname dim, bool descending=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::sort(at::Dimname dim, bool descending) const { + return at::_ops::sort_dimname::call(const_cast(*this), dim, descending); +} + +// aten::sort.dimname_stable(Tensor self, *, bool? stable, Dimname dim, bool descending=False) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::sort(::std::optional stable, at::Dimname dim, bool descending) const { + return at::_ops::sort_dimname_stable::call(const_cast(*this), stable, dim, descending); +} + +// aten::msort(Tensor self) -> Tensor +inline at::Tensor Tensor::msort() const { + return at::_ops::msort::call(const_cast(*this)); +} + +// aten::argsort(Tensor self, int dim=-1, bool descending=False) -> Tensor +inline at::Tensor Tensor::argsort(int64_t dim, bool descending) const { + return at::_ops::argsort::call(const_cast(*this), dim, descending); +} + +// aten::argsort.stable(Tensor self, *, bool stable, int dim=-1, bool descending=False) -> Tensor +inline at::Tensor Tensor::argsort(bool stable, int64_t dim, bool descending) const { + return at::_ops::argsort_stable::call(const_cast(*this), stable, dim, descending); +} + +// aten::argsort.dimname(Tensor self, Dimname dim, bool descending=False) -> Tensor +inline at::Tensor Tensor::argsort(at::Dimname dim, bool descending) const { + return at::_ops::argsort_dimname::call(const_cast(*this), dim, descending); +} + +// aten::topk(Tensor self, SymInt k, int dim=-1, bool largest=True, bool sorted=True) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::topk(int64_t k, int64_t dim, bool largest, bool sorted) const { + return at::_ops::topk::call(const_cast(*this), k, dim, largest, sorted); +} + +// aten::topk(Tensor self, SymInt k, int dim=-1, bool largest=True, bool sorted=True) -> (Tensor values, Tensor indices) +inline ::std::tuple Tensor::topk_symint(c10::SymInt k, int64_t dim, bool largest, bool sorted) const { + return at::_ops::topk::call(const_cast(*this), k, dim, largest, sorted); +} + +// aten::all(Tensor self) -> Tensor +inline at::Tensor Tensor::all() const { + return at::_ops::all::call(const_cast(*this)); +} + +// aten::any(Tensor self) -> Tensor +inline at::Tensor Tensor::any() const { + return at::_ops::any::call(const_cast(*this)); +} + +// aten::renorm(Tensor self, Scalar p, int dim, Scalar maxnorm) -> Tensor +inline at::Tensor Tensor::renorm(const at::Scalar & p, int64_t dim, const at::Scalar & maxnorm) const { + return at::_ops::renorm::call(const_cast(*this), p, dim, maxnorm); +} + +// aten::renorm_(Tensor(a!) self, Scalar p, int dim, Scalar maxnorm) -> Tensor(a!) +inline at::Tensor & Tensor::renorm_(const at::Scalar & p, int64_t dim, const at::Scalar & maxnorm) const { + return at::_ops::renorm_::call(const_cast(*this), p, dim, maxnorm); +} + +// aten::unfold(Tensor(a) self, int dimension, int size, int step) -> Tensor(a) +inline at::Tensor Tensor::unfold(int64_t dimension, int64_t size, int64_t step) const { + return at::_ops::unfold::call(const_cast(*this), dimension, size, step); +} + +// aten::equal(Tensor self, Tensor other) -> bool +inline bool Tensor::equal(const at::Tensor & other) const { + return at::_ops::equal::call(const_cast(*this), other); +} + +// aten::pow.Tensor_Tensor(Tensor self, Tensor exponent) -> Tensor +inline at::Tensor Tensor::pow(const at::Tensor & exponent) const { + return at::_ops::pow_Tensor_Tensor::call(const_cast(*this), exponent); +} + +// aten::pow.Tensor_Scalar(Tensor self, Scalar exponent) -> Tensor +inline at::Tensor Tensor::pow(const at::Scalar & exponent) const { + return at::_ops::pow_Tensor_Scalar::call(const_cast(*this), exponent); +} + +// aten::pow_.Scalar(Tensor(a!) self, Scalar exponent) -> Tensor(a!) +inline at::Tensor & Tensor::pow_(const at::Scalar & exponent) const { + return at::_ops::pow__Scalar::call(const_cast(*this), exponent); +} + +// aten::pow_.Tensor(Tensor(a!) self, Tensor exponent) -> Tensor(a!) +inline at::Tensor & Tensor::pow_(const at::Tensor & exponent) const { + return at::_ops::pow__Tensor::call(const_cast(*this), exponent); +} + +// aten::float_power.Tensor_Tensor(Tensor self, Tensor exponent) -> Tensor +inline at::Tensor Tensor::float_power(const at::Tensor & exponent) const { + return at::_ops::float_power_Tensor_Tensor::call(const_cast(*this), exponent); +} + +// aten::float_power.Tensor_Scalar(Tensor self, Scalar exponent) -> Tensor +inline at::Tensor Tensor::float_power(const at::Scalar & exponent) const { + return at::_ops::float_power_Tensor_Scalar::call(const_cast(*this), exponent); +} + +// aten::float_power_.Scalar(Tensor(a!) self, Scalar exponent) -> Tensor(a!) +inline at::Tensor & Tensor::float_power_(const at::Scalar & exponent) const { + return at::_ops::float_power__Scalar::call(const_cast(*this), exponent); +} + +// aten::float_power_.Tensor(Tensor(a!) self, Tensor exponent) -> Tensor(a!) +inline at::Tensor & Tensor::float_power_(const at::Tensor & exponent) const { + return at::_ops::float_power__Tensor::call(const_cast(*this), exponent); +} + +// aten::normal_(Tensor(a!) self, float mean=0, float std=1, *, Generator? generator=None) -> Tensor(a!) +inline at::Tensor & Tensor::normal_(double mean, double std, ::std::optional generator) const { + return at::_ops::normal_::call(const_cast(*this), mean, std, generator); +} + +// aten::alias(Tensor(a) self) -> Tensor(a) +inline at::Tensor Tensor::alias() const { + return at::_ops::alias::call(const_cast(*this)); +} + +// aten::isfinite(Tensor self) -> Tensor +inline at::Tensor Tensor::isfinite() const { + return at::_ops::isfinite::call(const_cast(*this)); +} + +// aten::isinf(Tensor self) -> Tensor +inline at::Tensor Tensor::isinf() const { + return at::_ops::isinf::call(const_cast(*this)); +} + +// aten::record_stream(Tensor(a!) self, Stream s) -> () +inline void Tensor::record_stream(at::Stream s) const { + return at::_ops::record_stream::call(const_cast(*this), s); +} + +// aten::isposinf(Tensor self) -> Tensor +inline at::Tensor Tensor::isposinf() const { + return at::_ops::isposinf::call(const_cast(*this)); +} + +// aten::isneginf(Tensor self) -> Tensor +inline at::Tensor Tensor::isneginf() const { + return at::_ops::isneginf::call(const_cast(*this)); +} + +// aten::det(Tensor self) -> Tensor +inline at::Tensor Tensor::det() const { + return at::_ops::det::call(const_cast(*this)); +} + +// aten::slogdet(Tensor self) -> (Tensor sign, Tensor logabsdet) +inline ::std::tuple Tensor::slogdet() const { + return at::_ops::slogdet::call(const_cast(*this)); +} + +// aten::logdet(Tensor self) -> Tensor +inline at::Tensor Tensor::logdet() const { + return at::_ops::logdet::call(const_cast(*this)); +} + +// aten::inverse(Tensor self) -> Tensor +inline at::Tensor Tensor::inverse() const { + return at::_ops::inverse::call(const_cast(*this)); +} + +// aten::inner(Tensor self, Tensor other) -> Tensor +inline at::Tensor Tensor::inner(const at::Tensor & other) const { + return at::_ops::inner::call(const_cast(*this), other); +} + +// aten::outer(Tensor self, Tensor vec2) -> Tensor +inline at::Tensor Tensor::outer(const at::Tensor & vec2) const { + return at::_ops::outer::call(const_cast(*this), vec2); +} + +// aten::ger(Tensor self, Tensor vec2) -> Tensor +inline at::Tensor Tensor::ger(const at::Tensor & vec2) const { + return at::_ops::ger::call(const_cast(*this), vec2); +} + +// aten::to_padded_tensor(Tensor self, float padding, SymInt[]? output_size=None) -> Tensor +inline at::Tensor Tensor::to_padded_tensor(double padding, at::OptionalIntArrayRef output_size) const { + return at::_ops::to_padded_tensor::call(const_cast(*this), padding, output_size.has_value() ? ::std::make_optional(c10::fromIntArrayRefSlow(*output_size)) : ::std::nullopt); +} + +// aten::to_padded_tensor(Tensor self, float padding, SymInt[]? output_size=None) -> Tensor +inline at::Tensor Tensor::to_padded_tensor_symint(double padding, at::OptionalSymIntArrayRef output_size) const { + return at::_ops::to_padded_tensor::call(const_cast(*this), padding, output_size); +} +} // namespace at + + +namespace c10 { +template <> +struct MaybeOwnedTraits { + using owned_type = at::Tensor; + using borrow_type = at::Tensor; + + static borrow_type createBorrow(const owned_type& from) { + // NOTE: this can be implemented without the special + // unsafe_borrow_t Tensor constructor as + // + // return borrow_type(c10::intrusive_ptr::reclaim(from.unsafeGetTensorImpl())); + // + // but that hurts inlining due to the nullptr check in the + // Tensor(c10::intrusive_ptr<...>) constructor. We already know + // that from.impl_ isn't null because from is a valid Tensor, so + // we needn't do the check again. (using __builtin_assume can + // avoid this, but wouldn't be portable to MSVC.) + return borrow_type(borrow_type::unsafe_borrow_t{}, from); + } + + static void assignBorrow(borrow_type& lhs, const borrow_type& rhs) { + lhs.unsafeReleaseTensorImpl(); + // See above note: this can be implemented with public API + // similarly to createBorrow(), but that would hurt inlining. + lhs = borrow_type(borrow_type::unsafe_borrow_t{}, rhs); + } + + static void destroyBorrow(borrow_type& toDestroy) { + toDestroy.unsafeReleaseTensorImpl(); // "leak" it, but it was already +0. + } + + static const owned_type& referenceFromBorrow(const borrow_type& borrow) { + return borrow; + } + + static const owned_type* pointerFromBorrow(const borrow_type& borrow) { + return &borrow; + } + + static bool debugBorrowIsValid(const borrow_type& /*borrow*/) { + return true; + } +}; + +template <> +struct ExclusivelyOwnedTraits { + using repr_type = at::Tensor; + using pointer_type = at::Tensor*; + using const_pointer_type = const at::Tensor*; + + static repr_type nullRepr() { + return at::Tensor(); + } + + template + static repr_type createInPlace(Args&&... args) { + return at::Tensor(std::forward(args)...); + } + + static repr_type moveToRepr(at::Tensor&& x) { + return std::move(x); + } + + static void destroyOwned(at::Tensor& x) { + return ExclusivelyOwnedTraits::destroyOwned(x); + } + + static at::Tensor take(at::Tensor& x) { + return std::move(x); + } + + static pointer_type getImpl(repr_type& x) { + return &x; + } + + static const_pointer_type getImpl(const repr_type& x) { + return &x; + } +}; +} // namespace c10 + +namespace at { + +inline c10::MaybeOwned borrow_from_optional_tensor( + const std::optional& opt) { + return opt.has_value() + ? c10::MaybeOwned::borrowed(*opt) + : c10::MaybeOwned::owned(std::in_place); +} + +inline c10::MaybeOwned Tensor::expect_contiguous(MemoryFormat memory_format) const & { + if (is_contiguous(memory_format)) { + return c10::MaybeOwned::borrowed(*this); + } else { + return c10::MaybeOwned::owned(__dispatch_contiguous(memory_format)); + } +} +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TorchDispatchUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TorchDispatchUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..7cb9934102852c3788ebdefa4b1738151391cf14 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TorchDispatchUtils.h @@ -0,0 +1,17 @@ +#pragma once + +#include +#include +#include +#include +#include + +namespace at::impl { + +TORCH_API bool tensor_has_dispatch(const at::Tensor& t); +TORCH_API bool tensorlist_has_dispatch(at::ITensorListRef li); +TORCH_API bool tensorlist_has_dispatch( + const c10::List>& li); +using c10::impl::dispatch_mode_enabled; + +} // namespace at::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TransformationHelper.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TransformationHelper.h new file mode 100644 index 0000000000000000000000000000000000000000..f81018a8e674f21027ef665c69a2788affe4f15a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/TransformationHelper.h @@ -0,0 +1,175 @@ +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at { + +// Using DistAccumType in accumulate types for distributions. +// Note: Ideally we'd be using ATen/AccumulateType.h but looks +// like the there is some inconsistency in how accumulate types +// are mapped currently, e.g. for the cpu side, float is mapped +// to double. +template +struct DistAccumType { }; + +#if defined(__CUDACC__) || defined(__HIPCC__) +template <> struct DistAccumType { using type = float; }; +#endif +template <> struct DistAccumType { using type = float; }; +template <> struct DistAccumType { using type = float; }; +template <> struct DistAccumType { using type = float; }; +template <> struct DistAccumType { using type = double; }; + +template +using dist_acctype = typename DistAccumType::type; + +namespace transformation { + +/** + * A transformation function for `torch.Tensor.random_()`, when both `from` and `to` are specified. + * `range` is `to - from` + * `base` is `from` + */ +template +C10_HOST_DEVICE inline T uniform_int_from_to(V val, uint64_t range, int64_t base) { + return static_cast(static_cast((val % range) + base)); +} + +/** + * A transformation function for `torch.Tensor.random_()`, when `from=min_value(int64_t)` and to=None + */ +template +C10_HOST_DEVICE inline T uniform_int_full_range(V val) { + return static_cast(static_cast(val)); +} + +/** + * A transformation function for `torch.Tensor.random_()`, when used without specifying `from` and `to`. + * In order to prevent compiler warnings reported in GitHub issue 46391, T can't be float or double + * in this overloaded version + */ +template +C10_HOST_DEVICE inline std::enable_if_t), T>uniform_int(V val) { + if constexpr (std::is_same_v) { + return static_cast(val & 1); + } else if constexpr (std::is_same_v) { + return static_cast(val % (static_cast(std::numeric_limits::max()) + 1)); + } else if constexpr (std::is_same_v || std::is_same_v) { + return static_cast(val % static_cast((1ULL << std::numeric_limits::digits) + 1)); + } else if constexpr (std::is_integral_v) { + return static_cast(val % (static_cast(std::numeric_limits::max()) + 1)); + } else { + assert(false); + return 0; + } +} + +/** + * An overloaded transformation function for `torch.Tensor.random_()`, when used without specifying `from` and `to`, + * added to fix compiler warnings reported in GitHub issue 46391. T is either float or double in this version. + */ +template +C10_HOST_DEVICE inline std::enable_if_t, T>uniform_int(V val) { + return static_cast(val % static_cast((1ULL << std::numeric_limits::digits) + 1)); +} + +template +C10_HOST_DEVICE inline dist_acctype uniform_real(V val, T from, T to) { + constexpr auto MASK = static_cast((static_cast(1) << std::numeric_limits::digits) - 1); + constexpr auto DIVISOR = static_cast>(1) / (static_cast(1) << std::numeric_limits::digits); + dist_acctype x = (val & MASK) * DIVISOR; + return (x * (to - from) + from); +} + +/** + * Transforms normally distributed `val` with mean 0.0 and standard deviation 1.0 to + * normally distributed with `mean` and standard deviation `std`. + */ +template +C10_HOST_DEVICE inline T normal(T val, T mean, T std) { + return val * std + mean; +} + +/** + * Transforms uniformly distributed `val` between 0.0 and 1.0 to + * Cauchy distribution with location parameter `median` and scale parameter `sigma`. + */ +template +C10_HOST_DEVICE inline T cauchy(T val, T median, T sigma) { + // https://en.wikipedia.org/wiki/Cauchy_distribution#Cumulative_distribution_function + // __tanf overflows and returns `inf/-inf` when (val > 1 - eps) or (val < 0 + eps), + // thus we clip those values. + constexpr T eps = std::numeric_limits::epsilon(); + constexpr T one_minus_eps = 1 - eps; + constexpr T zero_plus_eps = 0 + eps; + val = (val > one_minus_eps ? one_minus_eps : val); + val = (val < zero_plus_eps ? zero_plus_eps : val); + return median + sigma * at::tan(c10::pi * (val - static_cast(0.5))); +} + +template <> +C10_HOST_DEVICE inline double cauchy(double val, double median, double sigma) { + // https://en.wikipedia.org/wiki/Cauchy_distribution#Cumulative_distribution_function + return median + sigma * at::tan(c10::pi * (val - static_cast(0.5))); +} + +/** + * Transforms uniformly distributed `val` between 0.0 and 1.0 to + * exponentially distributed with `lambda` parameter of the distribution. + */ +template +C10_HOST_DEVICE inline T exponential(T val, T lambda) { + // https://en.wikipedia.org/wiki/Exponential_distribution#Generating_exponential_variates + // Different implementations for CUDA and CPU to preserve original logic + // TODO: must be investigated and unified!!! + // https://github.com/pytorch/pytorch/issues/38662 +#if defined(__CUDACC__) || defined(__HIPCC__) + // BEFORE TOUCHING THIS CODE READ: https://github.com/pytorch/pytorch/issues/16706 + // curand_uniform has (0,1] bounds. log(1) is 0 and exponential excludes 0. + // we need log to be not 0, and not underflow when converted to half + // fast __logf approximation can underflow, so set log to -epsilon/2 for 1 or close to 1 args + auto log = val >= static_cast(1.) - std::numeric_limits::epsilon() / 2 + ? -std::numeric_limits::epsilon() / 2 + : at::log(val); + return static_cast(-1.0) / lambda * log; +#else + return static_cast(-1.0) / lambda * at::log1p(-val); +#endif +} + +/** + * Transforms uniformly distributed `val` between 0.0 and 1.0 to + * geometrically distributed with success probability `p`. + */ +template +C10_HOST_DEVICE inline T geometric(T val, T p) { + // https://en.wikipedia.org/wiki/Geometric_distribution#Related_distributions + return static_cast(::ceil(at::log(val) / at::log1p(-p))); +} + +/** + * Transforms normally distributed `val` to log-normally distributed. + */ +template +C10_HOST_DEVICE inline T log_normal(T val) { + // https://en.wikipedia.org/wiki/Log-normal_distribution#Mode,_median,_quantiles + return at::exp(val); +} + +/** + * Transforms uniformly distributed `val` between 0.0 and 1.0 to + * bernoulli distributed with success probability `p`. + */ +template +C10_HOST_DEVICE inline T bernoulli(T val, T p) { + return val < p; +} + +}} // namespace at::transformation diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/UndefinedTensorImpl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/UndefinedTensorImpl.h new file mode 100644 index 0000000000000000000000000000000000000000..885f6e195f05d37ab4253315242167f8e546dcc1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/UndefinedTensorImpl.h @@ -0,0 +1 @@ +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/UnsafeFromTH.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/UnsafeFromTH.h new file mode 100644 index 0000000000000000000000000000000000000000..9ad5c45d3ab6ca499bc10b71c68bc04ededfeb87 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/UnsafeFromTH.h @@ -0,0 +1,21 @@ +#pragma once +#include + +namespace at { + +inline Tensor unsafeTensorFromTH(void * th_pointer, bool retain) { + auto tensor_impl = c10::intrusive_ptr::reclaim(static_cast(th_pointer)); + if (retain && tensor_impl.get() != UndefinedTensorImpl::singleton()) { + c10::raw::intrusive_ptr::incref(tensor_impl.get()); + } + return Tensor(std::move(tensor_impl)); +} + +inline Storage unsafeStorageFromTH(void * th_pointer, bool retain) { + if (retain && th_pointer) { + c10::raw::intrusive_ptr::incref(static_cast(th_pointer)); + } + return Storage(c10::intrusive_ptr::reclaim(static_cast(th_pointer))); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/VariableHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/VariableHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..f9c0aa4a5fc1482bff955cda5768c9dad41031d7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/VariableHooksInterface.h @@ -0,0 +1,83 @@ +#pragma once + +#include +#include + +// A little explanation about why this file exists at all. We have +// a few methods on Tensor class which require access to reified access to +// AutogradMeta. In open source, this isn't a big deal: we just access +// torch/csrc/autograd/variable.h from aten/src/ATen/core/Tensor.cpp and +// we can put the definitions inline. This is because everything gets balled +// into a single dynamic library in the end. +// +// However, inside our Facebook internal version of our build system, we +// have a split between aten and torch/csrc. So we cannot simply just +// cross this boundary. "Now wait," you might say, "Why don't we just +// merge the libraries inside Facebook". Well, the problem is that there +// are some downstream applications which are at binary size limit, and +// incorporating all of the extra code from libtorch would push them +// over (admarket/adreview/service:adreviewservice, see also +// https://github.com/pytorch/pytorch/pull/29299) So if you want to do that, +// we have to fix all of the services like this. +// +// I didn't want to block eliminating Tensor-Variable on this work, so I +// had to introduce another dynamic dispatch to get to the variable +// implementations (which live in torch/csrc/autograd/variable.cpp, FYI). +// +// I also considered using our existing dynamic dispatch mechanism, c10 +// dispatcher, to do this. However, (1) some of the functions on Tensor +// have weird signatures that are not supported by autograd, and (2) +// see this bug https://github.com/pytorch/pytorch/issues/30102 + +namespace torch::autograd { + +struct Node; + +} // namespace torch::autograd + +namespace at::impl { + +struct TORCH_API VariableHooksInterface { + virtual ~VariableHooksInterface() = default; + virtual TensorBase tensor_data(const TensorBase&) const = 0; + virtual TensorBase variable_data(const TensorBase&) const = 0; + virtual const std::shared_ptr& grad_fn( + const TensorBase&) const = 0; + virtual unsigned _register_hook( + const TensorBase&, + std::function hook) const = 0; + virtual void remove_hook(const TensorBase&, unsigned pos) const = 0; + virtual bool is_view(const TensorBase&) const = 0; + virtual const TensorBase& base(const TensorBase&) const = 0; + virtual const std::string& name(const TensorBase&) const = 0; + virtual bool is_leaf(const TensorBase&) const = 0; + virtual int64_t output_nr(const TensorBase&) const = 0; + virtual void set_data(const TensorBase&, const TensorBase&) const = 0; + virtual TensorBase data(const TensorBase&) const = 0; + virtual int64_t _version(const TensorBase&) const = 0; + virtual void retain_grad(const TensorBase&) const = 0; + virtual bool retains_grad(const TensorBase&) const = 0; + virtual void _backward( + const Tensor&, + TensorList, + const std::optional&, + std::optional, + bool) const = 0; + virtual void requires_grad_(const TensorBase&, bool) const = 0; + virtual void basic_autograd_not_implemented_fallback( + const c10::OperatorHandle& op, + c10::DispatchKeySet dispatch_keys, + torch::jit::Stack* stack) const = 0; +}; + +TORCH_API void SetVariableHooks(VariableHooksInterface* hooks); +TORCH_API VariableHooksInterface* GetVariableHooks(); +TORCH_API bool HasVariableHooks(); + +struct TORCH_API VariableHooksRegisterer { + explicit VariableHooksRegisterer(VariableHooksInterface* hooks) { + SetVariableHooks(hooks); + } +}; + +} // namespace at::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Variadic.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Variadic.h new file mode 100644 index 0000000000000000000000000000000000000000..da4df1b1b1a6628f76852d1012c7451fbdd85c3e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Variadic.h @@ -0,0 +1,92 @@ +#pragma once + +#include + +#include +#include + +namespace at { + +// This class allows you to write variadic functions which +// call a (possibly overloaded) function on each argument, +// in order. This is most commonly used in autogenerated code, +// where it is convenient to have a function that can uniformly +// take arguments of different types. If your arguments +// are homogenous consider using a std::initializer_list instead. +// +// For examples of this in use, see torch/csrc/utils/variadic.h +template +struct IterArgs { + template + inline F& apply() { + return self(); + } + + // NB: Use perfect forwarding here, otherwise we'll make value + // copies of all arguments! + template + inline F& apply(T&& arg, Args&&... args) { + self()(std::forward(arg)); + if (self().short_circuit()) { + return self(); + } else { + return apply(std::forward(args)...); + } + } + + // Here are some handy overloads which provide sensible + // defaults for container-like structures that one might + // be interested in recursing into. You can enable them + // by adding: + // + // using IterArgs::operator() + // + // to your struct. These are not enabled by default because + // you may be able to process these structures more efficiently + // than handling them one-by-one. + + template + void operator()(c10::IListRef args) { + for (const auto& arg : args) { + self()(arg); + if (self().short_circuit()) + return; + } + } + + template + void operator()(at::ArrayRef args) { + for (const auto& arg : args) { + self()(arg); + if (self().short_circuit()) + return; + } + } + + template + void operator()(const torch::List& args) { + for (const auto& arg : args) { + self()(arg); + if (self().short_circuit()) + return; + } + } + + // NB: we need to specify std::vector manually as C++ won't + // do an implicit conversion to make a template deduction go through. + template + void operator()(const std::vector& args) { + self()(at::ArrayRef{args}); + } + + constexpr bool short_circuit() const { + return false; + } + + private: + inline F& self() { + return *static_cast(this); + } +}; + +} // namespace torch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Vitals.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Vitals.h new file mode 100644 index 0000000000000000000000000000000000000000..2fd7729744a10398ccc55b79cf02a2e823b1496f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/Vitals.h @@ -0,0 +1,94 @@ +#pragma once +#include +#include +#include + +#include + +namespace at::vitals { + +TORCH_API bool torchVitalEnabled(); + +struct TORCH_API TorchVitalAttr { + // always initialized to empty + std::string value; + template + TorchVitalAttr& operator<<(const T& t) { + if (torchVitalEnabled()) { + std::stringstream ss; + ss << t; + value += ss.str(); + } + return *this; + } + + template + void write(const T& t, bool force) { + if (force || torchVitalEnabled()) { + std::stringstream ss; + ss << t; + value = ss.str(); + } + } +}; + +struct TORCH_API TorchVital { + std::string name; + std::unordered_map attrs; + + explicit TorchVital(std::string n) : name(std::move(n)) {} + TorchVital(const TorchVital&) = default; + TorchVital(TorchVital&&) = default; + TorchVital& operator=(const TorchVital&) = default; + TorchVital& operator=(TorchVital&&) = default; + TorchVital() = delete; + + TorchVitalAttr& create(const std::string& attr); + TorchVitalAttr& create(const std::string& attr, bool force); + friend std::ostream& operator<<(std::ostream& os, const TorchVital& dt); + + ~TorchVital(); +}; + +std::ostream& operator<<(std::ostream& os, TorchVital const& tv); + +// A way to access vitals by string names instead of by global reference. +// This enables access to vitals from the PythonAPI. +class TORCH_API APIVitals { + public: + bool vitals_enabled; + + // Set any vital sign that was added to the map. + bool setVital( + const std::string& vital_name, + const std::string& attr_name, + const std::string& value, + bool force = false); + std::string readVitals(); + + APIVitals(); + + // Ensure this stays a singleton + APIVitals(APIVitals const& other) = delete; + APIVitals(APIVitals&& other) = delete; + APIVitals& operator=(const APIVitals&) = delete; + APIVitals& operator=(APIVitals&&) = delete; + ~APIVitals() = default; + + private: + std::unordered_map name_map_; +}; + +extern TORCH_API APIVitals VitalsAPI; + +} // namespace at::vitals + +#define TORCH_VITAL_DECLARE(name) \ + TORCH_API at::vitals::TorchVital TorchVital_##name; + +#define TORCH_VITAL_DEFINE(name) \ + TORCH_API at::vitals::TorchVital TorchVital_##name(#name); + +#define TORCH_VITAL_BASE(name) TorchVital_##name + +#define TORCH_VITAL(name, attr) TORCH_VITAL_BASE(name).create(#attr) diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/alias_info.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/alias_info.h new file mode 100644 index 0000000000000000000000000000000000000000..a8a55bb782c479ff2f0243601bd36a034980b2fe --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/alias_info.h @@ -0,0 +1,151 @@ +#pragma once +#include +#include +#include +#include +#include + +namespace c10 { +/** + * class AliasInfo + * + * Data structure to hold aliasing information for an `Argument`. They can be + * nested to represent aliasing information on contained types. + * + * There is a `beforeSet` which describes the aliasing information before the + * operator executes, and an `afterSet` that describes aliasing info + * after execution. + */ +class AliasInfo { + public: + // Symbol for the set that can alias anything + static Symbol wildcardSet() { + static const Symbol wc = Symbol::fromQualString("alias::*"); + return wc; + } + + void setIsWrite(bool isWrite) { + isWrite_ = isWrite; + } + + bool isWrite() const { + return isWrite_; + } + + void addBeforeSet(Symbol aliasSet) { + beforeSets_.insert(aliasSet); + } + + void addAfterSet(Symbol aliasSet) { + afterSets_.insert(aliasSet); + } + + const std::unordered_set& beforeSets() const { + return beforeSets_; + } + + const std::unordered_set& afterSets() const { + return afterSets_; + } + + Symbol beforeSet() const { + AT_ASSERT(beforeSets_.size() == 1); + return *beforeSets_.begin(); + } + + bool isWildcardBefore() const { + return beforeSets_.count(wildcardSet()) != 0; + } + + bool isWildcardAfter() const { + return afterSets_.count(wildcardSet()) != 0; + } + + // the alias info for the contained types of the type + // e.g. if this is an annotation on List[T], `sets` refers to + // the alias sets that the list may be in + // while containedTypes()[0] refers to the sets that members of the list + // may be in + void addContainedType(AliasInfo aliasInfo) { + containedTypes_.push_back(std::move(aliasInfo)); + } + const std::vector& containedTypes() const { + return containedTypes_; + } + + private: + std::unordered_set beforeSets_; + std::unordered_set afterSets_; + std::vector containedTypes_; + bool isWrite_ = false; +}; + +inline bool operator==(const AliasInfo& lhs, const AliasInfo& rhs) { + return lhs.isWrite() == rhs.isWrite() + && lhs.beforeSets() == rhs.beforeSets() + && lhs.afterSets() == rhs.afterSets() + && lhs.containedTypes() == rhs.containedTypes(); +} + +// this does match the way things are represented in the schema +inline std::ostream& operator<<(std::ostream& out, const AliasInfo& aliasInfo) { + out << "("; + bool first = true; + for (const auto& set : aliasInfo.beforeSets()) { + if (first) { + first = false; + } else { + out << "|"; + } + out << set.toUnqualString(); + } + if (aliasInfo.isWrite()) { + out << "!"; + } + if (aliasInfo.beforeSets() != aliasInfo.afterSets()) { + out << " -> "; + first = true; + for (const auto& set : aliasInfo.afterSets()) { + if (first) { + first = false; + } else { + out << "|"; + } + out << set.toUnqualString(); + } + } + out << ")"; + return out; +} +} // namespace c10 + +namespace std { +template <> + struct hash { + size_t operator()(const c10::AliasInfo& aliasInfo) const { + auto hash = std::hash()(aliasInfo.isWrite()); + + // NOTE: for unordered_set hashes, we couldn't use hash_combine + // because hash_combine is order dependent. Instead, we choose to + // use XOR as the combining function as XOR is commutative. + size_t before_set_hash_seed = 0; + for (auto &e: aliasInfo.beforeSets()) { + auto symbol_hash = std::hash()(e); + before_set_hash_seed = before_set_hash_seed ^ symbol_hash; + } + size_t after_set_hash_seed = 0; + for (auto &e: aliasInfo.afterSets()) { + auto symbol_hash = std::hash()(e); + after_set_hash_seed = after_set_hash_seed ^ symbol_hash; + } + + hash = c10::hash_combine(hash, before_set_hash_seed); + hash = c10::hash_combine(hash, after_set_hash_seed); + for (auto &e: aliasInfo.containedTypes()) { + auto contained_type_hash = std::hash()(e); + hash = c10::hash_combine(hash, contained_type_hash); + } + return hash; + } + }; +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/aten_interned_strings.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/aten_interned_strings.h new file mode 100644 index 0000000000000000000000000000000000000000..b53524bafe2308b66b761c2c96a2e6338ad7cb7a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/aten_interned_strings.h @@ -0,0 +1,2287 @@ +#pragma once + +// @generated by torchgen/gen.py from aten_interned_strings.h + +#if defined(TORCH_ASSERT_NO_OPERATORS) || defined(TORCH_ASSERT_ONLY_METHOD_OPERATORS) +#error This change adds a dependency on native_functions.yaml, \ + meaning the file will need to be re-compiled every time an operator \ + is changed or added. Consider if including for \ + the c10::Symbol class would be sufficient, or if your change would be \ + better placed in another file. +#endif + +// ATen symbols correspond exactly to operators defined in ATen. 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+#include + +namespace caffe2 { + +class Tensor; + +/** + * @brief Blob is a general container that hosts a typed pointer. + * + * A Blob hosts a pointer as well as its type, and takes charge of deleting it + * properly when the blob is deallocated or re-allocated with a new type. A blob + * could contain anything, although the most common case is to contain a Tensor. + */ +class TORCH_API Blob final : public c10::intrusive_ptr_target { + public: + /** + * Initializes an empty Blob. + */ + Blob() noexcept = default; + ~Blob() override { + Reset(); + } + + Blob(Blob&& other) noexcept : Blob() { + swap(other); + } + + Blob& operator=(Blob&& other) noexcept { + Blob(std::move(other)).swap(*this); + return *this; + } + + /** + * Checks if the content stored in the blob is of type T. + */ + template + bool IsType() const noexcept { + return meta_.Match(); + } + + /** + * Returns the meta info of the blob. + */ + const TypeMeta meta() const noexcept { + return meta_; + } + + /** + * Returns a printable typename of the blob. + */ + std::string_view TypeName() const noexcept { + return meta_.name(); + } + + /** + * @brief Gets the const reference of the stored object. The code checks if + * the stored object is of the desired type. + */ + // TODO(jerryzh): add a Get(c10::DeviceType) function? + template + const T& Get() const { + TORCH_INTERNAL_ASSERT( + IsType(), + "wrong type for the Blob instance. Blob contains ", + meta_.name(), + " while caller expects ", + TypeMeta::TypeName()); + // TODO: after we add Get(c10::DeviceType) + // and changed all the callsites, we can add + // a static assert here to enforce T != Tensor + return *static_cast(pointer_); + } + + const void* GetRaw() const noexcept { + return pointer_; + } + void* GetRaw() noexcept { + return pointer_; + } + + /** + * @brief Gets a mutable pointer to the stored object. + * + * If the current object is not of the right type, a new object is created + * and the old object is freed. Note that type T should have a default + * constructor. Otherwise, create the object yourself first, and use + * Reset(). + */ + template + T* GetMutable() { + static_assert( + std::is_default_constructible_v, + "GetMutable can't be called with non-default-constructible types. " + "Try using specialized methods"); + if (IsType()) { + return static_cast(pointer_); + } else { + // TODO Re-enable logging + // VLOG(1) << "Create new mutable object " << TypeMeta::TypeName(); + return Reset(new T()); + } + } + + template + T* GetMutableOrNull() { + if (IsType()) { + return static_cast(pointer_); + } else { + return nullptr; + } + } + + /** + * Sets the underlying object to the allocated one. The Blob then takes over + * the ownership of the passed in pointer. If there is already an object in + * the Blob, the old object is freed. + * + * This is used when the underlying class T does not have a default ctor, or + * complex initializations needs to be done outside the blob. + */ + template + T* Reset(T* allocated) { + free_(); + meta_ = TypeMeta::Make(); + pointer_ = static_cast(allocated); + has_ownership_ = true; + return allocated; + } + + /** + * Sets the underlying object to the allocated one, but does not take over + * the ownership of the passed in pointer. If there is already an object in + * the Blob, the old object is freed. + * + * Unlike Reset, this does not take over the ownership of the pointer and the + * caller is responsible for making sure that the lifetime of the allocated + * blob outlasts the lifetime of any access to this blob, until another Reset + * call is made or the blob is destructed. + */ + template + std::remove_const_t* ShareExternal( + std::remove_const_t* allocated) { + return static_cast(ShareExternal( + static_cast(allocated), + TypeMeta::Make>())); + } + + void* ShareExternal(void* allocated, const TypeMeta meta) { + free_(); + meta_ = meta; + pointer_ = allocated; + has_ownership_ = false; + return allocated; + } + + /** + * Resets the Blob to an empty one. + */ + void Reset() { + free_(); + pointer_ = nullptr; + meta_ = TypeMeta(); + has_ownership_ = false; + } + + /** + * @brief Swaps the underlying storage of two blobs. + */ + void swap(Blob& rhs) noexcept { + using std::swap; + swap(meta_, rhs.meta_); + swap(pointer_, rhs.pointer_); + swap(has_ownership_, rhs.has_ownership_); + } + + private: + void free_() { + if (has_ownership_ && pointer_ != nullptr) { + (*meta_.deleteFn())(pointer_); + } + } + + TypeMeta meta_; + void* pointer_{nullptr}; + bool has_ownership_{false}; + + C10_DISABLE_COPY_AND_ASSIGN(Blob); +}; + +inline void swap(Blob& lhs, Blob& rhs) noexcept { + lhs.swap(rhs); +} + +inline std::ostream& operator<<(std::ostream& out, const Blob& v) { + return out << "Blob[" << v.TypeName() << "]"; +} + +} // namespace caffe2 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/BoxedKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/BoxedKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..62b915885a80a99934962bb7582a7ba7b7dd3754 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/BoxedKernel.h @@ -0,0 +1,213 @@ +#pragma once + +#include +#include +#include + +namespace c10 { + +struct IValue; +using Stack = std::vector; + +class OperatorHandle; +class KernelFunction; + +// This kernel implements the behavior of falling through to the next available +// registered dispatch key. The implementation of this function is FAST; it is +// no overhead to fallthrough to the next key. See cpp file for some more +// implementation notes; notably, this does NOT actually go through the +// boxing/unboxing codepath. +TORCH_API void fallthrough_kernel( + OperatorKernel*, + const OperatorHandle&, + DispatchKeySet, + Stack*); + +// Note [Ambiguity in AutogradOther kernel] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// This error-reporting kernel is registered to the AutogradOther entry in the +// dispatch table when there is both a CompositeImplicitAutograd kernel and a +// backend kernel for ANY backend that maps to AutogradOther. To see why +// this is necessary in the AutogradOther case, it's helpful to first see +// why everything works out fine for a backend that has a reserved Autograd +// entry (see rule 2.2 in [Note] DispatchTable computation): +// +// CPU AutogradCPU +// reg? registers with... +// ------------------------------------------------- +// y Autograd registration takes precedence +// over CompositeImplicitAutograd. +// This is good, because the CPU specific backend +// implementation is more specialized and typically better; +// if we used the composite, we would bypass it. +// (NB: the Autograd key is guaranteed to exist because +// the autograd codegen requires it!) +// +// n CompositeImplicitAutograd takes precedence. +// This is also good, because the Autograd +// registration (if it exists) would try to redispatch +// to the (non-existent) CPU implementation; by +// using the composite, we ensure the operator +// actually works. +// +// As you can see, when we have a specific Autograd key (AutogradCPU), we can +// decide whether or not to use the CompositeImplicitAutograd kernel or the +// Autograd kernel based on whether or not the backend kernel exists. +// +// However, for AutogradOther (which is the catchall autograd kernel for +// everything that doesn't have a specific Autograd key), we can't do this +// trick because there isn't any unique backend to peek at to disambiguate; +// if there are some backends that have implementations they prefer Autograd, +// but unimplemented backends would prefer CompositeImplicitAutograd. Rather +// than arbitrarily pick one or the other, we just register a kernel that raises +// an error and let the user decide how to proceed. +TORCH_API void ambiguous_autogradother_kernel( + OperatorKernel*, + const OperatorHandle&, + DispatchKeySet, + Stack*); + +// Note [named_not_supported_kernel] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// This kernel implements reporting an error message saying that named tensor is +// not supported. This kernel doesn't rely on the Stack, and so it is special +// cased in the dispatcher to be triggered before we attempt boxing (so we can +// give a good error message in cases when boxing is not supported). When +// boxing is universally supported this can be removed. +[[noreturn]] TORCH_API void named_not_supported_kernel( + OperatorKernel*, + const OperatorHandle&, + DispatchKeySet, + Stack*); + +/** + * BoxedKernel is similar to a std::function storing a boxed kernel. + */ +class TORCH_API BoxedKernel final { + public: + // This is how boxed kernels are actually stored + // + // Note [Plumbing Keys Through The Dispatcher] + // Benchmarks have shown that it is expensive for the dispatcher to read from + // thread-local storage (TLS) upon every dispatch call into order to compute + // which kernel to dispatch to. + // + // To mitigate this, we've updated the calling convention inside the + // dispatcher to expect every kernel that it stores to have a first argument + // of type DispatchKeySet. + // + // What are the invariants of the DispatchKeySet when it gets passed to a + // kernel? + // - All keys to the left of the current dispatch key have been masked out. + // (e.g. a Tracing kernel that takes in the DispatchKeySet will expect the + // highest bit to be DispatchKey::Tracer) + // - All other keys that dispatcher normally would have computed through TLS + + // global state + op arguments + // are still in the set. + // + // Kernels can then opt into using this keyset to save the dispatcher from + // doing repeated work during redispatches: recalculating the highest-priority + // dispatch key, which involves reading from TLS. Instead, the kernels that + // opt in will calculate an updated DispatchKeySet directly from the old one, + // and pass the updated set directly into the dispatcher upon redispatching. + // + // This is an opt-in mechanism: Kernels can automatically opt in by setting + // the first argument in their signature to be of type DispatchKeySet. See the + // kernels in VariableTypeEverything.cpp and TraceTypeEverything.cpp for + // examples. + // + // The mechanism for optionally passing that DispatchKeySet into the kernel + // lives in make_boxed_from_unboxed_functor.h. See Note [Plumbing Keys Through + // The Dispatcher 2] for details. + using InternalBoxedKernelFunction = + void(OperatorKernel*, const OperatorHandle&, DispatchKeySet, Stack*); + // This is the public API for how boxed kernels are defined + using BoxedKernelFunction = void(const OperatorHandle&, Stack*); + using BoxedKernelFunction_withDispatchKeys = + void(const OperatorHandle&, DispatchKeySet, Stack*); + + BoxedKernel(); + + // Fast path for dispatch to allow not touching the boxed kernel in + // the common case where unboxed is available. + bool isValid() const; + bool isFallthrough() const; + + /** + * Call the function with boxed arguments. + */ + void callBoxed( + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + Stack* stack) const; + + /** + * Create a KernelFunction from a boxed function. + * + * Example: + * + * > void boxed_func(OperatorKernel*, Stack* stack) {...} + * > BoxedFunction func = BoxedKernel::makeFromFunction<&boxed_func>(); + */ + template + static BoxedKernel makeFromFunction(); + + /** + * TODO: This will only be useful if we write a backend fallback that plumbs + * dispatch keys (currently there are none) See Note [Plumbing Keys Through + * The Dispatcher] for details. + */ + template + static BoxedKernel makeFromFunction(); + + /** + * Create a KernelFunction from a boxed functor. + * + * Example: + * + * > class MyFunctor final : public c10::OperatorKernel { + * > public: + * > void operator()(const OperatorHandle&, DispatchKeySet, Stack*) {...} + * > }; + * > BoxedKernel func = + * BoxedKernel::makeFromFunctor(std::make_unique()); + */ + template + static BoxedKernel makeFromFunctor( + std::unique_ptr kernelFunctor); + + static BoxedKernel makeFallthrough(); + static BoxedKernel makeAmbiguousAutogradOther(); + static BoxedKernel makeNamedNotSupported(); + + private: + friend class KernelFunction; + + template + static void make_boxed_function( + OperatorKernel*, + const OperatorHandle& opHandle, + DispatchKeySet, + Stack* stack); + + template + static void make_boxed_function( + OperatorKernel*, + const OperatorHandle& opHandle, + DispatchKeySet, + Stack* stack); + + explicit BoxedKernel( + std::unique_ptr functor, + InternalBoxedKernelFunction* boxed_kernel_func); + + OperatorKernel* getFunctor() const; + InternalBoxedKernelFunction* getFnPtr() const; + + c10::intrusive_ptr functor_; + InternalBoxedKernelFunction* boxed_kernel_func_; +}; + +} // namespace c10 + +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/BoxedKernel_impl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/BoxedKernel_impl.h new file mode 100644 index 0000000000000000000000000000000000000000..1960607c6bc8ea1807d6b16a3eabb39ccc650d11 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/BoxedKernel_impl.h @@ -0,0 +1,106 @@ +#pragma once + +namespace c10 { + +inline BoxedKernel::BoxedKernel() : functor_(), boxed_kernel_func_(nullptr) {} + +inline BoxedKernel::BoxedKernel( + std::unique_ptr functor, + InternalBoxedKernelFunction* boxed_kernel_func) + : functor_(std::move(functor)), boxed_kernel_func_(boxed_kernel_func) {} + +template +inline void BoxedKernel::make_boxed_function( + OperatorKernel*, + const OperatorHandle& opHandle, + DispatchKeySet, + Stack* stack) { + // Note that we're dropping the DispatchKeySet argument. + // See Note [Plumbing Keys Through The Dispatcher 2] for details. + func(opHandle, stack); +} + +template +inline void BoxedKernel::make_boxed_function( + OperatorKernel*, + const OperatorHandle& opHandle, + DispatchKeySet ks, + Stack* stack) { + // See Note [Plumbing Keys Through The Dispatcher 2] for details. + func(opHandle, ks, stack); +} + +inline bool BoxedKernel::isValid() const { + return boxed_kernel_func_ != nullptr; +} + +inline bool BoxedKernel::isFallthrough() const { + return boxed_kernel_func_ == &fallthrough_kernel; +} + +inline void BoxedKernel::callBoxed( + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + Stack* stack) const { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + boxed_kernel_func_ != nullptr, + "Tried to call BoxedKernel::callBoxed() on an uninitialized BoxedKernel."); + (*boxed_kernel_func_)(functor_.get(), opHandle, dispatchKeySet, stack); +} + +template +inline BoxedKernel BoxedKernel::makeFromFunction() { + return BoxedKernel( + nullptr, // no functor_ object + &make_boxed_function); +} + +template +inline BoxedKernel BoxedKernel::makeFromFunction() { + return BoxedKernel( + nullptr, // no functor_ object + &make_boxed_function); +} + +inline BoxedKernel BoxedKernel::makeFallthrough() { + return BoxedKernel( + nullptr, // no functor_ object + &fallthrough_kernel); +} + +inline BoxedKernel BoxedKernel::makeAmbiguousAutogradOther() { + return BoxedKernel( + nullptr, // no functor_ object + &ambiguous_autogradother_kernel); +} + +inline BoxedKernel BoxedKernel::makeNamedNotSupported() { + return BoxedKernel( + nullptr, // no functor_ object + &named_not_supported_kernel); +} + +template +inline BoxedKernel BoxedKernel::makeFromFunctor( + std::unique_ptr kernelFunctor) { + static_assert( + std::is_base_of_v, + "Tried to call BoxedKernel::makeFromFunctor, but the functor doesn't inherit from c10::OperatorKernel. Please have the functor inherit from it."); + return BoxedKernel( + std::move(kernelFunctor), + [](OperatorKernel* kernel, + const OperatorHandle& op, + DispatchKeySet ks, + Stack* stack) { + (*static_cast(kernel))(op, ks, stack); + }); +} + +inline OperatorKernel* BoxedKernel::getFunctor() const { + return functor_.get(); +} +inline BoxedKernel::InternalBoxedKernelFunction* BoxedKernel::getFnPtr() const { + return boxed_kernel_func_; +} + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/KernelFunction.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/KernelFunction.h new file mode 100644 index 0000000000000000000000000000000000000000..06bcc5d4f49b88ad60c7927108c0a906282c84f3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/KernelFunction.h @@ -0,0 +1,283 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include + +namespace c10 { + +using Stack = torch::jit::Stack; // TODO Instead of this, move torch::jit::Stack + // to the c10 namespace. + +class OperatorHandle; +struct OperatorKernel; +class KernelFunction; + +template +using has_symint = std::disjunction< + std::is_same, + std::is_same, + std::is_same, + std::is_same, T>>; + +template +struct remove_symint { + using type = T; +}; + +template <> +struct remove_symint { + using type = int64_t; +}; + +template <> +struct remove_symint { + using type = OptionalIntArrayRef; +}; + +template <> +struct remove_symint { + using type = c10::IntArrayRef; +}; + +template <> +struct remove_symint> { + using type = std::optional; +}; + +template +struct maybe_keep_symint final {}; + +template +struct maybe_keep_symint { + using type = T; +}; + +template +struct maybe_keep_symint { + using type = typename remove_symint::type; +}; + +template +using fn_has_symint = typename guts::typelist::true_for_any_type< + has_symint, + typename guts::infer_function_traits::type::parameter_types>; + +template +struct fn_remove_symint; + +template +struct fn_remove_symint { + using type = Ret(typename remove_symint::type...); +}; + +/** + * KernelFunction is similar to std::function but stores a kernel function. + * You can create a KernelFunction from a boxed or unboxed + * function/functor/lambda and call it in a boxed or unboxed way. If the way it + * was created doesn't match the way it was called, it will do boxing or + * unboxing as necessary. + */ +class TORCH_API KernelFunction final { + public: + using InternalBoxedKernelFunction = BoxedKernel::InternalBoxedKernelFunction; + using BoxedKernelFunction = BoxedKernel::BoxedKernelFunction; + using BoxedKernelFunction_withDispatchKeys = + BoxedKernel::BoxedKernelFunction_withDispatchKeys; + + KernelFunction(); + + // Fast path for dispatch to allow not touching the boxed kernel in + // the common case where unboxed is available. + bool isValidUnboxed() const; + bool isValidSymUnboxed() const; + bool isValid() const; + bool isFallthrough() const; + + /** + * Call the function in a boxed way. + * If the kernel function was created with an unboxed function, + * this will call an unboxing wrapper which then calls into that + * unboxed function. + * + * Example: + * + * > void boxed_func(OperatorKernel*, Stack* stack) {...} + * > KernelFunction func = KernelFunction::makeFromBoxedFunction(&boxed_func); + * > Tensor result = func.callBoxed(stack); + * + * Or, with an unboxed implementation: + * + * > KernelFunction func = KernelFunction::makeFromUnboxedLambda( + * > [] (Tensor a, bool b) -> Tensor {...}); + * > Tensor result = func.callBoxed(stack); + */ + void callBoxed( + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + Stack* stack) const; + + /** + * Call the function in an unboxed way. + * If the kernel function was created with a boxed function, + * this will box all inputs and then call into that boxed function. + * + * Note that this doesn't work for all types yet. + * + * Example: + * + * > KernelFunction func = KernelFunction::makeFromUnboxedLambda( + * > [] (Tensor a, bool b) -> Tensor {...}); + * > Tensor result = func.call(tensor1, true); + * + * Or, with a boxed implementation: + * + * > void boxed_func(OperatorKernel*, Stack* stack) {...} + * > KernelFunction func = KernelFunction::makeFromBoxedFunction(&boxed_func); + * > Tensor result = func.call(tensor1, true); + */ + template + Return call( + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + Args... args) const; + + /** + * Create a KernelFunction from a BoxedKernel. + */ + static KernelFunction makeFromBoxedKernel(BoxedKernel boxed_fn); + + /** + * Create a KernelFunction from a boxed function. + * + * Example: + * + * > void boxed_func(OperatorKernel*, Stack* stack) {...} + * > KernelFunction func = + * KernelFunction::makeFromBoxedFunction<&boxed_func>(); + */ + template + static KernelFunction makeFromBoxedFunction(); + + /** + * TODO: This will only be useful if we write a backend fallback that plumbs + * dispatch keys (currently there are none) See Note [Plumbing Keys Through + * The Dispatcher] for details. + */ + template + static KernelFunction makeFromBoxedFunction(); + + /** + * Create a KernelFunction from an unboxed functor. + * + * Example: + * + * > class MyFunctor final : public c10::OperatorKernel { + * > public: + * > Tensor operator()(Tensor a, Tensor b) {...} + * > }; + * > KernelFunction func = + * KernelFunction::makeFromUnboxedFunctor(std::make_unique()); + */ + template + static KernelFunction makeFromUnboxedFunctor( + std::unique_ptr kernelFunctor); + + /** + * Create a KernelFunction from a boxed functor. + * + * Example: + * + * > class MyFunctor final : public c10::OperatorKernel { + * > public: + * > void operator()(const OperatorHandle&, DispatchKeySet, Stack*) {...} + * > }; + * > KernelFunction func = + * KernelFunction::makeFromBoxedFunctor(std::make_unique()); + */ + template + static KernelFunction makeFromBoxedFunctor( + std::unique_ptr kernelFunctor); + + /** + * Create a KernelFunction from an unboxed function. + * This is usually better than KernelFunction::makeFromUnboxedRuntimeFunction + * because knowing the function pointer as a template argument (i.e. at + * compile time) allows the compiler to inline the function into its + * unboxing wrapper and yields better performance when calling the function. + * + * Example: + * + * > Tensor unboxed_func(Tensor a, Tensor b) {...} + * > KernelFunction func = + * KernelFunction::makeFromUnboxedFunction(); + */ + template + static KernelFunction makeFromUnboxedFunction(FuncPtr); + + /** + * Create a KernelFunction from an unboxed function. + * KernelFunction::makeFromUnboxedFunction is usually a better choice than + * this if you know the function pointer at compile time, see doc comment + * there for an explanation. + * + * Example: + * + * > Tensor unboxed_func(Tensor a, Tensor b) {...} + * > KernelFunction func = + * KernelFunction::makeFromUnboxedRuntimeFunction(&unboxed_func); + */ + template + static KernelFunction makeFromUnboxedRuntimeFunction(FuncType* func); + + static KernelFunction makeFallthrough(); + static KernelFunction makeAmbiguousAutogradOther(); + static KernelFunction makeNamedNotSupported(); + + /** + * Create a KernelFunction from an unboxed lambda. + * + * Example: + * + * > KernelFunction func = KernelFunction::makeFromUnboxedLambda( + * > [] (Tensor a, bool b) -> Tensor {...}); + */ + template + static std::enable_if_t< + guts::is_stateless_lambda>::value, + KernelFunction> + makeFromUnboxedLambda(Lambda&& lambda); + template + static std::enable_if_t< + !guts::is_stateless_lambda>::value, + KernelFunction> + makeFromUnboxedLambda(Lambda&& lambda); + + std::string dumpState() const; + // For testing internal invariants only + bool _equalsBoxedAndUnboxed(const KernelFunction&) const; + + private: + explicit KernelFunction( + std::unique_ptr functor, + InternalBoxedKernelFunction* boxed_kernel_func, + void* unboxed_kernel_func, + void* sym_unboxed_kernel_func); + explicit KernelFunction( + BoxedKernel boxed_fn, + void* unboxed_kernel_func, + void* sym_unboxed_kernel_func); + + BoxedKernel boxed_kernel_func_; + void* unboxed_kernel_func_; + void* sym_unboxed_kernel_func_; +}; + +} // namespace c10 + +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/KernelFunction_impl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/KernelFunction_impl.h new file mode 100644 index 0000000000000000000000000000000000000000..df49d6227ee93ce014ad7b90db0b6cf997061edb --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/KernelFunction_impl.h @@ -0,0 +1,320 @@ +#include +#include +#include +#include + +#include +#include + +namespace c10 { + +namespace detail { +template +std::enable_if_t< + !std::is_array_v && !std::is_array_v && + std::is_base_of_v, + std::unique_ptr> +make_unique_base(Args&&... args) { + return std::unique_ptr(new Child(std::forward(args)...)); +} +} // namespace detail + +inline KernelFunction::KernelFunction() + : boxed_kernel_func_(), + unboxed_kernel_func_(nullptr), + sym_unboxed_kernel_func_(nullptr) {} + +inline KernelFunction::KernelFunction( + std::unique_ptr functor, + InternalBoxedKernelFunction* boxed_kernel_func, + void* unboxed_kernel_func, + void* sym_unboxed_kernel_func = nullptr) + : boxed_kernel_func_(std::move(functor), boxed_kernel_func), + unboxed_kernel_func_(unboxed_kernel_func), + sym_unboxed_kernel_func_(sym_unboxed_kernel_func) {} + +inline KernelFunction::KernelFunction( + BoxedKernel boxed_fn, + void* unboxed_kernel_func, + void* sym_unboxed_kernel_func = nullptr) + : boxed_kernel_func_(std::move(boxed_fn)), + unboxed_kernel_func_(unboxed_kernel_func), + sym_unboxed_kernel_func_(sym_unboxed_kernel_func) {} + +inline bool KernelFunction::isValidUnboxed() const { + return unboxed_kernel_func_ != nullptr; +} + +inline bool KernelFunction::isValidSymUnboxed() const { + return sym_unboxed_kernel_func_ != nullptr; +} + +inline bool KernelFunction::isValid() const { + return boxed_kernel_func_.isValid(); +} + +inline bool KernelFunction::isFallthrough() const { + return boxed_kernel_func_.isFallthrough(); +} + +inline void KernelFunction::callBoxed( + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + Stack* stack) const { + boxed_kernel_func_.callBoxed(opHandle, dispatchKeySet, stack); +} + +template +inline Return callUnboxedKernelFunction( + void* unboxed_kernel_func, + OperatorKernel* functor, + DispatchKeySet dispatchKeySet, + Args&&... args) { + using ActualSignature = Return(OperatorKernel*, DispatchKeySet, Args...); + ActualSignature* func = + reinterpret_cast(unboxed_kernel_func); + return (*func)(functor, dispatchKeySet, std::forward(args)...); +} + +// This template requires you to explicitly specify the argument you want to +// forward; it doesn't work if you try to deduce it +// NB: keep this in sync with cloneWithRealTypes in function_schema.cpp + +template +inline typename remove_symint::type unpackSymInt(T x) { + return x; +} + +template <> +inline typename remove_symint::type unpackSymInt(c10::SymInt x) { + return x.guard_int(__FILE__, __LINE__); +} + +template <> +inline typename remove_symint::type unpackSymInt( + c10::SymIntArrayRef x) { + return C10_AS_INTARRAYREF_SLOW(x); +} + +template <> +inline typename remove_symint>::type unpackSymInt( + std::optional x) { + return x.has_value() ? std::make_optional(x->guard_int(__FILE__, __LINE__)) + : std::nullopt; +} + +template <> +inline typename remove_symint::type unpackSymInt( + at::OptionalSymIntArrayRef x) { + return x.has_value() ? std::make_optional(C10_AS_INTARRAYREF_SLOW(*x)) + : std::nullopt; +} + +template +C10_ALWAYS_INLINE Return KernelFunction::call( + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + Args... args) const { + // note: Args above is intentionally not Args&&. We don't want perfect + // forwarding, which would require Args to be deduced, but instead we + // want callers to explicitly specify the Args. + + if constexpr (std::disjunction_v...>) { + if (sym_unboxed_kernel_func_ != nullptr) { + auto* functor = boxed_kernel_func_.getFunctor(); + return callUnboxedKernelFunction( + sym_unboxed_kernel_func_, + functor, + dispatchKeySet, + std::forward(args)...); + } + + if (unboxed_kernel_func_ != nullptr) { + auto* functor = boxed_kernel_func_.getFunctor(); + return callUnboxedKernelFunction< + Return, + typename remove_symint::type...>( + unboxed_kernel_func_, + functor, + dispatchKeySet, + unpackSymInt(args)...); + } + } else { + if (C10_LIKELY(unboxed_kernel_func_ != nullptr)) { + auto* functor = boxed_kernel_func_.getFunctor(); + return callUnboxedKernelFunction( + unboxed_kernel_func_, + functor, + dispatchKeySet, + std::forward(args)...); + } + } + + return impl::BoxedKernelWrapper::call( + boxed_kernel_func_, + opHandle, + dispatchKeySet, + std::forward(args)...); +} + +inline KernelFunction KernelFunction::makeFromBoxedKernel( + BoxedKernel boxed_fn) { + return KernelFunction( + std::move(boxed_fn), nullptr); // no unboxed function pointer +} + +template +inline KernelFunction KernelFunction::makeFromBoxedFunction() { + return KernelFunction::makeFromBoxedKernel( + BoxedKernel::makeFromFunction()); +} + +template +inline KernelFunction KernelFunction::makeFromBoxedFunction() { + return KernelFunction::makeFromBoxedKernel( + BoxedKernel::makeFromFunction()); +} + +inline KernelFunction KernelFunction::makeFallthrough() { + return KernelFunction::makeFromBoxedKernel(BoxedKernel::makeFallthrough()); +} + +inline KernelFunction KernelFunction::makeAmbiguousAutogradOther() { + return KernelFunction::makeFromBoxedKernel( + BoxedKernel::makeAmbiguousAutogradOther()); +} + +inline KernelFunction KernelFunction::makeNamedNotSupported() { + return KernelFunction::makeFromBoxedKernel( + BoxedKernel::makeNamedNotSupported()); +} + +template +inline KernelFunction KernelFunction::makeFromUnboxedFunctor( + std::unique_ptr kernelFunctor) { +#ifndef NDEBUG + // This assertion is costly for build time so it's debug-gated. + static_assert( + guts::is_functor::value, + "Tried to call KernelFunction::makeFromUnboxedFunctor but the argument is not a functor."); +#endif + static_assert( + std::is_base_of_v, + "Tried to call KernelFunction::makeFromUnboxedFunctor, but the functor doesn't inherit from c10::OperatorKernel. Please have the functor inherit from it."); + + auto* unboxed_fn = &impl::wrap_kernel_functor_unboxed::call; + void* void_unboxed_fn = reinterpret_cast(unboxed_fn); + bool is_symint = fn_has_symint::value; + return KernelFunction( + std::move(kernelFunctor), + &impl::make_boxed_from_unboxed_functor:: + call, + is_symint ? nullptr : void_unboxed_fn, + is_symint ? void_unboxed_fn : nullptr); +} + +template +inline KernelFunction KernelFunction::makeFromBoxedFunctor( + std::unique_ptr kernelFunctor) { + return KernelFunction::makeFromBoxedKernel( + BoxedKernel::makeFromFunctor(std::move(kernelFunctor))); +} + +template +inline KernelFunction KernelFunction::makeFromUnboxedFunction( + FuncPtr func_ptr) { + static_assert( + is_compile_time_function_pointer::value, + "Tried to call KernelFunction::makeFromUnboxedFunction with an invalid parameter. It must be a function pointer created with TORCH_FN."); + static_assert( + !std::is_same_v, + "Tried to call KernelFunction::makeFromUnboxedFunction with a boxed function pointer. Please use KernelFunction::makeFromBoxedFunction instead."); +#if defined(__GNUC__) && defined(__SANITIZE_ADDRESS__) && !defined(__CUDACC__) + TORCH_INTERNAL_ASSERT( + FuncPtr::func_ptr() != nullptr, "Kernel function cannot be nullptr"); +#else + static_assert( + FuncPtr::func_ptr() != nullptr, "Kernel function cannot be nullptr"); +#endif + +#if !defined(C10_MOBILE) + (void)func_ptr; // Suppress unused variable warning + return makeFromUnboxedFunctor< + AllowLegacyTypes, + typename impl::WrapFunctionIntoFunctor::type>( + detail::make_unique_base< + OperatorKernel, + typename impl::WrapFunctionIntoFunctor::type>()); +#else + // On mobile, we rather want to optimize for binary size than for performance, + // so let's not inline the kernel into the wrapper but use + // makeFromUnboxedRuntimeFunction instead. + return makeFromUnboxedRuntimeFunction(func_ptr.func_ptr()); +#endif +} + +template +inline KernelFunction KernelFunction::makeFromUnboxedRuntimeFunction( + FuncType* func) { + static_assert( + guts::is_function_type::value, + "Tried to call KernelFunction::makeFromUnboxedRuntimeFunction with a non-function type."); + static_assert( + !std::is_same_v, + "Tried to call KernelFunction::makeFromUnboxedRuntimeFunction with a boxed function pointer. Please use KernelFunction::makeFromBoxedFunction instead."); + TORCH_INTERNAL_ASSERT(func != nullptr, "Kernel function cannot be nullptr"); + + return makeFromUnboxedFunctor< + AllowLegacyTypes, + impl::WrapFunctionIntoRuntimeFunctor>>( + detail::make_unique_base< + OperatorKernel, + impl::WrapFunctionIntoRuntimeFunctor>>(func)); +} + +template +inline std::enable_if_t< + guts::is_stateless_lambda>::value, + KernelFunction> +KernelFunction::makeFromUnboxedLambda(Lambda&& lambda) { + static_assert( + guts::is_functor>::value, + "Tried to call KernelFunction::makeFromUnboxedLambda with a non-lambda type."); + +#if !defined(C10_MOBILE) + return makeFromUnboxedFunctor< + AllowLegacyTypes, + impl::WrapFunctionIntoRuntimeFunctor>>( + detail::make_unique_base< + OperatorKernel, + impl::WrapFunctionIntoRuntimeFunctor>>( + std::forward(lambda))); +#else + // On mobile, we rather want to optimize for binary size than for performance, + // so let's not inline the kernel into the wrapper but use + // makeFromUnboxedRuntimeFunction instead. + using FuncType = + typename guts::infer_function_traits_t>::func_type; + return makeFromUnboxedRuntimeFunction(lambda); +#endif +} + +template +inline std::enable_if_t< + !guts::is_stateless_lambda>::value, + KernelFunction> +KernelFunction::makeFromUnboxedLambda(Lambda&& lambda) { + static_assert( + guts::is_functor>::value, + "Tried to call KernelFunction::makeFromUnboxedLambda with a non-lambda type."); + + return makeFromUnboxedFunctor< + AllowLegacyTypes, + impl::WrapFunctionIntoRuntimeFunctor>>( + detail::make_unique_base< + OperatorKernel, + impl::WrapFunctionIntoRuntimeFunctor>>( + std::forward(lambda))); +} + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/OperatorKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/OperatorKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..2d0620fa0d9f1257bf36b3a4c6962e97a07e64c7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/OperatorKernel.h @@ -0,0 +1,27 @@ +#pragma once +#include + +namespace c10 { + +/** + * Inherit from OperatorKernel to implement a c10 kernel. + * + * Example: + * > namespace { + * > class my_kernel_cpu final : public c10::OperatorKernel { + * > public: + * > Tensor operator()(Tensor a, Tensor b) {...} + * > }; + * > } + * + * The kernel class is allowed to have members but these are equivalent + * to global variables. The kernel implementation is responsible for + * preventing race conditions on them. + * + * See below for how to register this kernel with PyTorch. + */ +struct TORCH_API OperatorKernel : public c10::intrusive_ptr_target { + ~OperatorKernel() override = default; +}; + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/WrapFunctionIntoFunctor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/WrapFunctionIntoFunctor.h new file mode 100644 index 0000000000000000000000000000000000000000..8b81ae4e517df706c96f286e49f40357c6abf7d3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/WrapFunctionIntoFunctor.h @@ -0,0 +1,38 @@ +#pragma once + +#include + +namespace c10::impl { +namespace detail { +template +class WrapFunctionIntoFunctor_ {}; +template +class WrapFunctionIntoFunctor_< + FuncPtr, + ReturnType, + guts::typelist::typelist> + final : public c10::OperatorKernel { + public: + C10_ALWAYS_INLINE decltype(auto) operator()(Parameters... args) { + return (*FuncPtr::func_ptr())(std::forward(args)...); + } +}; +} // namespace detail + +// WrapFunctionIntoFunctor: Wraps a compile time function pointer into a kernel +// functor. Since it is a compile time function pointer, many compilers can +// inline it into the wrapper and you don't get any performance overhead for +// wrapping. +template +struct WrapFunctionIntoFunctor final { + static_assert( + c10::is_compile_time_function_pointer::value, + "WrapFunctionIntoFunctor can only wrap functions created with TORCH_FN."); + using type = detail::WrapFunctionIntoFunctor_< + FuncPtr, + typename guts::function_traits::return_type, + typename guts::function_traits< + typename FuncPtr::FuncType>::parameter_types>; +}; + +} // namespace c10::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/WrapFunctionIntoRuntimeFunctor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/WrapFunctionIntoRuntimeFunctor.h new file mode 100644 index 0000000000000000000000000000000000000000..c5609eada7af3e54c5f36002895a782c340ff51d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/WrapFunctionIntoRuntimeFunctor.h @@ -0,0 +1,41 @@ +#pragma once + +#include + +namespace c10::impl { + +namespace detail { +template +class WrapFunctionIntoRuntimeFunctor_ {}; +template +class WrapFunctionIntoRuntimeFunctor_< + FuncType, + ReturnType, + guts::typelist::typelist> + final : public c10::OperatorKernel { + public: + template + explicit WrapFunctionIntoRuntimeFunctor_(FuncType_&& kernel_func) + : kernel_func_(std::forward(kernel_func)) {} + + decltype(auto) operator()(Parameters... args) { + return kernel_func_(std::forward(args)...); + } + + private: + FuncType kernel_func_; +}; +} // namespace detail + +// WrapFunctionIntoRuntimeFunctor: Wraps any runtime functor into a functor that +// inherits from c10::OperatorKernel, so it can be used as a c10 kernel. +// This can, for example, be used for lambdas, functors or even function +// pointers. In the case of function pointers, since it is a runtime function +// pointer, there is an overhead for calling it whenever the kernel is invoked. +template +using WrapFunctionIntoRuntimeFunctor = detail::WrapFunctionIntoRuntimeFunctor_< + FuncType, + typename guts::infer_function_traits_t::return_type, + typename guts::infer_function_traits_t::parameter_types>; + +} // namespace c10::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/boxing.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/boxing.h new file mode 100644 index 0000000000000000000000000000000000000000..68e25cccd44c87f30de9052832c0ea0ceb5aa40c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/boxing.h @@ -0,0 +1,410 @@ +#pragma once + +// This file contains boxing (not unboxing) logic, +// i.e. how to make a vector from a set of concrete arguments. + +#include +#include +#include + +#include + +#include +#include + +namespace c10::impl { + +// +// utils +// + +// is_mutable_tensor_ref +template +struct is_mutable_tensor_ref : std::false_type {}; +template <> +struct is_mutable_tensor_ref : std::true_type {}; + +// is_tuple_of_mutable_tensor_refs +// +template +struct is_tuple_of_mutable_tensor_refs : std::false_type {}; + +template +struct is_tuple_of_mutable_tensor_refs< + T, + std::enable_if_t::value, void>> + : guts::typelist:: + all> {}; + +// has_ivalue_to tests the presence/absence of instance method +// IValue::to() +// +template +struct has_ivalue_to : std::false_type {}; + +template +struct ivalue_to_helper { + using type = decltype(std::declval().template to()); +}; +template +using ivalue_to_helper_t = typename ivalue_to_helper::type; + +template +struct has_ivalue_to>> : std::true_type {}; + +// +// boxing predicates +// + +// A boxable arg type is one that IValue has a constructor for. +template +using can_box = std::disjunction< + std::is_constructible>, + // TensorOptions are not directly constructible into IValue, + // but torch::jit::push knows how to handle them + std::is_same>>; + +template +using can_box_all = std::conjunction...>; + +// an unboxable result is one that can be extracted from an IValue +template +using can_unbox = std::conjunction< + std::disjunction< + has_ivalue_to, + // void returns are ok + std::is_same>, + std::negation>>; + +// +// boxArgs - utility for pushing unboxed args onto IValue stack +// +template +torch::jit::Stack boxArgs(Args... args) { + // TODO Reuse stack vector instead of allocating? + torch::jit::Stack stack; + stack.reserve(sizeof...(Args)); + torch::jit::push(stack, std::forward(args)...); + return stack; +} + +template +inline constexpr size_t boxed_size_one() { + static_assert( + !std::is_same_v, c10::TensorOptions>, + "need to patch this path to support TensorOptions passed by reference"); + return 1; +} + +// torch::jit::push pushes 4 values for a TensorOptions; this needs to +// be kept in sync. +template <> +inline constexpr size_t boxed_size_one() { + return 4; +} + +// NOTE: this could probably be simplified with C++17 fold expressions. +template +struct BoxedSize : std::integral_constant {}; +template +struct BoxedSize + : std::integral_constant< + size_t, + boxed_size_one() + BoxedSize::value> {}; + +template +static inline constexpr size_t boxed_size() { + return BoxedSize::value; +} + +template +C10_ALWAYS_INLINE_UNLESS_MOBILE void boxToStack(IValue*& dest, T& arg) { + new (dest++) IValue(arg); +} + +C10_ALWAYS_INLINE_UNLESS_MOBILE void boxToStack( + IValue*& dest, + c10::TensorOptions options) { + new (dest++) IValue(c10::typeMetaToScalarType(options.dtype())); + new (dest++) IValue(options.layout()); + new (dest++) IValue(options.device()); + new (dest++) IValue(options.pinned_memory()); +} + +inline void boxArgsToStack(IValue*&) {} + +template +C10_ALWAYS_INLINE_UNLESS_MOBILE void boxArgsToStack( + IValue*& dest, + T& arg, + Args&... args) { + boxToStack(dest, arg); + boxArgsToStack(dest, args...); +} + +// +// PopResult is a helper class whose specializations handle popping single and +// multiple return values, respectively. +// +template +struct PopResult final { + static Result call(Stack& stack) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + stack.size() == 1, + "Boxed kernel was expected to return one value on the stack, ", + "but instead pushed ", + stack.size(), + " values."); + return std::move(stack[0]).to(); + } +}; + +template +struct PopResult> final { + using Result = std::tuple; + + static Result call(Stack& stack) { + // for tuple return types, boxed kernel has pushed multiple values onto the + // stack + constexpr int RetCount = sizeof...(Types); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + stack.size() == RetCount, + "Boxed kernel was expected to return ", + RetCount, + " values on the stack, ", + "but instead pushed ", + stack.size(), + " values."); + return pop_to_tuple_impl(stack, std::make_index_sequence()); + } + + private: + // note: this has been moved into its own helper only to avoid a parse error + // on `indices` otherwise. I'm sure there's an incantation that slips it past + // the parser but eh + template + static Result pop_to_tuple_impl( + Stack& stack, + std::index_sequence) { + return std::make_tuple((std::move(stack[indices]).template to())...); + } +}; + +// +// BoxedKernelWrapper +// +// For a given function type FT, BoxedKernelWrapper implements +// a `call` method that +// - takes a boxed kernel and unboxed arguments as specified by FT, +// - calls `boxArgs` to box the arguments +// - calls the boxed kernel +// - unboxes and returns the result +// +// The partial specializations below handle various cases: in +// particular, not all types appearing in op signatures are supported, +// and ops returning references have nonstandard wrapper implementations. +// + +// 1. The base specialization of BoxedKernelWrapper should never be +// instantiated. A "no call method defined on BoxedKernelWrapper" compile error +// means that an op signature has failed to trigger any of the partial +// specializations that follow this one. +// +template +struct BoxedKernelWrapper { + // The reason we're not just doing straight up static_assert(false, ...) here: + // Basically, the way to make sure a static_assert only fires if a template + // is actually instantiated (rather than every time the file is parsed) is to + // use template parameters in the expression, e.g. FuncType here. However, + // since `sizeof(FuncType) != sizeof(FuncType)` is always false, this has the + // same effect. + static_assert( + sizeof(FuncType) != sizeof(FuncType), + "Function signature contains one or more unsupported parameter and/or return types. " + "Look for a nearby error like " + "\"'call' is not a member of 'c10::impl::BoxedKernelWrapper<(your function type), void>'\" " + "- (your function type) is the unsupported signature."); +}; + +// +// 2. Supported signatures, other than those involving non-const Tensor refs - +// i.e., "functional" ops. +// + +template +struct BoxedKernelWrapper< + Result(Args...), + std::enable_if_t< + can_box_all::value && can_unbox::value && + !is_tuple_of_mutable_tensor_refs::value, + void>> { + static Result call( + const BoxedKernel& boxed_kernel_func, + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + Args... args) { + torch::jit::Stack stack = boxArgs(std::forward(args)...); + boxed_kernel_func.callBoxed(opHandle, dispatchKeySet, &stack); + + if constexpr (!std::is_same_v) { + // op has pushed one or more values onto the stack. + return PopResult::call(stack); + } else { + // op returns void, boxed kernel has pushed nothing onto stack. + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + stack.empty(), + "Boxed kernel was expected to return no values on the stack, ", + "but instead returned ", + stack.size(), + " values."); + } + } +}; + +// +// 3. in-place ops take a single non-const Tensor reference +// as their first argument, and return it. +// +// Note: all signatures matching this pattern are assumed to be for such ops. +// Because of this, the generated BoxedKernelWrapper specializations simply +// return the in-place argument. +// + +template +struct BoxedKernelWrapper< + at::Tensor&(at::Tensor&, OtherArgs...), + std::enable_if_t::value, void>> { + static at::Tensor& call( + const BoxedKernel& boxed_kernel_func, + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + at::Tensor& outArg, + OtherArgs... otherArgs) { + torch::jit::Stack stack = boxArgs( + outArg, std::forward(otherArgs)...); + boxed_kernel_func.callBoxed(opHandle, dispatchKeySet, &stack); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + stack.size() == 1, + "Boxed kernel was expected to return a single value on the stack, ", + "but instead returned ", + stack.size(), + " values."); + + return outArg; + } +}; + +// +// 3.5. In-process migration to make in-place ops take and return +// const references instead. +template +struct BoxedKernelWrapper< + const at::Tensor&(const at::Tensor&, OtherArgs...), + std::enable_if_t::value, void>> { + static const at::Tensor& call( + const BoxedKernel& boxed_kernel_func, + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + const at::Tensor& outArg, + OtherArgs... otherArgs) { + torch::jit::Stack stack = boxArgs(outArg, otherArgs...); + boxed_kernel_func.callBoxed(opHandle, dispatchKeySet, &stack); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + stack.size() == 1, + "Boxed kernel was expected to return a single value on the stack, ", + "but instead returned ", + stack.size(), + " values."); + + return outArg; + } +}; + +// +// 4. out of place ops that take a single non-const Tensor reference as their +// final argument, and also return it. +// +// Note: all signatures matching this pattern are assumed to be for such ops. +// This assumption permits the generated BoxedKernelWrapper specializations to +// simply return out arguments. +// +template +struct BoxedKernelWrapper< + at::Tensor&(FirstArg, RestArgs...), + std::enable_if_t< + can_box_all::value + // this skips over in-place kernels with a non-const Tensor + // arg at the front, so those can unambiguously trigger the + // preceding specialization. + && !is_mutable_tensor_ref::value, + void>> { + static at::Tensor& call( + const BoxedKernel& boxed_kernel_func, + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + FirstArg firstArg, + RestArgs... restArgs) { + torch::jit::Stack stack = boxArgs( + std::forward(firstArg), std::forward(restArgs)...); + boxed_kernel_func.callBoxed(opHandle, dispatchKeySet, &stack); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + stack.size() == 1, + "Boxed kernel was expected to return a single value on the stack, ", + "but instead returned ", + stack.size(), + " values."); + + // reusing restArgs after it has been forwarded here is ok because we know + // that the last element is of type `Tensor&`. + return std::get( + std::tuple{restArgs...}); + } +}; + +// +// 5. out of place ops that take multiple non-const Tensor references as their +// final arguments, and return them in a std::tuple. +// +// Note: all signatures matching this pattern are assumed to be for such ops. +// This assumption permits the generated BoxedKernelWrapper specializations to +// simply return the out arguments. +// +template +struct BoxedKernelWrapper< + Result(Args...), + std::enable_if_t< + can_box_all::value && + is_tuple_of_mutable_tensor_refs::value, + void>> { + static Result call( + const BoxedKernel& boxed_kernel_func, + const OperatorHandle& opHandle, + DispatchKeySet dispatchKeySet, + Args... args) { + using ArgTuple = std::tuple; + constexpr int RetCount = std::tuple_size(); + + torch::jit::Stack stack = boxArgs(std::forward(args)...); + boxed_kernel_func.callBoxed(opHandle, dispatchKeySet, &stack); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + stack.size() == RetCount, + "Boxed kernel was expected to return ", + RetCount, + " values on the stack, ", + "but instead returned ", + stack.size(), + " values."); + + // reusing args after it has been forwarded here is ok because we know + // that the last RetCount elements are of type `Tensor&`. + auto result = guts::tuple_take( + ArgTuple{std::forward(args)...}); + static_assert( + std::is_same_v, + "The parameter list of an op returning a tuple of Tensor references " + "must end with an equal number of Tensor reference parameters."); + return result; + } +}; + +} // namespace c10::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/make_boxed_from_unboxed_functor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/make_boxed_from_unboxed_functor.h new file mode 100644 index 0000000000000000000000000000000000000000..e67d1badc9a46504c3fdfe080ae2591d3960d650 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/make_boxed_from_unboxed_functor.h @@ -0,0 +1,785 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include + +#include + +namespace c10 { + +using Stack = torch::jit::Stack; // TODO Instead of this, move torch::jit::Stack + // to the c10 namespace. +class OperatorHandle; + +/* + * [Note: Argument forwarding in the dispatcher] + * + * The dispatcher uses a somewhat unusual way to forward arguments through + * several layers of wrapper functions. This can be confusing because an + * experienced C++ programmer would look at this and think "oh this is supposed + * to be forwarding a universal reference but the && is missing. This is a + * bug.". It is not a bug. The common way in C++ to forward arguments is to use + * universal references: + * + * > template void func(T&& arg) { func2(std::forward(arg)); } + * + * but that relies on inferring the correct reference type (i.e. value vs & vs + * &&) from the argument. In our case, we cannot rely on the argument as + * supplied by the caller, because that could infer a different reference type + * than was used in the kernel function. The correct reference type is dictated + * by the kernel signature and must be identical since we cast function pointers + * through void* pointers and mismatches would be UB. So we need a forwarding + * pattern that determines the reference type to use by looking at the + * explicitly supplied operator signature, not by looking at the argument we're + * calling it with. + * + * What does std::forward do, exactly? + * ------------------------------------ + * std::forward(t) is a way to cast t to the reference type supplied in T. + * Let's assume decay_t == U and T is either U or some reference of U. + * - std::forward(t) will return U&, no matter what kind of reference t is. + * - std::forward(t) will return U&&, no matter what kind of reference t + * is. + * - std::forward(t) will return U&& (not U!), no matter what kind of + * reference t is. + * + * For universal references, that means that in the following function + * > template void func(T&& arg) { func2(std::forward(arg)); } + * + * - when called with arg being a rvalue reference or non-reference value, T + * gets inferred to be a non-reference U, and std::forward(t) will return + * U&&, correctly moving the argument. + * - when called with arg behind a lvalue reference, T gets inferred to be U& + * because that's the only way to match the signature (in C++, a type that is + * (T&)&& will collapse to T&). That means std::forward(t) will return U& and + * the value will not be moved but passed on as a lvalue reference. + * + * How do we use that? + * ------------------------------------ + * But std::forward can also be used outside of the common "universal + * forwarding" pattern to change reference types. So instead of following the + * common C++ pattern, we notice what std::forward() actually does, and that + * is it takes a value and changes its reference to the type of reference passed + * in as T. If we don't infer T but explicitly specify it, we can use this to + * forward based on an explicitly specified reference type instead of the + * inferred argument type. + * + * This is why many of the dispatcher functions look like + * > template func(T t) { func2(std::forward(t)); } + * instead of the common + * > template func(T&& t) { func2(std::forward(t)); } + * + * and are expected to be called by explicitly specifying the template + * parameters in a way that matches the expected operator signature at each call + * site. + */ + +namespace impl { +// supported_primitive_arg_types defines which primitive types we allow in +// kernel functions as arguments or returns. +// Additionally, we support lists, dicts and optionals containing these types. +using supported_primitive_arg_types = guts::typelist::typelist< + int64_t, + double, + bool, + std::string_view, + at::Tensor, + at::Scalar, + c10::QScheme, + c10::ScalarType, + c10::Device, + c10::DeviceIndex, + c10::Layout, + c10::MemoryFormat, + at::Dimname>; + +// We have an unboxed functor in hand that takes C++ arguments, and +// we're building a boxed functor wrapper for it that takes IValues. +// So "outside" is boxed and "inside" is unboxed. +// +// So a valid input type is one that our boxed functor wrapper can +// unbox from an IValue into a C++ value. +// +// Whereas a valid output type is one that our wrapper can recieve +// as a C++ value from the unboxed functor, and box into an IValue. + +// +// assert_is_valid_input_type +// checks that T can be unboxed from an IValue into a C++ value. +// + +template +struct assert_is_valid_input_type { + assert_is_valid_input_type() { + if constexpr (guts::typelist::contains:: + value) { + /* everything is ok, this is a primitive type */ + } else { + /* otherwise this must be an instance of a valid custom class, since it + can only have been created via IValue(x), which ensures this. */ + } + } +}; + +template +struct assert_is_valid_input_type, AllowDeprecatedTypes> + : assert_is_valid_input_type {}; + +template +struct TypeCheckHelper; + +template +struct TypeCheckHelper {}; + +template +struct TypeCheckHelper + : TypeCheckHelper { + assert_is_valid_input_type check; +}; + +template +struct assert_is_valid_input_type< + std::tuple, + AllowDeprecatedTypes> + : TypeCheckHelper {}; + +template +struct assert_is_valid_input_type, AllowDeprecatedTypes> + : assert_is_valid_input_type { + static_assert( + guts::typelist::contains::value, + "You tried to register a kernel with an unsupported input type: Dict where Key is invalid. We only support int64_t, double, bool, and string."); +}; + +template +struct assert_is_valid_input_type< + std::unordered_map, + AllowDeprecatedTypes> + : assert_is_valid_input_type { + static_assert( + AllowDeprecatedTypes, + "You tried to register a kernel with an unsupported input type: std::unordered_map. Please use Dict instead."); + static_assert( + guts::typelist::contains::value, + "You tried to register a kernel with an unsupported input type: std::unordered_map where Key is invalid. We only support int64_t, double, bool, and string."); +}; + +template +struct assert_is_valid_input_type, AllowDeprecatedTypes> + : assert_is_valid_input_type { + static_assert( + !std::is_same_v, + "You tried to register a kernel with an unsupported input type: List. Please use List, List or Tensor instead."); +}; + +template +struct assert_is_valid_input_type, AllowDeprecatedTypes> + : assert_is_valid_input_type { + static_assert( + !std::is_same_v, + "You tried to register a kernel with an unsupported input type: ArrayRef. Please use List, List or Tensor instead."); +}; + +template +struct assert_is_valid_input_type< + c10::OptionalArrayRef, + AllowDeprecatedTypes> + : assert_is_valid_input_type { + static_assert( + !std::is_same_v, + "You tried to register a kernel with an unsupported input type: OptionalArrayRef. Please use List, List or Tensor instead."); +}; + +template +struct assert_is_valid_input_type, AllowDeprecatedTypes> + : assert_is_valid_input_type { + static_assert( + !std::is_same_v, + "You tried to register a kernel with an unsupported input type: std::array. Please use std::array instead."); +}; + +template +struct assert_is_valid_input_type< + T, + AllowDeprecatedTypes, + std::enable_if_t>> { + // There is no reason to support float when we have double. Keep the API lean. + static_assert( + guts::false_t::value, + "You tried to register a kernel with an unsupported input type: float. Please use double instead; you should use `double` in the C++ function signature and `float` in the schema string."); +}; +template +struct assert_is_valid_input_type< + T, + AllowDeprecatedTypes, + std::enable_if_t>> { + static_assert( + guts::false_t::value, + "You tried to register a kernel with an unsupported input type: const char*. Please use std::string_view instead."); +}; +template +struct assert_is_valid_input_type< + T, + AllowDeprecatedTypes, + std::enable_if_t, T>>> { + static_assert( + guts::false_t::value, + "You tried to register a kernel with an unsupported input type: vector. Please use List instead."); +}; +template +struct assert_is_valid_input_type< + T, + AllowDeprecatedTypes, + std::enable_if_t< + std::is_integral_v && + !guts::typelist::contains::value>> { + static_assert( + guts::false_t::value, + "You tried to register a kernel with an unsupported integral input type. Please use int64_t instead; you should use `int64_t` in the C++ function signature and `int` in the schema string."); +}; +template +struct assert_is_valid_input_type< + T, + AllowDeprecatedTypes, + std::enable_if_t>> { + static_assert( + guts::false_t::value, + "You tried to register a kernel taking c10::SymInt by reference. Please accept it by value instead."); +}; + +// TODO: it probably would be good to tighten this up quite a bit more with +// an explicit list for everything + +// +// assert_is_valid_output_type +// + +template +struct assert_is_valid_output_type { + assert_is_valid_output_type() { + if constexpr (guts::typelist::contains:: + value) { + /* everything is ok, this is a primitive type */ + } else { + /* otherwise T is verified to be a registered custom class in the IValue + constructor, so no benefit in double-checking here */ + } + } +}; + +template +struct assert_is_valid_output_type, AllowDeprecatedTypes> + : assert_is_valid_output_type {}; + +template +struct assert_is_valid_output_type< + c10::OptionalArrayRef, + AllowDeprecatedTypes> + : assert_is_valid_output_type {}; + +template +struct assert_is_valid_output_type, AllowDeprecatedTypes> + : assert_is_valid_output_type { + static_assert( + guts::typelist::contains::value, + "You tried to register a kernel with an unsupported output type: Dict where Key is invalid. We only support int64_t, double, bool, and string."); + static_assert( + !std::is_same_v, + "You tried to register a kernel with an unsupported output type: Dict. Please use Dict or Dict."); +}; + +template +struct assert_is_valid_output_type< + std::unordered_map, + AllowDeprecatedTypes> + : assert_is_valid_output_type { + static_assert( + AllowDeprecatedTypes, + "You tried to register a kernel with an unsupported output type: std::unordered_map. Please use Dict instead."); + static_assert( + guts::typelist::contains::value, + "You tried to register a kernel with an unsupported output type: std::unordered_map where Key is invalid. We only support int64_t, double, bool, and string."); + static_assert( + !std::is_same_v, + "You tried to register a kernel with an unsupported output type: std::unordered_map. Please use Dict or Dict."); +}; + +template +struct assert_is_valid_output_type, AllowDeprecatedTypes> + : assert_is_valid_output_type { + static_assert( + !std::is_same_v, + "You tried to register a kernel with an unsupported output type: List. Please use List, List or Tensor instead."); +}; + +template +struct assert_is_valid_output_type, AllowDeprecatedTypes> + : assert_is_valid_output_type { + static_assert( + !std::is_same_v, + "You tried to register a kernel with an unsupported output type: std::vector. Please use List, List or Tensor instead."); + // TODO static_assert(AllowDeprecatedTypes, "You tried to register a kernel + // with an unsupported output type: std::vector. Please use List + // instead."); +}; + +template +struct assert_is_valid_output_type, AllowDeprecatedTypes> + : assert_is_valid_output_type { + static_assert( + !std::is_same_v, + "You tried to register a kernel with an unsupported output type: std::array. Please use std::array instead."); +}; + +// The following specialisations of assert_is_valid_output_type are technically +// not necessary since we would hit the base case and show an error message +// there if they didn't exist, but we can show a better error message +// in some common error scenarios. +template +struct assert_is_valid_output_type< + T, + AllowDeprecatedTypes, + std::enable_if_t>> { + // There is no reason to support float when we have double. Keep the API lean. + static_assert( + guts::false_t::value, + "You tried to register a kernel with an unsupported output type: float. Please use double instead; you should use `double` in the C++ function signature and `float` in the schema string."); +}; +template +struct assert_is_valid_output_type< + T, + AllowDeprecatedTypes, + std::enable_if_t>> { + static_assert( + guts::false_t::value, + "You tried to register a kernel with an unsupported output type: const char*. Please use std::string_view instead."); +}; +template +struct assert_is_valid_output_type< + T, + AllowDeprecatedTypes, + std::enable_if_t, T>>> { + static_assert( + guts::false_t::value, + "You tried to register a kernel with an unsupported output type: vector. Please use List instead."); +}; +template +struct assert_is_valid_output_type< + T, + AllowDeprecatedTypes, + std::enable_if_t< + std::is_integral_v && + !guts::typelist::contains::value>> { + static_assert( + guts::false_t::value, + "You tried to register a kernel with an unsupported integral output type. Please use int64_t instead; you should use `int64_t` in the C++ function signature and `int` in the schema string."); +}; + +// ivalue_to_arg + +template +struct decay_if_not_tensor final { + using type = std::decay_t; +}; + +template <> +struct decay_if_not_tensor final { + using type = at::Tensor&; +}; + +template <> +struct decay_if_not_tensor final { + using type = const at::Tensor&; +}; + +template +struct ivalue_to_arg final { + static decltype(auto) call(IValue& v) { + assert_is_valid_input_type(); + return std::move(v).to(); + } +}; + +// The following two specializations take advantage of specialized +// `toTensor()` overloads on IValue to avoid copying. +template +struct ivalue_to_arg final { + // We cannot use the default implementation if they asked for a + // `at::Tensor&` because it moves from the IValue, so it can't get + // an lvalue reference. + static at::Tensor& call(IValue& v) { + // Tensor& is valid, don't bother asserting + return v.toTensor(); + } +}; + +template +struct ivalue_to_arg final { + // We should not use the default implementation if they asked for + // a `const at::Tensor&` because it moves from the IValue and they + // didn't ask for that. + static const at::Tensor& call(IValue& v) { + // const Tensor& is valid, don't bother asserting + return v.toTensor(); + } +}; + +template +struct ivalue_to_arg final { + static List call(IValue& v) { + return v.toTensorList(); + } +}; + +template +struct ivalue_to_arg, AllowDeprecatedTypes> final { + // If an argument is ArrayRef, convert the IValue to a std::vector and + // pass that to the operator. std::vector is implicitly convertible to + // ArrayRef. + static std::vector call(IValue& v) { + return ivalue_to_arg, AllowDeprecatedTypes>::call(v); + } +}; +template +struct ivalue_to_arg final { + static std::vector call(IValue& v) { + if (v.isIntList()) { + std::vector r; + auto src = v.toIntList(); + std::transform( + src.begin(), src.end(), std::back_inserter(r), [](int64_t i) { + return c10::SymInt(i); + }); + return r; + } else { + return ivalue_to_arg, AllowDeprecatedTypes>:: + call(v); + } + } +}; +template +struct ivalue_to_arg, AllowDeprecatedTypes> + final { + static OptionalArray call(IValue& v) { + if (v.isIntList()) { + std::vector r; + auto src = v.toIntList(); + std::transform( + src.begin(), src.end(), std::back_inserter(r), [](int64_t i) { + return c10::SymInt(i); + }); + return OptionalArray(std::move(r)); + } else { + return std::move(v).to>(); + } + } +}; +template +struct ivalue_to_arg>, AllowDeprecatedTypes> final { + // If an argument is std::optional>, convert the IValue to an + // std::optional> and pass that to the operator. + // OptionalArray is basically a std::optional> but + // implicitly convertible to std::optional>. + static OptionalArray call(IValue& v) { + return ivalue_to_arg, AllowDeprecatedTypes>::call(v); + } +}; + +template +struct ivalue_to_arg, AllowDeprecatedTypes> final { + // If an argument is OptionalArrayRef, convert the IValue to an + // std::optional> and pass that to the operator. + // OptionalArray is basically a std::optional> but + // implicitly convertible to OptionalArrayRef + static OptionalArray call(IValue& v) { + return ivalue_to_arg, AllowDeprecatedTypes>::call(v); + } +}; + +// return_to_ivalue +template +struct return_to_ivalue final {}; + +template +struct return_to_ivalue< + T, + AllowDeprecatedTypes, + std::enable_if_t>> + final { + static IValue call(T&& v) { + assert_is_valid_output_type(); + return c10::ivalue::from(std::move(v)); + } + static IValue copy(const T& v) { + assert_is_valid_output_type(); + return IValue(v); + } +}; + +// Special case to allow kernels to return `Tensor&`. +// TODO Delete this once kernels don't do that anymore +template +struct return_to_ivalue final { + static IValue call(at::Tensor& v) { + return c10::ivalue::from(v); + } + static IValue copy(at::Tensor& v) { + return IValue(v); + } +}; + +// wrap_kernel_functor_unboxed_ + +template +struct wrap_kernel_functor_unboxed_ final {}; + +// This specialization is for kernels with a first argument that is NOT of type +// DispatchKeySet This includes kernels with 0 arguments. +template +struct wrap_kernel_functor_unboxed_< + KernelFunctor, + ReturnType(ParameterTypes...)> + final { + static_assert( + std::is_same_v< + ReturnType, + typename guts::infer_function_traits_t::return_type>, + "Return type mismatch"); + static_assert( + std::is_same_v< + guts::typelist::typelist, + typename guts::infer_function_traits_t< + KernelFunctor>::parameter_types>, + "Parameter types mismatch"); + + // See [Note: Argument forwarding in the dispatcher] for why ParameterTypes + // doesn't use && + static ReturnType call( + OperatorKernel* functor, + DispatchKeySet, + ParameterTypes... args) { + KernelFunctor* functor_ = static_cast(functor); + // Note [Plumbing Keys Through The Dispatcher 2] + // See Note [Plumbing Keys Through The Dispatcher] for the background. + // This functor explicitly takes in a dispatchKeySet and drops it on the + // floor- it does not forward it to the registered kernel. + // + // This is due to the calling convention within the dispatcher, which + // expects all registered kernels to have a first argument of type + // DispatchKeySet. + // This is not the case for pretty much all manually written kernels, + // however- this functor serves to separate the calling convention of the + // dispatcher from the calling convention of manually written kernels. + return (*functor_)(std::forward(args)...); + } +}; + +// This specialization is for kernels with a first argument of type +// DispatchKeySet +template +struct wrap_kernel_functor_unboxed_< + KernelFunctor, + ReturnType(DispatchKeySet, ParameterTypes...)> + final { + static_assert( + std::is_same_v< + ReturnType, + typename guts::infer_function_traits_t::return_type>, + "Return type mismatch"); + static_assert( + std::is_same_v< + guts::typelist::typelist, + typename guts::infer_function_traits_t< + KernelFunctor>::parameter_types>, + "Parameter types mismatch"); + + // See [Note: Argument forwarding in the dispatcher] for why ParameterTypes + // doesn't use && + static ReturnType call( + OperatorKernel* functor, + DispatchKeySet dispatchKeySet, + ParameterTypes... args) { + KernelFunctor* functor_ = static_cast(functor); + // We're explicitly taking in a dispatchKeySet and forwarding it to the + // registered kernel. See Note [Plumbing Keys Through The Dispatcher 2] for + // details. + return (*functor_)(dispatchKeySet, std::forward(args)...); + } +}; + +template +using wrap_kernel_functor_unboxed = wrap_kernel_functor_unboxed_< + KernelFunctor, + typename guts::infer_function_traits_t::func_type>; + +// call_functor_with_args_from_stack + +template < + class Functor, + bool AllowDeprecatedTypes, + size_t... ivalue_arg_indices, + typename... ArgTypes> +std::decay_t::return_type> +call_functor_with_args_from_stack_( + OperatorKernel* functor, + DispatchKeySet dispatchKeySet, + Stack* stack, + std::index_sequence, + guts::typelist::typelist*) { + (void)(stack); // when sizeof...(ivalue_arg_indices) == 0, this argument would + // be unused and we have to silence the compiler warning. + + // We're explicitly filtering out DispatchKeySet from the argument list. + // Some kernels take a DispatchKeySet as their first argument in order to + // plumb keys through the dispatcher. We don't want to expose the + // DispatchKeySet type to jit, so we don't include this argument on the stack. + // See Note [Plumbing Keys Through The Dispatcher] for the background. + return wrap_kernel_functor_unboxed::call( + functor, + dispatchKeySet, + ivalue_to_arg< + typename decay_if_not_tensor::type, + AllowDeprecatedTypes>:: + call(torch::jit::peek( + *stack, ivalue_arg_indices, sizeof...(ivalue_arg_indices)))...); +} + +template +std::decay_t::return_type> +call_functor_with_args_from_stack( + OperatorKernel* functor, + DispatchKeySet dispatchKeySet, + Stack* stack) { + // We're explicitly filtering out DispatchKeySet from the argument list. + // Some kernels take a DispatchKeySet as their first argument in order to + // plumb keys through the dispatcher. We don't want to expose the + // DispatchKeySet type to jit, so we don't include this argument on the stack. + // See Note [Plumbing Keys Through The Dispatcher] for the background. + using ArgTypes = typename c10::remove_DispatchKeySet_arg_from_func< + Functor>::parameter_types; + constexpr size_t num_ivalue_args = guts::typelist::size::value; + return call_functor_with_args_from_stack_( + functor, + dispatchKeySet, + stack, + std::make_index_sequence(), + static_cast(nullptr)); +} + +// push_outputs + +template +struct push_outputs final { + // Contrary to [Note: Argument forwarding in the dispatcher], we use + // OutputType&& here to avoid one extra call to the move constructor in this + // case. This is still not a universal reference though because OutputType is + // an explicitly specified class template parameter. + static void call(OutputType&& output, Stack* stack) { + torch::jit::push( + *stack, + return_to_ivalue::call( + std::forward(output))); + } + static void copy(const OutputType& output, Stack* stack) { + torch::jit::push( + *stack, + return_to_ivalue::copy(output)); + } +}; +template +struct push_outputs, AllowDeprecatedTypes> final { + static void call(std::tuple&& output, Stack* stack) { + call_( + std::move(output), + stack, + std::make_index_sequence()); + } + static void copy(const std::tuple& output, Stack* stack) { + copy_(output, stack, std::make_index_sequence()); + } + + private: + template + static void call_( + std::tuple&& output, + Stack* stack, + std::index_sequence) { + torch::jit::push( + *stack, + return_to_ivalue::call( + std::forward(std::get(output)))...); + } + template + static void copy_( + const std::tuple& output, + Stack* stack, + std::index_sequence) { + torch::jit::push( + *stack, + return_to_ivalue::copy( + std::get(output))...); + } +}; +template +struct push_outputs final { + static void call(int /*dummy*/, Stack* /*stack*/) {} + static void copy(int /*dummy*/, Stack* /*stack*/) {} +}; + +// make_boxed_from_unboxed_functor + +template +struct make_boxed_from_unboxed_functor final { + static_assert( + std::is_base_of_v, + "Tried to register a kernel functor using the kernel() API, but it doesn't inherit from c10::OperatorKernel. Please have the functor inherit from it."); + + static void call( + OperatorKernel* functor, + const OperatorHandle&, + DispatchKeySet dispatchKeySet, + Stack* stack) { + using ReturnType = + typename guts::infer_function_traits_t::return_type; + // We're explicitly filtering out DispatchKeySet from the argument list. + // Some kernels take a DispatchKeySet as their first argument in order to + // plumb keys through the dispatcher. We don't want to expose the + // DispatchKeySet type to jit, so we don't include this argument on the + // stack. See Note [Plumbing Keys Through The Dispatcher] for the + // background. + using ArgTypes = typename c10::remove_DispatchKeySet_arg_from_func< + KernelFunctor>::parameter_types; + constexpr bool has_outputs = !std::is_same_v; + constexpr size_t num_inputs = guts::typelist::size::value; + if constexpr (has_outputs) { + // Decay ReturnType to ReturnType_ so that if a reference gets returned, + // we actually store it by value and don't get a dangling reference. This + // is only required because some kernels still return `Tensor&`. [Note: + // VC++ and 'std': ambiguous symbol] + using ReturnType_ = ::std::decay_t; + ReturnType_ output = call_functor_with_args_from_stack< + KernelFunctor, + AllowDeprecatedTypes>(functor, dispatchKeySet, stack); + torch::jit::drop(*stack, num_inputs); + // See note [ VC++ and 'std': ambiguous symbol] + push_outputs::call( + ::std::move(output), stack); + } else { + call_functor_with_args_from_stack( + functor, dispatchKeySet, stack); + torch::jit::drop(*stack, num_inputs); + } + } +}; +} // namespace impl + +} // namespace c10 + +namespace torch { +using OperatorKernel = c10::OperatorKernel; +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/test_helpers.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/test_helpers.h new file mode 100644 index 0000000000000000000000000000000000000000..2c389ac4c75b5c54bf7b2259ac4db849d82f426a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/boxing/impl/test_helpers.h @@ -0,0 +1,140 @@ +#pragma once + +#include +#include + +#include +#include +#include +#include +#include + +template +inline std::vector makeStack(Inputs&&... inputs) { + return {std::forward(inputs)...}; +} + +inline at::Tensor dummyTensor( + c10::DispatchKeySet ks, + bool requires_grad = false) { + auto* allocator = c10::GetCPUAllocator(); + int64_t nelements = 1; + auto dtype = caffe2::TypeMeta::Make(); + int64_t size_bytes = nelements * dtype.itemsize(); + auto storage_impl = c10::make_intrusive( + c10::StorageImpl::use_byte_size_t(), + size_bytes, + allocator->allocate(size_bytes), + allocator, + /*resizable=*/true); + at::Tensor t = + at::detail::make_tensor(storage_impl, ks, dtype); + // TODO: We add this to simulate the ideal case where we only have Autograd + // backend keys + // on Tensor when it requires grad. But currently Autograd keys are + // added in TensorImpl constructor by default. + if (!requires_grad) { + t.unsafeGetTensorImpl()->remove_autograd_key(); + } + return t; +} + +inline at::Tensor dummyTensor( + c10::DispatchKey dispatch_key, + bool requires_grad = false) { + return dummyTensor(c10::DispatchKeySet(dispatch_key), requires_grad); +} + +template +inline std::vector callOp( + const c10::OperatorHandle& op, + Args... args) { + auto stack = makeStack(std::forward(args)...); + op.callBoxed(&stack); + return stack; +} + +template +inline Result callOpUnboxed(const c10::OperatorHandle& op, Args... args) { + return op.typed().call(std::forward(args)...); +} + +template +inline Result callOpUnboxedWithDispatchKey( + const c10::OperatorHandle& op, + c10::DispatchKey dispatchKey, + Args... args) { + return op.typed().callWithDispatchKey( + dispatchKey, std::forward(args)...); +} + +template +inline Result callOpUnboxedWithPrecomputedDispatchKeySet( + const c10::OperatorHandle& op, + c10::DispatchKeySet ks, + Args... args) { + return op.typed().redispatch( + ks, std::forward(args)...); +} + +inline void expectDoesntFindKernel( + const char* op_name, + c10::DispatchKey dispatch_key) { + auto op = c10::Dispatcher::singleton().findSchema({op_name, ""}); + EXPECT_ANY_THROW(callOp(*op, dummyTensor(dispatch_key), 5);); +} + +inline void expectDoesntFindOperator(const char* op_name) { + auto op = c10::Dispatcher::singleton().findSchema({op_name, ""}); + EXPECT_FALSE(op.has_value()); +} + +template +inline void expectThrows(Functor&& functor, const char* expectMessageContains) { + try { + std::forward(functor)(); + } catch (const Exception& e) { + EXPECT_THAT(e.what(), testing::HasSubstr(expectMessageContains)); + return; + } + ADD_FAILURE() << "Expected to throw exception containing \"" + << expectMessageContains << "\" but didn't throw"; +} + +template +void expectListEquals(c10::ArrayRef expected, std::array actual) { + EXPECT_EQ(expected.size(), actual.size()); + for (const auto i : c10::irange(expected.size())) { + EXPECT_EQ(expected[i], actual[i]); + } +} + +template +void expectListEquals(c10::ArrayRef expected, c10::ArrayRef actual) { + EXPECT_EQ(expected.size(), actual.size()); + for (const auto i : c10::irange(expected.size())) { + EXPECT_EQ(expected[i], actual[i]); + } +} + +template +void expectListEquals(c10::ArrayRef expected, c10::List actual) { + EXPECT_EQ(expected.size(), actual.size()); + for (const auto i : c10::irange(expected.size())) { + EXPECT_EQ(expected[i], actual.get(i)); + } +} + +template +void expectListEquals(c10::ArrayRef expected, std::vector actual) { + EXPECT_EQ(expected.size(), actual.size()); + for (const auto i : c10::irange(expected.size())) { + EXPECT_EQ(expected[i], actual[i]); + } +} + +// NB: This is not really sound, but all of the type sets constructed here +// are singletons so it's fine +static inline c10::DispatchKey extractDispatchKey(const at::Tensor& t) { + return legacyExtractDispatchKey(t.key_set()); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/builtin_function.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/builtin_function.h new file mode 100644 index 0000000000000000000000000000000000000000..5ab1ace1685f8b73f05ff3b647a10037b01d2644 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/builtin_function.h @@ -0,0 +1,90 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + +namespace torch::jit { + +struct BuiltinOpFunction : public Function { + BuiltinOpFunction( + c10::QualifiedName qualname, + c10::FunctionSchema schema, + std::function callable, + std::string doc_string = "") + : name_(std::move(qualname)), + callable_(std::move(callable)), + schema_(std::move(schema)), + doc_string_(std::move(doc_string)) { + TORCH_INTERNAL_ASSERT(schema_.returns().size() == 1); + } + + std::string_view doc_string() const override { + return doc_string_; + } + + void run(Stack& stack) override { + callable_(stack); + } + + c10::intrusive_ptr runAsync( + Stack& stack, + TaskLauncher /* not used */) override { + run(stack); + auto res = c10::make_intrusive(stack.front().type()); + res->markCompleted(std::move(stack.front())); + return res; + } + + const c10::QualifiedName& qualname() const override { + return name_; + } + + // if this isn't yet defined, run its method_creator function + void ensure_defined() override { + // nop + } + + const c10::FunctionSchema& getSchema() const override { + return schema_; + } + + size_t num_inputs() const override { + return schema_.arguments().size(); + } + + Function& setSchema(c10::FunctionSchema schema) override { + schema_ = std::move(schema); + return *this; + } + + bool call( + Stack& stack, + std::optional, + c10::function_ref) override { + run(stack); + return false; + } + + bool call(Stack& stack, c10::function_ref) + override { + run(stack); + return false; + } + + ~BuiltinOpFunction() override = default; + + private: + c10::QualifiedName name_; + + std::function callable_; + + c10::FunctionSchema schema_; + + std::string doc_string_; +}; + +} // namespace torch::jit diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/class_type.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/class_type.h new file mode 100644 index 0000000000000000000000000000000000000000..ea124fc6eb079558c4682fcb62726a3ab8d019ba --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/class_type.h @@ -0,0 +1,441 @@ +#pragma once + +#include + +#include +#include +#include + + +namespace torch::jit { +struct CompilationUnit; +struct Function; +} // namespace torch::jit + + +namespace c10 { + +struct FunctionSchema; + +// This enumerator represents the 'kind' of an attribute - a buffer, a parameter, or neither. +// This state is mutually exclusive. Buffers and Parameters can only appear on modules. +enum class AttributeKind { + BUFFER, + PARAMETER, + REGULAR_ATTRIBUTE +}; + +// This structure represents all notional booking entities in a class attribute: name, kind (see: AttributeKind), and type (see: TypePtr). +// Note: This structure does not represent the value of the attribute. +struct TORCH_API ClassAttribute { + public: + ClassAttribute(AttributeKind kind, + TypePtr attributeType, + std::string attributeName) : + kind_(kind), + attributeType_(std::move(attributeType)), + attributeName_(std::move(attributeName)) {} + + AttributeKind getKind() const { + return kind_; + } + + const TypePtr& getType() const { + return attributeType_; + } + + const std::string& getName() const { + return attributeName_; + } + + private: + AttributeKind kind_; + TypePtr attributeType_; + std::string attributeName_; +}; + +/** + * User Defined Types + */ + +struct ClassType; +using ClassTypePtr = std::shared_ptr; +using ::torch::jit::CompilationUnit; + +// This represents a class in TorchScript. +struct TORCH_API ClassType : public NamedType { + // This represents an attribute of a class; a name associated with an attribute, and a + // getter and (optional) setter for that attribute. + struct Property { + std::string name; + torch::jit::Function* getter; + torch::jit::Function* setter; + }; + + // Create a class type with name `name` and its methods stored in `cu`. + static ClassTypePtr create( + std::optional qualifiedName, + std::weak_ptr cu, + bool is_module = false, + std::string doc_string = "", + std::vector unresolved_class_attributes = {}); + + bool equals(const Type& rhs) const override { + if (this == &rhs) { + return true; + } + if (auto user_rhs = rhs.castRaw()) { + const auto& lhs_name = name(); + const auto& rhs_name = user_rhs->name(); + return lhs_name.has_value() && lhs_name == rhs_name && + this->compilation_unit() == user_rhs->compilation_unit(); + } + return false; + } + + std::string str() const override { + return annotation_str(); + } + + std::string repr_str() const override { + std::stringstream ss; + ss << str() + << " (of Python compilation unit at: " << compilation_unit().get() << ")"; + return ss.str(); + } + + const std::vector& methods() const; + + TypePtr findAttribute(const std::string& name) const { + size_t pos = 0; + for (const auto& attr : attributes_) { + if (name == attr.getName()) { + break; + } + ++pos; + } + + if (pos >= attributes_.size()) { + return nullptr; + } + return attributes_[pos].getType(); + } + + const TypePtr& getAttribute(const std::string& name) const { + auto slot = findAttributeSlot(name); + TORCH_CHECK( + slot, + repr_str(), + " does not have an attribute with name '", + name, + "'"); + return attributes_[*slot].getType(); + } + + size_t numAttributes() const { + return attributes_.size(); + } + + const TypePtr& getAttribute(size_t slot) const { + AT_ASSERT(slot < attributes_.size()); + return attributes_.at(slot).getType(); + } + + const std::string getAttributeName(size_t slot) const { + AT_ASSERT(slot < attributes_.size()); + return attributes_[slot].getName(); + } + + void checkNotExist(const std::string& name, const std::string& what) const; + + // Attributes are stored in a specific slot at runtime for effiency. + // When emitting instructions we specify the slot so that attribute access is + // a constant lookup + std::optional findAttributeSlot(const std::string& name) const { + size_t slot = 0; + for (const auto& attr : attributes_) { + if (name == attr.getName()) { + return slot; + } + slot++; + } + return std::nullopt; + } + size_t getAttributeSlot(const std::string& name) const { + if (auto r = findAttributeSlot(name)) { + return *r; + } + TORCH_CHECK( + false, + repr_str(), + " does not have an attribute with name '", + name, + "'"); + } + + bool hasAttribute(const std::string& name) const { + return std::find_if( + attributes_.cbegin(), + attributes_.cend(), + [&](const ClassAttribute& attr) { return attr.getName() == name; }) != + attributes_.cend(); + } + + bool isUnresolvedClassAttribute(const std::string& name) const; + + at::ArrayRef containedTypes() const override { + return attributeTypes_; + } + + size_t addAttribute( + const std::string& name, + TypePtr type, + bool is_parameter = false, + bool is_buffer = false); + + // [Internal Only] Remove attribute from the ClassType, + // caller is responsible to make sure the modification is safe: + // it is unsafe to having existing allocations + // of this object around anymore, and any code that works on + // the attribute is now invalid. Only newly created code is + // valid again. + void unsafeRemoveAttribute(const std::string& name); + + // [Internal Only] Change the type of an attribute of the ClassType, + // The caller is responsible to make sure the modification is safe: + // it is unsafe to maintain uses of the old type of the attribute, + // and any code that works on the attribute is now invalid. + // Only newly created code is valid again. + void unsafeChangeAttributeType(const std::string& name, const TypePtr& new_ty); + + // Add attribute \p NAME if it doesn't exist or verify that it has a + // compatible type otherwise. + size_t addOrCheckAttribute( + const std::string& name, + TypePtr ty, + bool is_parameter = false, + bool is_buffer = false) { + auto slot_idx = findAttributeSlot(name); + if (!slot_idx) { + return addAttribute(name, std::move(ty), is_parameter, is_buffer); + } + + TORCH_CHECK( + is_parameter == this->is_parameter(*slot_idx), + "Parameter field mismatch for the field '", + name, + "'"); + const TypePtr& atype = getAttribute(*slot_idx); + TORCH_CHECK( + ty->isSubtypeOf(*atype), + ty->repr_str(), + " is not compatible with the type ", + atype->repr_str(), + " for the field '", + name, + "'"); + return *slot_idx; + } + + // Get the property with the given \p name, if it exists on the class. + std::optional getProperty(const std::string& name); + // Add a property named \p name with \p getter and \p setter as its getter and setter. + void addProperty(const std::string& name, torch::jit::Function* getter, torch::jit::Function* setter); + // Get a list of all properties. + const std::vector& properties() const { + return properties_; + } + + bool hasConstant(const std::string& name) const { + return std::find_if( + constantNames_.cbegin(), + constantNames_.cend(), + [&](const std::string& constant) { return constant == name; }) != + constantNames_.cend(); + } + + size_t addConstant(const std::string& name, const IValue& value); + + std::optional findConstantSlot(const std::string& name) const; + + size_t getConstantSlot(const std::string& name) const { + if (auto r = findConstantSlot(name)) { + return *r; + } + TORCH_CHECK( + false, + repr_str(), + " does not have constant field with the name '", + name, + "'"); + } + + const std::string& getConstantName(size_t slot) const; + + const std::string& doc_string() const { + return doc_string_; + } + + IValue getConstant(const std::string& name) const; + + IValue getConstant(size_t slot) const; + + std::optional findConstant(const std::string& name) const; + + size_t numConstants() const; + + at::ArrayRef constantNames() const { + return constantNames_; + } + + at::ArrayRef constantValues() const; + + // [Internal Only] Remove constant from the ClassType + // caller is responsible to make sure the modification is safe: + // it is unsafe to having existing allocations + // of this object around anymore, and any code that works on + // the attribute is now invalid. Only newly created code is + // valid again. + void unsafeRemoveConstant(const std::string& name); + + TypePtr createWithContained(std::vector contained_types) const override { + auto ptr = ClassType::create(name(), compilation_unit_, is_module()); + AT_ASSERT(numAttributes() == contained_types.size()); + for(size_t i = 0; i < attributes_.size(); ++i) { + AT_ASSERT(attributes_[i].getType()->isSubtypeOf(*contained_types[i])); + ptr->addAttribute(attributes_[i].getName(), std::move(contained_types[i])); + } + // Copy methods over + for (const auto& method : methods()) { + ptr->addMethod(method); + } + return ptr; + } + + bool is_module() const override { + return isModule_; + } + + const std::vector& getAttributes() const { + return attributes_; + } + + bool is_parameter(size_t slot) const { + TORCH_INTERNAL_ASSERT( + is_module(), "asking for parameterSlots of non-Module"); + return attributes_.at(slot).getKind() == AttributeKind::PARAMETER; + } + + bool is_buffer(size_t slot) const { + TORCH_INTERNAL_ASSERT( + is_module(), "asking for bufferWrittenSlots of non-Module"); + return attributes_.at(slot).getKind() == AttributeKind::BUFFER; + } + + void addForwardPreHook(torch::jit::Function* pre_hook_ptr); + void addForwardHook(torch::jit::Function* hook_ptr); + torch::jit::Function* findForwardPreHook(const std::string& name) const; + torch::jit::Function* findForwardHook(const std::string& name) const; + const std::vector& getForwardHooks() const; + const std::vector& getForwardPreHooks() const; + + void checkForwardPreHookSchema( + size_t pre_hook_idx, + const FunctionSchema& pre_hook_schema) const; + void checkForwardHookSchema( + size_t hook_idx, + const FunctionSchema& hook_schema) const; + + void addMethod(torch::jit::Function* method); + torch::jit::Function* findMethod(const std::string& name) const; + torch::jit::Function& getMethod(const std::string& name) const; + torch::jit::Function* findHook(const std::string& name) const; + torch::jit::Function& getHook(const std::string& name) const; + bool hasMethod(const std::string& name) const; + + torch::jit::Function* findStaticMethod(const std::string& name) const; + void addStaticMethod(torch::jit::Function* method); + + // [Internal Only] Remove method from the ClassType + // caller is responsible to make sure the modification is safe: + // it is unsafe to having existing allocations + // of this object around anymore, and any code that works on + // the attribute is now invalid. Only newly created code is + // valid again. + // Note this method is intended for freezing only. + void unsafeRemoveMethod(const std::string& name); + + std::shared_ptr compilation_unit(); + + std::shared_ptr compilation_unit() const; + + // generate a refined version of this class. + // It has the same name but the slot Types are subtypes of + // the original slots. It is only valid to refine a class type in a context + // where it is know that there are not assignments to the objects slots + // that would invalidate the refinement. + // These variants are not registered in the global class table. + ClassTypePtr refine(at::ArrayRef refined_slots) const; + + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override; + + static const TypeKind Kind = TypeKind::ClassType; + + private: + ClassType( + std::optional name, + std::weak_ptr cu, + bool is_module = false, + std::string doc_string = "", + std::vector unresolved_class_attributes = {}); + + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + // NOLINTNEXTLINE(bugprone-unchecked-optional-access) + return name()->qualifiedName(); + } + + void addAttribute(ClassAttribute classAttribute); + std::string getForwardPreHookErrorMessage(size_t pre_hook_idx) const; + std::string getForwardHookErrorMessage(size_t hook_idx) const; + + // Mapping of attribute names -> their type. + // NOTE: this does not contain methods, which are stored in the module + // TODO: once modules support arbitrary ivalue attributes, we don't need this + // anymore. + // TODO: This is better represented as an OrderedDict, but alas it is not yet + // available from c10 + + // Mapping of constant names -> their value. + std::vector constantNames_; + std::vector constantValues_; + // Holds method attributes + std::weak_ptr compilation_unit_; + + // Holds all atrributes, attribute details are found on ClassAttribute + std::vector attributes_; + // Construct mirroring attributes_, only around due to the fact that `containedTypes()` method returns an ArrayRef. + // Never fill this without using the appropriate provideNewClassAttribute method + std::vector attributeTypes_; + + // List of methods associated with this class. + std::vector methods_; + std::vector staticmethods_; + + // List of hooks to be run before/after forward. + std::vector forward_hooks_; + std::vector forward_pre_hooks_; + + // List of properties exposed by this class. + std::vector properties_; + + bool isModule_ = false; + + // Doc string of class. + std::string doc_string_; + + // For error reporting accesses to class level attributes. + std::vector unresolved_class_attributes_; +}; + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/custom_class.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/custom_class.h new file mode 100644 index 0000000000000000000000000000000000000000..ff9bda981b2906e55449e93a582266888c2eb258 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/custom_class.h @@ -0,0 +1,28 @@ +#pragma once + +#include +#include + +#include +#include +#include + +namespace c10 { + +struct ClassType; +using ClassTypePtr = std::shared_ptr; + +TORCH_API c10::ClassTypePtr getCustomClassTypeImpl(const std::type_index &tindex); + +template +const c10::ClassTypePtr& getCustomClassType() { + // Classes are never unregistered from getCustomClassTypeMap and the + // hash lookup can be a hot path, so just cache. + // For the same reason, it's fine If this ends up getting duplicated across + // DSO boundaries for whatever reason. + static c10::ClassTypePtr cache = getCustomClassTypeImpl( + std::type_index(typeid(T))); + return cache; +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/CppSignature.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/CppSignature.h new file mode 100644 index 0000000000000000000000000000000000000000..e7695aa5c21f4098b2f7c2971d7a20b03b51fa73 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/CppSignature.h @@ -0,0 +1,67 @@ +#pragma once + +#include +#include +#include +#include +#include + +namespace c10::impl { + +// A CppSignature object holds RTTI information about a C++ function signature +// at runtime and can compare them or get a debug-printable name. +class TORCH_API CppSignature final { + public: + CppSignature(const CppSignature&) = default; + CppSignature(CppSignature&&) noexcept = default; + CppSignature& operator=(const CppSignature&) = default; + CppSignature& operator=(CppSignature&&) noexcept = default; + + template + static CppSignature make() { + // Normalize functors, lambdas, function pointers, etc. into the plain + // function type The first argument of the schema might be of type + // DispatchKeySet, in which case we remove it. We do this to guarantee that + // all CppSignature's for an operator will match, even if they're registered + // with different calling conventions. + // See Note [Plumbing Keys Through The Dispatcher] + using decayed_function_type = + typename c10::remove_DispatchKeySet_arg_from_func< + std::decay_t>::func_type; + + return CppSignature(std::type_index(typeid(decayed_function_type))); + } + + std::string name() const { + return c10::demangle(signature_.name()); + } + + friend bool operator==(const CppSignature& lhs, const CppSignature& rhs) { + if (lhs.signature_ == rhs.signature_) { + return true; + } + // Without RTLD_GLOBAL, the type_index comparison could yield false because + // they point to different instances of the RTTI data, but the types would + // still be the same. Let's check for that case too. + // Note that there still is a case where this might not work, i.e. when + // linking libraries of different compilers together, they might have + // different ways to serialize a type name. That, together with a missing + // RTLD_GLOBAL, would still fail this. + if (0 == strcmp(lhs.signature_.name(), rhs.signature_.name())) { + return true; + } + + return false; + } + + private: + explicit CppSignature(std::type_index signature) + : signature_(std::move(signature)) {} + std::type_index signature_; +}; + +inline bool operator!=(const CppSignature& lhs, const CppSignature& rhs) { + return !(lhs == rhs); +} + +} // namespace c10::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/DispatchKeyExtractor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/DispatchKeyExtractor.h new file mode 100644 index 0000000000000000000000000000000000000000..27438b926db558bcc2c460bea297745b98a2c14c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/DispatchKeyExtractor.h @@ -0,0 +1,258 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include + +namespace c10 { + +namespace impl { + +// Take a DispatchKeySet for a Tensor and determine what the actual dispatch +// DispatchKey should be, taking into account TLS, and skipping backends which +// fall through. +// +// Unlike Tensor::key_set(), the value of this on a tensor can change depending +// on TLS. +// +// NB: If there is no valid dispatch key, this will return Undefined +inline DispatchKeySet computeDispatchKeySet( + DispatchKeySet ks, + // The key mask lets us eliminate (by zero entries) keys which should not + // be considered for dispatch. There are two cases when we use this: + // + // - If an operator's dispatch table contains a fallthrough entry, we + // should bypass it entirely when finding the key + // - If a user invokes with redispatch, the mask lets us + // zero out the key the user asked us to stop. + // + // These excluded backends are NOT tracked in the TLS, but must be applied + // AFTER TLS (since the backend may have been introduced for consideration + // by the included TLS), which is why you have to pass them in to this + // function (as opposed to just applying it to the input 'ks'). + DispatchKeySet key_mask) { + c10::impl::LocalDispatchKeySet local = + c10::impl::tls_local_dispatch_key_set(); + // TODO: It's a bit irritating that we have to do logical ORs here, it would + // be nice to only do one. Can always_included be folded into the TLS? Well, + // it's a bit troublesome, because fastpath TLS access requires the type of + // the TLS in question to be zero-initialized, so you don't actually win + // anything in that case. + return (((ks | local.included_) - local.excluded_) & key_mask); +} + +} // namespace impl + +namespace detail { +// A small gadget to extract the DispatchKeySet from types which are known +// to have it. Used to extract dispatch keys from unboxed calls. +struct MultiDispatchKeySet : at::IterArgs { + DispatchKeySet ts; + void operator()(const at::Tensor& x) { + ts = ts | x.key_set(); + } + void operator()(const std::optional& x) { + if (x.has_value()) { + ts = ts | x->key_set(); + } + } + void operator()(at::ArrayRef xs) { + for (const auto& x : xs) { + ts = ts | x.key_set(); + } + } + // Tensor?[] translates to this case. + void operator()(const c10::List>& xs) { + for (std::optional x : xs) { + if (x.has_value()) { + ts = ts | x.value().key_set(); + } + } + } + // Structured Tensor[] translates to this case + void operator()(const at::ITensorListRef& xs) { + for (const auto& x : xs) { + ts = ts | x.key_set(); + } + } + [[noreturn]] void operator()(at::ArrayRef>) { + // Just checking that the handling of Tensor?[] didn't change. + TORCH_INTERNAL_ASSERT(false); + } + void operator()(const at::Generator& gen) { + if (gen.defined()) { + ts = ts | gen.key_set(); + } + } + void operator()(const std::optional& gen) { + if (gen.has_value() && gen->defined()) { + ts = ts | gen->key_set(); + } + } + template + void operator()(const T&) { + // do nothing + } +}; + +// NB: take by const reference (Don't do universal forwarding here! You +// don't want to move into this function!) +template +DispatchKeySet multi_dispatch_key_set(const Args&... args) { + return MultiDispatchKeySet().apply(args...).ts; +} +} // namespace detail + +/** + * An instance of DispatchKeyExtractor knows how to get a dispatch key given + * a list of arguments for an operator call. + * + * The instance is specific for a certain operator as: + * - In boxed dispatch, different operators have different ways to extract + * the dispatch key (e.g. different numbers of arguments), and we precompute + * the stack locations we should look at; and + * - In all dispatch, some backends should be excluded from dispatch because + * they have been registered as fallthrough. The set of excluded backends + * varies from operator, as some operators may have overridden the + * fallthrough with custom behavior. + * + * Note - this should maintain identical impl to the py dispatcher key + * extraction logic at pytorch/torch/dispatcher.py + */ +struct TORCH_API DispatchKeyExtractor final { + public: + static DispatchKeyExtractor make(const FunctionSchema& schema) { + return DispatchKeyExtractor(makeBitsetForDispatchArgs(schema)); + } + + static DispatchKeyExtractor makeUninitialized() { + return DispatchKeyExtractor(c10::utils::bitset()); + } + + void registerSchema(const FunctionSchema& schema) { + TORCH_INTERNAL_ASSERT(dispatch_arg_indices_reverse_.is_entirely_unset()); + dispatch_arg_indices_reverse_ = makeBitsetForDispatchArgs(schema); + } + void deregisterSchema() { + dispatch_arg_indices_reverse_ = c10::utils::bitset(); + } + + DispatchKeySet getDispatchKeySetBoxed(const torch::jit::Stack* stack) const { + DispatchKeySet ks; + dispatch_arg_indices_reverse_.for_each_set_bit([&](size_t + reverse_arg_index) { + const auto& ivalue = torch::jit::peek(*stack, 0, reverse_arg_index + 1); + if (C10_LIKELY(ivalue.isTensor())) { + // NB: Take care not to introduce a refcount bump (there's + // no safe toTensorRef method, alas) + ks = ks | ivalue.unsafeToTensorImpl()->key_set(); + } else if (C10_UNLIKELY(ivalue.isTensorList())) { + for (const at::Tensor& tensor : ivalue.toTensorList()) { + ks = ks | tensor.key_set(); + } + } + // Tensor?[] translates to a c10::List so we need to peek inside + else if (C10_UNLIKELY(ivalue.isList())) { + for (const auto& elt : ivalue.toListRef()) { + if (elt.isTensor()) { + ks = ks | elt.toTensor().key_set(); + } + } + } + }); + // Keys that are fallthrough should be skipped + if (requiresBitsetPerBackend_) { + c10::impl::LocalDispatchKeySet tls = + c10::impl::tls_local_dispatch_key_set(); + auto backend_idx = + ((ks | tls.included_) - tls.excluded_).getBackendIndex(); + return impl::computeDispatchKeySet( + ks, nonFallthroughKeysPerBackend_[backend_idx]); + } else { + return impl::computeDispatchKeySet(ks, nonFallthroughKeys_); + } + } + + template + DispatchKeySet getDispatchKeySetUnboxed(const Args&... args) const { + auto ks = detail::multi_dispatch_key_set(args...); + // Keys that are fallthrough should be skipped + if (requiresBitsetPerBackend_) { + c10::impl::LocalDispatchKeySet tls = + c10::impl::tls_local_dispatch_key_set(); + auto backend_idx = + ((ks | tls.included_) - tls.excluded_).getBackendIndex(); + return impl::computeDispatchKeySet( + ks, nonFallthroughKeysPerBackend_[backend_idx]); + } else { + return impl::computeDispatchKeySet(ks, nonFallthroughKeys_); + } + } + + void setOperatorHasFallthroughForKey(DispatchKey k, bool has_fallthrough); + + std::string dumpState() const; + void checkInvariants(const FunctionSchema& schema) const; + + private: + static c10::utils::bitset makeBitsetForDispatchArgs( + const FunctionSchema& schema) { + TORCH_CHECK( + schema.arguments().size() <= c10::utils::bitset::NUM_BITS(), + "The function schema has ", + schema.arguments().size(), + " arguments but this PyTorch build only supports ", + c10::utils::bitset::NUM_BITS()); + c10::utils::bitset dispatch_arg_indices_reverse; + for (const auto index : c10::irange(schema.arguments().size())) { + if (schema.arguments()[index].type()->isSubtypeOf(*TensorType::get()) || + schema.arguments()[index].type()->isSubtypeOf( + *ListType::ofTensors()) || + schema.arguments()[index].type()->isSubtypeOf( + *ListType::ofOptionalTensors()) || + schema.arguments()[index].type()->isSubtypeOf( + *OptionalType::ofTensor())) { + dispatch_arg_indices_reverse.set(schema.arguments().size() - 1 - index); + } + } + return dispatch_arg_indices_reverse; + } + + explicit DispatchKeyExtractor(c10::utils::bitset dispatch_arg_indices_reverse) + : dispatch_arg_indices_reverse_(dispatch_arg_indices_reverse), + nonFallthroughKeys_(DispatchKeySet::FULL), + requiresBitsetPerBackend_(false) { + for (const auto i : c10::irange(nonFallthroughKeysPerBackend_.size())) { + nonFallthroughKeysPerBackend_[i] = DispatchKeySet::FULL; + } + } + + // this is a bitset that has ones for each argument index which has to be + // considered for dispatch. This avoids having to iterate over the stack + // to find all the tensors. The bits are stored in reverse order, i.e. + // dispatch_arg_indices_reverse_[i] == true, then the i-th argument from + // the top of the stack (i.e. the i-th last argument of the function) + // is relevant for dispatch. + // dispatch_arg_indices_reverse_ is allowed to have zero bits set; that just + // means you must do the fallthrough + c10::utils::bitset dispatch_arg_indices_reverse_; + + // Set of functionality keys for which the operator does NOT have fallthrough + // kernel. + DispatchKeySet nonFallthroughKeys_; + // Set of functionality keys for which the operator does NOT have fallthrough + // kernel, defined PER BACKEND. This is only needed if we know that the + // operator has a different set of fallthroughs defined for some backends. + std::array nonFallthroughKeysPerBackend_; + // Flag to tell us if we can use the single set of nonFallthroughKeys_ (fast + // path), or if we need to fall back to the slower path and check + // nonFallthroughKeysPerBackend_ + bool requiresBitsetPerBackend_; +}; + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/Dispatcher.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/Dispatcher.h new file mode 100644 index 0000000000000000000000000000000000000000..dbc501afe7ce5c14e3b5aa5a035425fbf51109fd --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/Dispatcher.h @@ -0,0 +1,933 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include + +#ifndef NDEBUG +#include +#endif + +namespace c10 { + +TORCH_API bool show_dispatch_trace(); +TORCH_API void dispatch_trace_nesting_incr(); +TORCH_API void dispatch_trace_nesting_decr(); +TORCH_API int64_t dispatch_trace_nesting_value(); + +struct DispatchTraceNestingGuard { + DispatchTraceNestingGuard() { + dispatch_trace_nesting_incr(); + } + ~DispatchTraceNestingGuard() { + dispatch_trace_nesting_decr(); + } +}; + +class TORCH_API OperatorHandle; +template +class TypedOperatorHandle; + +/** + * Implement this interface and register your instance with the dispatcher + * to get notified when operators are registered or deregistered with + * the dispatcher. + * + * NB: registration events only occur when a 'def' occurs; we don't trigger + * on 'impl' or 'fallback' calls. + */ +class TORCH_API OpRegistrationListener { + public: + virtual ~OpRegistrationListener(); + + virtual void onOperatorRegistered(const OperatorHandle& op) = 0; + virtual void onOperatorDeregistered(const OperatorHandle& op) = 0; +}; + +namespace detail { +class RegistrationListenerList; +} +class SchemaRegistrationHandleRAII; + +/** + * Top-level dispatch interface for dispatching via the dynamic dispatcher. + * Most end users shouldn't use this directly; if you're trying to register + * ops look in op_registration + */ +class TORCH_API Dispatcher final { + private: + // For direct access to backend fallback information + friend class impl::OperatorEntry; + + struct OperatorDef final { + explicit OperatorDef(OperatorName&& op_name) : op(std::move(op_name)) {} + + impl::OperatorEntry op; + + // These refer to the number of outstanding RegistrationHandleRAII + // for this operator. def_count reflects only def() registrations + // (in the new world, this should only ever be 1, but old style + // registrations may register the schema multiple times, which + // will increase this count). def_and_impl_count reflects the number + // of combined def() and impl() registrations. When the last def() gets + // unregistered, we must immediately call the Deregistered listeners, but we + // must not actually delete the handle as there are other outstanding RAII + // destructors which will try to destruct and they had better still have a + // working operator handle in this case + size_t def_count = 0; + size_t def_and_impl_count = 0; + }; + friend class OperatorHandle; + template + friend class TypedOperatorHandle; + + struct Guard final { + Guard() : alive(true), mutex() {} + std::atomic alive; + std::mutex mutex; + }; + + public: + ~Dispatcher(); + + // Implementation note: this class abstracts over the fact that we have + // per-operator dispatch tables. This could be easily adjusted to have a + // single global hash table. + static Dispatcher& realSingleton(); + + C10_ALWAYS_INLINE static Dispatcher& singleton() { +#if !defined C10_MOBILE + // Implemented inline so that steady-state code needn't incur + // function-call overhead. We can't just inline `realSingleton` + // because the function-local static would get duplicated across + // all DSOs that include & use this header, leading to multiple + // singleton instances. + static Dispatcher& s = realSingleton(); + return s; +#else + // For C10_MOBILE, we should never inline a static function that + // has a static member, since the generated code calls + // __cxa_guard_acquire and __cxa_guard_release which help + // implement exactly once semantics for the initialization of the + // static Dispatcher& s above (for the non-mobile case). That + // additional code when duplicated across all operator stubs + // for every backend results in a lot of additional code + // being generated by the compiler. + return realSingleton(); +#endif + } + + // ------------------------------------------------------------------------ + // + // Accessing operators by schema + // + // ------------------------------------------------------------------------ + + /** + * Looks for an operator schema with the given name and overload name + * and returns it if it is registered WITH A SCHEMA. + * Returns nullopt otherwise. + */ + std::optional findSchema(const OperatorName& operator_name); + + /** + * Variant of findSchema that results in less code generated at the call site. + * It (1) takes const char* pointer rather than OperatorName (so we skip + * generating std::string constructor calls at the call site), and (2) + * it raises an exception if the operator is not found (so we skip + * generating exception raising code at the call site) + * + * Irritatingly, we still have to generate the handful of instructions + * for dealing with an exception being thrown during static initialization + * (e.g. __cxa_guard_abort). If we could annotate this method noexcept we + * could avoid this code too, but as the name of the function suggests, + * it does throw exceptions. + */ + OperatorHandle findSchemaOrThrow(const char* name, const char* overload_name); + + // Like findSchema, but also returns OperatorHandle even if there is no schema + std::optional findOp(const OperatorName& operator_name); + + // Returns a list of all operator names present in the operatorLookupTable_ + const std::vector getAllOpNames(); + + // ------------------------------------------------------------------------ + // + // Invoking operators + // + // ------------------------------------------------------------------------ + + template + Return call(const TypedOperatorHandle& op, Args... args) + const; + + template + static Return callWithDispatchKeySlowPath( + const TypedOperatorHandle& op, + at::StepCallbacks& stepCallbacks, + DispatchKeySet dispatchKeySet, + const KernelFunction& kernel, + Args... args); + + // Like call, but intended for use in a redispatch in kernels that have + // explicitly performed the DispatchKey update calculatulation. This will take + // the DispatchKeySet completely as is and dispatch to the kernel of the + // corresponding highest priority key in the set. Note that this version of + // redispatch treats the inputted DispatchKeySet *as is*, and does NOT mask + // out the highest priority key. See Note [Plumbing Keys Through The + // Dispatcher] + template + Return redispatch( + const TypedOperatorHandle& op, + DispatchKeySet currentDispatchKeySet, + Args... args) const; + + // Invoke an operator via the boxed calling convention using an IValue stack + void callBoxed(const OperatorHandle& op, Stack* stack) const; + void callBoxedForDispatchKey( + const OperatorHandle& op, + DispatchKey dk, + Stack* stack) const; + + // TODO: This will only be useful if we write a backend fallback that plumbs + // dispatch keys (currently there are none) See Note [Plumbing Keys Through + // The Dispatcher] + void redispatchBoxed( + const OperatorHandle& op, + DispatchKeySet dispatchKeySet, + Stack* stack) const; + + bool hasBackendFallbackForDispatchKey(DispatchKey dk) { + auto dispatch_ix = getDispatchTableIndexForDispatchKey(dk); + if (dispatch_ix < 0) + return false; + return backendFallbackKernels_[dispatch_ix].kernel.isValid(); + } + + // Used by torchdeploy/multipy for multiple interpreters racing. + void waitForDef(const FunctionSchema& schema); + void waitForImpl( + const OperatorName& op_name, + std::optional dispatch_key); + + // ------------------------------------------------------------------------ + // + // Performing registrations (NON user public; use op_registration) + // + // ------------------------------------------------------------------------ + + /** + * Register a new operator schema. + * + * If a schema with the same operator name and overload name already exists, + * this function will check that both schemas are exactly identical. + */ + RegistrationHandleRAII registerDef( + FunctionSchema schema, + std::string debug, + std::vector tags = {}); + + /** + * Register a kernel to the dispatch table for an operator. + * If dispatch_key is nullopt, then this registers a fallback kernel. + * + * @return A RAII object that manages the lifetime of the registration. + * Once that object is destructed, the kernel will be deregistered. + */ + // NB: steals the inferred function schema, as we may need to hold on to + // it for a bit until the real schema turns up + RegistrationHandleRAII registerImpl( + OperatorName op_name, + std::optional dispatch_key, + KernelFunction kernel, + std::optional cpp_signature, + std::unique_ptr inferred_function_schema, + std::string debug); + + /** + * Given an operator, tells the Dispatcher that we have implemented a fake + * impl for this op in the given Python module. Call this a "pystub". + */ + RegistrationHandleRAII registerPythonModule( + const OperatorName& op_name, + const char* pymodule, + const char* context); + + /** + * Given an operator, throws if we have a pystub. + */ + void throwIfHasPythonModule(OperatorName op_name); + + std::optional> getPyStub( + OperatorName op_name); + + /** + * Register a new operator by name. + */ + RegistrationHandleRAII registerName(OperatorName op_name); + + /** + * Register a fallback kernel for a backend. + * If an operator is called but there is no concrete kernel for the dispatch + * key of the given operator arguments, it will check if there is such a + * fallback kernel for the given dispatch key and, if yes, call that one. + */ + RegistrationHandleRAII registerFallback( + DispatchKey dispatch_key, + KernelFunction kernel, + std::string debug); + + /** + * Use to register whenever we had a TORCH_LIBRARY declaration in the frontend + * API. These invocations are only permitted once per program, so we raise + * an error if this is called again for the same namespace. + */ + RegistrationHandleRAII registerLibrary(std::string ns, std::string debug); + + // ------------------------------------------------------------------------ + // + // Listeners on registrations + // + // ------------------------------------------------------------------------ + + /** + * Add a listener that gets called whenever a new op is registered or an + * existing op is deregistered. Immediately after registering, this listener + * gets called for all previously registered ops, so it can be used to keep + * track of ops registered with this dispatcher. + */ + RegistrationHandleRAII addRegistrationListener( + std::unique_ptr listener); + + void checkInvariants() const; + + // + // ------------------------------------------------------------------------ + // + // Assertions + // + // ------------------------------------------------------------------------ + + /** + * For testing purposes. + * Returns a list of all operators that were created through calls to + * registerImpl(), without any corresponding calls to registerDef(). After + * static initialization is done this is almost certainly a bug, as the + * created OperatorHandle won't have any schema associated with it and users + * calling the op through the dispatcher won't be able to access it + * + * Note that we cannot enforce this invariant "as we go" during static + * initialization, due to undefined static initialization order- we have no + * guarantees over the order in which .def() and .impl() calls are registered + * in the dispatcher at static initialization time. So this function should + * only be called after static initialization. + */ + std::vector findDanglingImpls() const; + + /** + * Useful for inspecting global Dispatcher registration state. + * Returns the names of all operators with a kernel registered for the + * specified DispatchKey. If no DispatchKey is specified, it returns all + * registered operators. + */ + std::vector getRegistrationsForDispatchKey( + std::optional k) const; + + private: + Dispatcher(); + + static int64_t sequenceNumberForRunningRecordFunction( + DispatchKey dispatchKey, + DispatchKeySet dispatchKeySet); + static void runRecordFunction( + at::RecordFunction& guard, + at::RecordFunction::schema_ref_t schema_ref, + DispatchKey dispatchKey, + DispatchKeySet dispatchKeySet); + static void runRecordFunction( + at::RecordFunction& guard, + at::RecordFunction::schema_ref_t schema_ref, + DispatchKey dispatchKey, + DispatchKeySet dispatchKeySet, + c10::ArrayRef args); + +#ifdef FBCODE_CAFFE2 + static bool profilingOperatorEvents(); + static void fireOpStartUSDT(at::RecordFunction::schema_ref_t schema_ref); + static void fireOpEndUSDT(at::RecordFunction::schema_ref_t schema_ref); +#endif // FBCODE_CAFFE2 + + OperatorHandle findOrRegisterSchema_(FunctionSchema&& schema); + OperatorHandle findOrRegisterName_(const OperatorName& op_name); + + void deregisterDef_(const OperatorHandle& op, const OperatorName& op_name); + void deregisterImpl_( + const OperatorHandle& op, + const OperatorName& op_name, + std::optional dispatch_key, + impl::OperatorEntry::AnnotatedKernelContainerIterator kernel_handle); + void deregisterName_(const OperatorHandle& op, const OperatorName& op_name); + void deregisterFallback_(DispatchKey dispatchKey); + void deregisterLibrary_(const std::string& ns); + void cleanup(const OperatorHandle& op, const OperatorName& op_name); + void checkSchemaCompatibility( + const OperatorHandle& op, + const FunctionSchema& schema, + const std::string& debug); + + std::list operators_; +#if !defined(C10_MOBILE) + LeftRight> + operatorLookupTable_; +#else + RWSafeLeftRightWrapper> + operatorLookupTable_; +#endif + // Map from namespace to debug string (saying, e.g., where the library was + // defined) + ska::flat_hash_map libraries_; + + std::array + backendFallbackKernels_; + + std::unique_ptr listeners_; + + // This condition variable gets notified whenever we add a new def/impl to the + // dispatch table. This is primarily used by multipy/torchdeploy, when + // we have multiple interpreters trying to register to the dispatch table. + // In this situation, whenever the non-primary interpreter would have tried + // to register to the dispatch table, instead it will check to see if the + // expected registration has already been made, and if it hasn't, wait on + // this condition variable to see if it was just racing with the primary + // interpreter. + // + // We expect it to be rare for there to be any waiters on this condition + // variable. This is mostly just to help give better diagnostics if + // something goes horribly wrong + std::condition_variable cond_var_; + + // Protect concurrent access to the dispatcher. We store this in a + // `shared_ptr` as we return callbacks that call back into dispatcher methods, + // and we need to be able to handle and guard against the event when the + // `Dispatcher` has been destroyed before the callbacks fire. + std::shared_ptr guard_; +}; + +/** + * This is a handle to an operator schema registered with the dispatcher. + * This handle can be used to register kernels with the dispatcher or + * to lookup a kernel for a certain set of arguments. + */ +class TORCH_API OperatorHandle { + template + friend struct std::hash; + + public: + OperatorHandle(OperatorHandle&&) noexcept = default; + OperatorHandle& operator=(OperatorHandle&&) noexcept = default; + OperatorHandle(const OperatorHandle&) = default; + OperatorHandle& operator=(const OperatorHandle&) = default; + // NOLINTNEXTLINE(performance-trivially-destructible) + ~OperatorHandle(); + + const OperatorName& operator_name() const { + return operatorDef_->op.operator_name(); + } + + bool hasSchema() const { + return operatorDef_->op.hasSchema(); + } + + const FunctionSchema& schema() const { + return operatorDef_->op.schema(); + } + + const std::string& debug() const { + return operatorDef_->op.debug(); + } + + std::string dumpState() const { + return operatorDef_->op.dumpState(); + } + + bool hasKernelForDispatchKey(DispatchKey k) const { + return operatorDef_->op.hasKernelForDispatchKey(k); + } + + bool isKernelFallthroughKernel(DispatchKey k) const { + return operatorDef_->op.kernelForDispatchKey(k).isFallthrough(); + } + + bool hasKernelForAnyDispatchKey(DispatchKeySet k) const { + return operatorDef_->op.hasKernelForAnyDispatchKey(k); + } + + bool hasComputedKernelForDispatchKey(DispatchKey k) const { + return operatorDef_->op.hasComputedKernelForDispatchKey(k); + } + + std::string dumpComputedTable() const { + return operatorDef_->op.dumpComputedTable(); + } + + void checkInvariants() const { + return operatorDef_->op.checkInvariants(); + } + + c10::ArrayRef getTags() const { + return operatorDef_->op.getTags(); + } + + void setReportErrorCallback_(std::unique_ptr callback) { + operatorDef_->op.setReportErrorCallback_(std::move(callback)); + } + + bool hasTag(const at::Tag& tag) const { + for (const auto& tag_ : getTags()) { + if (tag == tag_) { + return true; + } + } + return false; + } + + template + TypedOperatorHandle typed() const { + // NB: This assert is not 100% sound: you can retrieve a typed() operator + // handle prior to ANY C++ signature being registered on the operator + // and the check will say everything is OK (at which point you can then + // smuggle in a kernel that is typed incorrectly). For everything + // in core library this won't happen, because all the static registrations + // will be done by the time a typed() handle is acquired. +#if !defined C10_MOBILE + operatorDef_->op.assertSignatureIsCorrect(); + if (fn_has_symint::value) { + operatorDef_->op.assertSignatureIsCorrect< + typename fn_remove_symint::type>(); + } +#endif + return TypedOperatorHandle(operatorIterator_); + } + + void callBoxed(Stack* stack) const { + c10::Dispatcher::singleton().callBoxed(*this, stack); + } + + void callBoxed(Stack& stack) const { + callBoxed(&stack); + } + + void callBoxedForDispatchKey(DispatchKey dk, Stack& stack) const { + c10::Dispatcher::singleton().callBoxedForDispatchKey(*this, dk, &stack); + } + + void redispatchBoxed(DispatchKeySet ks, Stack* stack) const { + c10::Dispatcher::singleton().redispatchBoxed(*this, ks, stack); + } + + template + PyObject* getPythonOp( + c10::impl::PyInterpreter* self_interpreter, + F slow_accessor) const { + return operatorDef_->op.getPythonOp(self_interpreter, slow_accessor); + } + + bool operator==(const OperatorHandle& other) const { + return operatorDef_ == other.operatorDef_; + } + + bool operator!=(const OperatorHandle& other) const { + return operatorDef_ != other.operatorDef_; + } + + private: + explicit OperatorHandle( + std::list::iterator operatorIterator) + : operatorDef_(&*operatorIterator), operatorIterator_(operatorIterator) {} + friend class Dispatcher; + template + friend class TypedOperatorHandle; + + // Storing a direct pointer to the OperatorDef even though we + // already have the iterator saves an instruction in the critical + // dispatch path. The iterator is effectively a + // pointer-to-std::list-node, and (at least in libstdc++'s + // implementation) the element is at an offset 16 bytes from that, + // because the prev/next pointers come first in the list node + // struct. So, an add instruction would be necessary to convert from the + // iterator to an OperatorDef*. + Dispatcher::OperatorDef* operatorDef_; + + // We need to store this iterator in order to make + // Dispatcher::cleanup() fast -- it runs a lot on program + // termination (and presuambly library unloading). + std::list::iterator operatorIterator_; +}; + +/** + * This is a handle to an operator schema registered with the dispatcher. + * It holds the same information as an OperatorHandle, but it is templated + * on the operator arguments and allows calling the operator in an + * unboxed way. + */ +template +class TypedOperatorHandle final { + static_assert( + guts::false_t(), + "FuncType in OperatorHandle::typed was not a valid function type"); +}; +template +class TypedOperatorHandle final : public OperatorHandle { + public: + TypedOperatorHandle(TypedOperatorHandle&&) noexcept = default; + TypedOperatorHandle& operator=(TypedOperatorHandle&&) noexcept = default; + TypedOperatorHandle(const TypedOperatorHandle&) = default; + TypedOperatorHandle& operator=(const TypedOperatorHandle&) = default; + + // See [Note: Argument forwarding in the dispatcher] for why Args doesn't use + // && + C10_ALWAYS_INLINE Return call(Args... args) const { + return c10::Dispatcher::singleton().call( + *this, std::forward(args)...); + } + + // See [Note: Argument forwarding in the dispatcher] for why Args doesn't use + // && + C10_ALWAYS_INLINE Return + redispatch(DispatchKeySet currentDispatchKeySet, Args... args) const { + return c10::Dispatcher::singleton().redispatch( + *this, currentDispatchKeySet, std::forward(args)...); + } + + private: + explicit TypedOperatorHandle( + std::list::iterator operatorIterator) + : OperatorHandle(operatorIterator) {} + friend class OperatorHandle; +}; + +namespace detail { +template +inline void unused_arg_(const Args&...) {} + +// CaptureKernelCall is intended to capture return values from Dispatcher +// unboxed kernel calls. A record function may request to get outputs from the +// kernel calls. For boxed kernels, it's straightforward, the returned values +// are in the stack object. The stack can be passed to record functions. For +// unboxed kernels, we need to handle different kinds of return values, cache +// them temporarily, then release the values for the actual function call +// return. +template +struct CaptureKernelCall { + template + CaptureKernelCall( + const F& kernel, + const TypedOperatorHandle& op, + const DispatchKeySet& dispatchKeySet, + Args&&... args) + // Calls the kernel and capture the result in output_. + : output_{kernel.template call( + op, + dispatchKeySet, + std::forward(args)...)} {} + // Wraps the return values in a Stack. + Stack getOutputs() { + Stack stack; + impl::push_outputs::copy(output_, &stack); + return stack; + } + // Since we are returning the output_, we don't expect the output_ to be used + // afterward. Copy elision and RVO do not apply to class data members. Using + // move semantic to avoid copies when possible. + ReturnType release() && { + return std::move(output_); + } + + private: + ReturnType output_; +}; + +// Handle the lvalue reference differently since it should not be moved. +template <> +inline at::Tensor& CaptureKernelCall::release() && { + return output_; +} + +// Handle case where the kernel returns void. +template <> +struct CaptureKernelCall { + template + CaptureKernelCall( + const F& kernel, + const TypedOperatorHandle& op, + const DispatchKeySet& dispatchKeySet, + Args&&... args) { + // Calling the kernel and no need to capture void. + kernel.template call( + op, dispatchKeySet, std::forward(args)...); + } + Stack getOutputs() { + return Stack(); + } + void release() && {} +}; + +TORCH_API void _print_dispatch_trace( + const std::string& label, + const std::string& op_name, + const DispatchKeySet& dispatchKeySet); + +} // namespace detail + +// See [Note: Argument forwarding in the dispatcher] for why Args doesn't use && +template +inline Return Dispatcher::callWithDispatchKeySlowPath( + const TypedOperatorHandle& op, + at::StepCallbacks& stepCallbacks, + DispatchKeySet dispatchKeySet, + const KernelFunction& kernel, + Args... args) { + // If callbacks need inputs, we box the arguments and pass them to the guard. + // Note: For perf reasons we wouldn't want to prematurely box the arguments. + at::RecordFunction guard(std::move(stepCallbacks)); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(op.operatorDef_->op.isObserved()); + auto dispatchKey = dispatchKeySet.highestPriorityTypeId(); + auto& schema = op.schema(); + auto schema_ref = std::reference_wrapper(schema); + constexpr auto num_boxed_args = impl::boxed_size(); + if constexpr (num_boxed_args != 0) { + if (guard.needsInputs()) { + // If we used std::array here, we would + // have to spend time default constructing the IValues in + // boxedArgs. aligned_storage has no such requirement. + // NOLINTNEXTLINE(*array*) + alignas(IValue) std::byte boxedArgs[num_boxed_args * sizeof(IValue)]; + // For debugging only; could be removed (but the compiler will do + // that for us and it's nice to have the extra assurance of + // correctness from our debug builds). + IValue* boxedArgsPtr = reinterpret_cast(boxedArgs); + impl::boxArgsToStack(boxedArgsPtr, args...); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + reinterpret_cast(boxedArgsPtr) == + boxedArgs + num_boxed_args * sizeof(IValue)); + // I don't *think* we need std::launder here, because IValue has + // no subclasses and no const or reference fields. + runRecordFunction( + guard, + schema_ref, + dispatchKey, + dispatchKeySet, + c10::ArrayRef( + reinterpret_cast(boxedArgs), num_boxed_args)); + boxedArgsPtr = reinterpret_cast(boxedArgs); + for (size_t ii = 0; ii < num_boxed_args; ++ii) { + (boxedArgsPtr + ii)->~IValue(); + } + } else { + runRecordFunction(guard, schema_ref, dispatchKey, dispatchKeySet); + } + } else { + runRecordFunction(guard, schema_ref, dispatchKey, dispatchKeySet); + } + + if (C10_UNLIKELY(guard.needsOutputs())) { + // Calls the kernel and capture the output temporarily to pass to + // RecordFunction. + detail::CaptureKernelCall captureKernelCall( + kernel, op, dispatchKeySet, std::forward(args)...); + guard.setOutputs(captureKernelCall.getOutputs()); + // Releases the captured output to return to caller. + return std::move(captureKernelCall).release(); + } + + // keeping the guard alive while executing the kernel + return kernel.template call( + op, dispatchKeySet, std::forward(args)...); +} + +// See [Note: Argument forwarding in the dispatcher] for why Args doesn't use && +template +C10_ALWAYS_INLINE_UNLESS_MOBILE Return Dispatcher::call( + const TypedOperatorHandle& op, + Args... args) const { + auto dispatchKeySet = + op.operatorDef_->op.dispatchKeyExtractor() + .template getDispatchKeySetUnboxed(args...); +#if defined(HAS_TORCH_SHOW_DISPATCH_TRACE) || !defined(NDEBUG) + DispatchTraceNestingGuard debug_guard; + if (show_dispatch_trace()) { + detail::_print_dispatch_trace( + "[call]", toString(op.operator_name()), dispatchKeySet); + } +#endif + const KernelFunction& kernel = op.operatorDef_->op.lookup(dispatchKeySet); +#ifndef PYTORCH_DISABLE_PER_OP_PROFILING + auto step_callbacks = + at::getStepCallbacksUnlessEmpty(at::RecordScope::FUNCTION); + if (C10_UNLIKELY( + step_callbacks.has_value() && op.operatorDef_->op.isObserved())) { + return callWithDispatchKeySlowPath( + op, + *step_callbacks, + dispatchKeySet, + kernel, + std::forward(args)...); + } +#endif // PYTORCH_DISABLE_PER_OP_PROFILING + +#ifdef FBCODE_CAFFE2 + if (profilingOperatorEvents()) { + struct FireOpRAII { + FireOpRAII(at::RecordFunction::schema_ref_t schema_ref) + : schema_ref_(schema_ref) { + fireOpStartUSDT(schema_ref); + } + ~FireOpRAII() { + fireOpEndUSDT(schema_ref_); + } + at::RecordFunction::schema_ref_t schema_ref_; + } event(op.schema()); + return kernel.template call( + op, dispatchKeySet, std::forward(args)...); + } else { + return kernel.template call( + op, dispatchKeySet, std::forward(args)...); + } +#else + return kernel.template call( + op, dispatchKeySet, std::forward(args)...); +#endif // FBCODE_CAFFE2 +} + +// See [Note: Argument forwarding in the dispatcher] for why Args doesn't use && +template +inline Return Dispatcher::redispatch( + const TypedOperatorHandle& op, + DispatchKeySet currentDispatchKeySet, + Args... args) const { + // do not use RecordFunction on redispatch +#if defined(HAS_TORCH_SHOW_DISPATCH_TRACE) || !defined(NDEBUG) + DispatchTraceNestingGuard debug_guard; + if (show_dispatch_trace()) { + detail::_print_dispatch_trace( + "[redispatch]", toString(op.operator_name()), currentDispatchKeySet); + } +#endif + const KernelFunction& kernel = + op.operatorDef_->op.lookup(currentDispatchKeySet); + return kernel.template call( + op, currentDispatchKeySet, std::forward(args)...); +} + +inline void Dispatcher::callBoxed(const OperatorHandle& op, Stack* stack) + const { + // note: this doesn't need the mutex because write operations on the list keep + // iterators intact. + const auto& entry = op.operatorDef_->op; + auto dispatchKeySet = + entry.dispatchKeyExtractor().getDispatchKeySetBoxed(stack); +#if defined(HAS_TORCH_SHOW_DISPATCH_TRACE) || !defined(NDEBUG) + DispatchTraceNestingGuard debug_guard; + if (show_dispatch_trace()) { + detail::_print_dispatch_trace( + "[callBoxed]", toString(op.operator_name()), dispatchKeySet); + } +#endif + const auto& kernel = entry.lookup(dispatchKeySet); +#ifndef PYTORCH_DISABLE_PER_OP_PROFILING + auto step_callbacks = + at::getStepCallbacksUnlessEmpty(at::RecordScope::FUNCTION); + if (C10_UNLIKELY(step_callbacks.has_value() && entry.isObserved())) { + at::RecordFunction guard(std::move(*step_callbacks)); + auto dispatchKey = dispatchKeySet.highestPriorityTypeId(); + auto& schema = op.schema(); + auto schema_ref = std::reference_wrapper(schema); + guard.needsInputs() + ? runRecordFunction( + guard, + schema_ref, + dispatchKey, + dispatchKeySet, + c10::ArrayRef(stack->data(), stack->size())) + : runRecordFunction(guard, schema_ref, dispatchKey, dispatchKeySet); + + // keeping the guard alive while executing the kernel + kernel.callBoxed(op, dispatchKeySet, stack); + + if (C10_UNLIKELY(guard.needsOutputs())) { + guard.setOutputs(*stack); + } + return; + } +#endif // PYTORCH_DISABLE_PER_OP_PROFILING + kernel.callBoxed(op, dispatchKeySet, stack); +} + +// NB: this doesn't count as a "true" dispatcher jump, so no instrumentation +inline void Dispatcher::callBoxedForDispatchKey( + const OperatorHandle& op, + DispatchKey dk, + Stack* stack) const { + // note: this doesn't need the mutex because write operations on the list keep + // iterators intact. + const auto& entry = op.operatorDef_->op; + // We still compute this as we're obligated to pass it on to the internal + // kernel, if it is a boxed fallback + auto dispatchKeySet = + entry.dispatchKeyExtractor().getDispatchKeySetBoxed(stack); + const auto& kernel = ([&]() { + if (op.hasKernelForDispatchKey(dk)) { + return entry.kernelForDispatchKey(dk); + } else { + auto idx = getDispatchTableIndexForDispatchKey(dk); + TORCH_INTERNAL_ASSERT(idx >= 0); + return backendFallbackKernels_[idx].kernel; + } + })(); + kernel.callBoxed(op, dispatchKeySet, stack); +} + +inline void Dispatcher::redispatchBoxed( + const OperatorHandle& op, + DispatchKeySet dispatchKeySet, + Stack* stack) const { + // note: this doesn't need the mutex because write operations on the list keep + // iterators intact. + const auto& entry = op.operatorDef_->op; +#if defined(HAS_TORCH_SHOW_DISPATCH_TRACE) || !defined(NDEBUG) + DispatchTraceNestingGuard debug_guard; + if (show_dispatch_trace()) { + detail::_print_dispatch_trace( + "[redispatchBoxed]", toString(op.operator_name()), dispatchKeySet); + } +#endif + const auto& kernel = entry.lookup(dispatchKeySet); + return kernel.callBoxed(op, dispatchKeySet, stack); +} + +} // namespace c10 + +namespace std { + +template <> +struct hash { + size_t operator()(const c10::OperatorHandle& op) const noexcept { + return std::hash{}(static_cast(op.operatorDef_)); + } +}; + +} // namespace std diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/ObservedOperators.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/ObservedOperators.h new file mode 100644 index 0000000000000000000000000000000000000000..1741171fbf00412647178b2210071cee36928e54 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/ObservedOperators.h @@ -0,0 +1,17 @@ +#pragma once + +#include +#include +#include + +namespace c10 { + +struct TORCH_API ObservedOperators { + ObservedOperators() = delete; + + static bool isObserved(const OperatorName& name); + + static std::unordered_set& getUnobservedOperatorList(); +}; + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/OperatorEntry.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/OperatorEntry.h new file mode 100644 index 0000000000000000000000000000000000000000..83200ff9c94ffcf4325a3fc8cb9844c699f9c1b7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/OperatorEntry.h @@ -0,0 +1,335 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include + +#include +#include +#include + +#ifdef C10_MOBILE +#define C10_DISPATCHER_ONE_KERNEL_PER_DISPATCH_KEY +#endif + +namespace c10 { + +class Dispatcher; + +namespace impl { + +// This data structure represents a kernel that was registered to us from a +// user. Unlike KernelFunction, AnnotatedKernel contains some extra metadata +// about the kernel that isn't necessary for actual dispatching (this is why +// we don't put AnnotatedKernel in the actual DispatchTable), but is useful for +// giving good error messages. +struct AnnotatedKernel final { + AnnotatedKernel( + KernelFunction k, + std::unique_ptr s, + std::string d) + : kernel(std::move(k)), + inferred_function_schema(std::move(s)), + debug(std::move(d)) {} + AnnotatedKernel() = default; + KernelFunction kernel; + std::unique_ptr inferred_function_schema; + // A little debug string to help us identify the kernel in question. + // Most importantly it records the TORCH_LIBRARY block that did the + // registration. + std::string debug; +}; + +// This data structure represents operator schema, with metadata specifying +// where the registration of this schema occurred +struct AnnotatedSchema final { + AnnotatedSchema(FunctionSchema s, std::string d) + : schema(std::move(s)), debug(std::move(d)) {} + FunctionSchema schema; + std::string debug; +}; + +// Internal data structure that records information about a specific operator. +// It's not part of the public API; typically, users will interact with +// OperatorHandle instead. +// +// Concurrent writes to OperatorEntry are protected by the GLOBAL Dispatcher +// lock (this is important because some methods in OperatorEntry access +// dispatcher state) +class TORCH_API OperatorEntry final { + public: + explicit OperatorEntry(OperatorName&& operator_name); + + OperatorEntry(const OperatorEntry&) = delete; + OperatorEntry(OperatorEntry&&) noexcept = delete; + OperatorEntry& operator=(const OperatorEntry&) = delete; + OperatorEntry& operator=(OperatorEntry&&) noexcept = delete; + + const FunctionSchema& schema() const { + TORCH_INTERNAL_ASSERT( + schema_.has_value(), + "Tried to access the schema for ", + name_, + " which doesn't have a schema registered yet"); + return schema_->schema; + } + const std::string& debug() const { + TORCH_INTERNAL_ASSERT(schema_.has_value()); + return schema_->debug; + } + bool hasSchema() const { + return schema_.has_value(); + } + + bool isObserved() const { + return is_observed_; + } + + // We may allocate an OperatorEntry for an operator even when we don't + // have a schema. When we receive the schema registration, we post + // facto register a schema. + // + // NB: registerSchema/deregisterSchema are not idempotent; if you + // attempt to register a schema when one is already present or vice + // versa that is an error. (Refcounting for the registrations is + // handled in the OperatorHandle in Dispatcher) + void registerSchema( + FunctionSchema&&, + std::string&& debug, + std::vector tags = {}); + void deregisterSchema(); + + const OperatorName& operator_name() const { + return name_; + } + +#ifdef C10_DISPATCHER_ONE_KERNEL_PER_DISPATCH_KEY + using AnnotatedKernelContainer = std::array; +#else + using AnnotatedKernelContainer = std::list; +#endif + using AnnotatedKernelContainerIterator = AnnotatedKernelContainer::iterator; + + // Why are kernels and fallback asymmetric? It has to do with ownership. + // Kernels and the computed dispatch tables for them are canonically + // owned by OperatorEntry, but backend fallbacks are specified once + // and apply for all operators, so they should be owned by Dispatcher. + // However, the registration of a backend fallback affects the + // state of the computed dispatch table, so when a backend fallback + // is updated, we need to update the operator tables too. Thus, + // registerKernel is the mechanism by which we give kernels to + // operator entry to own (and update dispatch table), but we only + // need a non-owning mechanism to update fallback. + + // Precondition: Dispatcher::mutex_ is held + // Postcondition: caller is responsible for disposing of the kernel + AnnotatedKernelContainerIterator registerKernel( + const Dispatcher& dispatcher, + std::optional dispatch_key, + KernelFunction kernel, + std::optional cpp_signature, + std::unique_ptr inferred_function_schema, + std::string debug); + + // Precondition: Dispatcher::mutex_ is held + void deregisterKernel_( + const Dispatcher& dispatcher, + std::optional dispatch_key, + AnnotatedKernelContainerIterator kernel); + + // Precondition: Dispatcher::mutex_ is held + void updateFallback(const Dispatcher& dispatcher, DispatchKey dispatch_key); + + // Precondition: Dispatcher::mutex_ is held + void updateSchemaAliasAnalysis(AliasAnalysisKind a) { + TORCH_INTERNAL_ASSERT(schema_.has_value()); + schema_->schema.setAliasAnalysis(a); + } + + std::string dumpComputedTable() const; + std::string dumpState() const; + void checkInvariants() const; + + const DispatchKeyExtractor& dispatchKeyExtractor() const { + return dispatchKeyExtractor_; + } + + // Asserts that the given FuncType is correct for calling this operator in an + // unboxed way. + template + inline void assertSignatureIsCorrect() { + assertSignatureIsCorrect( + CppSignature::make(), fn_has_symint::value); + } + + void assertSignatureIsCorrect( + const CppSignature& call_signature, + bool has_symint) const; + + [[noreturn]] void reportError(DispatchKey dispatchKey) const; + + const KernelFunction& lookup(DispatchKeySet ks) const { + const auto idx = ks.getDispatchTableIndexForDispatchKeySet(); + if (C10_UNLIKELY(idx == -1)) { + reportError(ks.highestPriorityTypeId()); + } + const auto& kernel = dispatchTable_[idx]; + // A valid kernel *always* has a boxed kernel and *may* have an + // unboxed kernel. However, we typically do unboxed calls in at:: + // APIs, where the kernel 1) will very likely be valid and 2) + // should have an unboxed kernel. Checking the unboxed kernel + // first will allow us to avoid touching the boxed kernel at all + // in the common case. + if (C10_UNLIKELY(!kernel.isValidUnboxed())) { + if (!kernel.isValid()) { + reportError(ks.highestPriorityTypeId()); + } + } + return kernel; + } + + std::string listAllDispatchKeys() const; + + // Returns true if kernel_ has entry for any key in ks. + // + // Invariant: There are no alias keys in the passed-in dispatch key set. + // Note [No Alias Keys in DispatchKeySet] + // Alias keys should be checked using `hasKernelForDispatchKey` + // Alias keys shouldn't go inside of a DispatchKeySet, since they can + // technically have a value > 63 (causing overflow). + bool hasKernelForAnyDispatchKey(DispatchKeySet ks) const; + // Returns true if kernel_ has entry for a particular key. + bool hasKernelForDispatchKey(DispatchKey k) const; + // Retrieves the kernel entry at a particular key. Symmetric with + // hasKernelForDispatchKey. To get the AnnotatedKernel, see + // getKernelForDispatchKey (private) + const KernelFunction& kernelForDispatchKey(DispatchKey k) const; + // Returns true if the "computed table" has an entry for a particular key. + bool hasComputedKernelForDispatchKey(DispatchKey k) const; + // Returns all the operator tags added at the time of registration + const std::vector& getTags() const; + void setReportErrorCallback_(std::unique_ptr callback); + + template + PyObject* getPythonOp(PyInterpreter* self_interpreter, F slow_accessor) + const { + return py_cache_.ptr_or(self_interpreter, slow_accessor); + } + + private: + OperatorName name_; + std::optional schema_; +#ifndef C10_MOBILE + std::vector tags_; +#endif + std::array dispatchTable_; + DispatchKeyExtractor dispatchKeyExtractor_; + // Pointer to the torch.ops.ns.op.overload object for speed + c10::PyHandleCache py_cache_; + + // kernels_ stores all registered kernels for the corresponding dispatch key + // and catchAllKernels_ stores the catch-all kernels. + // If an operator library gets loaded that overwrites an already existing + // kernel, both kernels will be in that list but only the newer one will be in + // dispatchTable. If any of the kernels go away (say the library gets + // unloaded), we remove the kernel from this list and update the + // dispatchTable if necessary. + // Kernels in the list are ordered by registration time descendingly, + // newer registrations are before older registrations. + // We do not combine dispatchTable and kernels into one hash map because + // kernels is a larger data structure and accessed quite infrequently + // while dispatchTable is accessed often and should be kept small to fit + // into CPU caches. + // Invariants: + // - dispatchTable[dispatch_key] == kernels_[dispatch_key].front() + // - dispatchTable[dispatch_key] does not exist if and only if + // kernels_[dispatch_key] does not exist + // - If kernels_[dispatch_key] exists, then it has elements. + // It is never an empty list. + // + // Why do we do that? + // ----- + // We mostly do this to enable Jupyter notebooks where a cell registering + // a kernel could be executed multiple times and the later execution + // should overwrite the earlier one. Note that this still fails when the + // function schema changed between the executions, but it works as long + // as the function schema didn't change. A better solution would be to + // unload the old extension library from the Jupyter cell when the cell is + // re-executed and then only allow one kernel here, i.e. error if a kernel + // is already registered, but that's a lot of effort to implement and + // currently not high-pri. + ska::flat_hash_map< + DispatchKey, +#ifdef C10_DISPATCHER_ONE_KERNEL_PER_DISPATCH_KEY + // On mobile, we needn't worry about Jupyter notebooks. + std::array +#else + std::list +#endif + > + kernels_; + + const AnnotatedKernel& missingKernel() const; + const AnnotatedKernel& ambiguousAutogradOtherKernel() const; + + // cpp_signature_ stores function signature if any of + // the kernels was created in a way that allowed us to know the function + // signature (i.e. by supplying an unboxed C++ kernel function). + // If this is set, it will be used to check that future kernel + // registrations match and it will be used in unboxed function calls + // to verify their arguments against the known function signature. + struct CppSignatureWithDebug { + CppSignature signature; + std::string debug; + std::optional dispatch_key; + }; + std::optional cpp_signature_; + std::optional sym_cpp_signature_; + + // A Python custom error handler for OperatorEntry::reportError + std::unique_ptr report_error_callback_; + + // Whether this operator needs to be observed with RecordFunction + const bool is_observed_; + + [[noreturn]] void reportSignatureError( + const CppSignature& call_signature, + const CppSignatureWithDebug& saved_signature) const; + const KernelFunction& computeDispatchTableEntry( + const c10::Dispatcher& dispatcher, + DispatchKey dispatch_key) const; + std::pair + computeDispatchTableEntryWithDebug( + const c10::Dispatcher& dispatcher, + DispatchKey dispatch_key) const; + // This function re-establishes the invariant that dispatchTable + // contains the front element from the kernels list for a given runtime + // dispatch key. + void updateDispatchTableEntry_( + const c10::Dispatcher& dispatcher, + DispatchKey dispatch_key); + // Like above, but also handles alias dispatch keys. + void updateDispatchTable_( + const c10::Dispatcher& dispatcher, + DispatchKey dispatch_key); + // Like above, but for ALL entries in the dispatch table. + void updateDispatchTableFull_(const c10::Dispatcher& dispatcher); + // Retrieves a pointer to AnnotatedKernel at + // kernels_.at(dispatch_key).front(). + const AnnotatedKernel* getKernelForDispatchKey( + DispatchKey dispatch_key) const; +}; + +} // namespace impl +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/OperatorOptions.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/OperatorOptions.h new file mode 100644 index 0000000000000000000000000000000000000000..d66686c1bb4690a3b39d1ed959167e0a375d0319 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/OperatorOptions.h @@ -0,0 +1,30 @@ +#pragma once + +#include + +namespace c10 { + +enum class AliasAnalysisKind : uint8_t { + INTERNAL_SPECIAL_CASE, + CONSERVATIVE, // The most conservative alias analysis type, assumes + // side-effects. This is the default analysis. + FROM_SCHEMA, + PURE_FUNCTION +}; + +#if !defined(_MSC_VER) +constexpr // Our current MSVC version has a bug that doesn't allow this to be + // constexpr. +#endif + inline const char* + toString(AliasAnalysisKind aliasAnalysisKind) { + return (aliasAnalysisKind == AliasAnalysisKind::CONSERVATIVE) ? "CONSERVATIVE" + : (aliasAnalysisKind == AliasAnalysisKind::FROM_SCHEMA) ? "FROM_SCHEMA" + : (aliasAnalysisKind == AliasAnalysisKind::PURE_FUNCTION) + ? "PURE_FUNCTION" + : (aliasAnalysisKind == AliasAnalysisKind::INTERNAL_SPECIAL_CASE) + ? "INTERNAL_SPECIAL_CASE" + : "UNKNOWN"; +} + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/RegistrationHandleRAII.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/RegistrationHandleRAII.h new file mode 100644 index 0000000000000000000000000000000000000000..a5a88aafed631a88efa35f8526ace8d8b1f293fa --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dispatch/RegistrationHandleRAII.h @@ -0,0 +1,36 @@ +#pragma once + +#include + +namespace c10 { + +class RegistrationHandleRAII final { + public: + explicit RegistrationHandleRAII(std::function onDestruction) + : onDestruction_(std::move(onDestruction)) {} + + ~RegistrationHandleRAII() { + if (onDestruction_) { + onDestruction_(); + } + } + + RegistrationHandleRAII(const RegistrationHandleRAII&) = delete; + RegistrationHandleRAII& operator=(const RegistrationHandleRAII&) = delete; + + RegistrationHandleRAII(RegistrationHandleRAII&& rhs) noexcept + : onDestruction_(std::move(rhs.onDestruction_)) { + rhs.onDestruction_ = nullptr; + } + + RegistrationHandleRAII& operator=(RegistrationHandleRAII&& rhs) noexcept { + onDestruction_ = std::move(rhs.onDestruction_); + rhs.onDestruction_ = nullptr; + return *this; + } + + private: + std::function onDestruction_; +}; + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dynamic_type.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dynamic_type.h new file mode 100644 index 0000000000000000000000000000000000000000..2e7b7cbc5d312d346413c3f7b4d032d86382cb35 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/dynamic_type.h @@ -0,0 +1,244 @@ +#pragma once + +#include +#include +#include + +#include +#include + +namespace c10 { + +using DynamicTypeBits = std::uint32_t; +#define DYNAMIC_TYPE_BIT(x) (1u << x) + +constexpr DynamicTypeBits kDynamicCovariantTypeBit = DYNAMIC_TYPE_BIT(31); +constexpr DynamicTypeBits kDynamicAnyTypeBit = DYNAMIC_TYPE_BIT(30); + +constexpr DynamicTypeBits kDynamicNoneTypeBit = DYNAMIC_TYPE_BIT(1); +constexpr DynamicTypeBits kDynamicIntTypeBit = DYNAMIC_TYPE_BIT(3); +constexpr DynamicTypeBits kDynamicFloatTypeBit = DYNAMIC_TYPE_BIT(4); +constexpr DynamicTypeBits kDynamicComplexTypeBit = DYNAMIC_TYPE_BIT(5); +constexpr DynamicTypeBits kDynamicListTypeBit = DYNAMIC_TYPE_BIT(7); +constexpr DynamicTypeBits kDynamicTupleTypeBit = DYNAMIC_TYPE_BIT(8); +constexpr DynamicTypeBits kDynamicClassTypeBit = DYNAMIC_TYPE_BIT(10); + +#define FORALL_DYNAMIC_TYPES(_) \ + _(Tensor, DYNAMIC_TYPE_BIT(0), 1) \ + _(None, kDynamicNoneTypeBit, 1) \ + _(Bool, DYNAMIC_TYPE_BIT(2), 1) \ + _(Int, kDynamicIntTypeBit, 1) \ + _(Float, kDynamicFloatTypeBit, 1) \ + _(Complex, kDynamicComplexTypeBit, 1) \ + _(Number, \ + (kDynamicIntTypeBit | kDynamicFloatTypeBit | kDynamicComplexTypeBit), \ + 1) \ + _(String, DYNAMIC_TYPE_BIT(6), 1) \ + _(List, kDynamicListTypeBit, 0) \ + _(Tuple, (kDynamicTupleTypeBit | kDynamicCovariantTypeBit), 0) \ + _(Dict, DYNAMIC_TYPE_BIT(9), 0) \ + _(Class, kDynamicClassTypeBit, 0) \ + _(Optional, \ + (DYNAMIC_TYPE_BIT(11) | kDynamicNoneTypeBit | kDynamicCovariantTypeBit), \ + 0) \ + _(AnyList, (kDynamicListTypeBit | kDynamicAnyTypeBit), 1) \ + _(AnyTuple, \ + (kDynamicTupleTypeBit | kDynamicCovariantTypeBit | kDynamicAnyTypeBit), \ + 1) \ + _(DeviceObj, DYNAMIC_TYPE_BIT(12), 1) \ + _(StreamObj, DYNAMIC_TYPE_BIT(13), 1) \ + _(Capsule, DYNAMIC_TYPE_BIT(14), 1) \ + _(Generator, DYNAMIC_TYPE_BIT(15), 1) \ + _(Storage, DYNAMIC_TYPE_BIT(16), 1) \ + _(Var, DYNAMIC_TYPE_BIT(17), 0) \ + _(AnyClass, (kDynamicClassTypeBit | kDynamicAnyTypeBit), 1) \ + _(QScheme, DYNAMIC_TYPE_BIT(18), 1) \ + _(Quantizer, DYNAMIC_TYPE_BIT(19), 1) \ + _(AnyEnum, DYNAMIC_TYPE_BIT(20), 1) \ + _(RRef, DYNAMIC_TYPE_BIT(21), 0) \ + _(Future, DYNAMIC_TYPE_BIT(22), 0) \ + _(Await, DYNAMIC_TYPE_BIT(23), 0) \ + _(Any, 0xffffffff, 1) + +#define FORALL_DYNAMIC_TYPES_FAKE(_) \ + _(ScalarType, kDynamicIntTypeBit, 1) \ + _(Layout, kDynamicIntTypeBit, 1) \ + _(SymInt, kDynamicIntTypeBit, 1) \ + _(MemoryFormat, kDynamicIntTypeBit, 1) + +#define FORWARD_DECL_TYPE(NAME, _, __) struct NAME ## Type; + FORALL_DYNAMIC_TYPES(FORWARD_DECL_TYPE) + FORALL_DYNAMIC_TYPES_FAKE(FORWARD_DECL_TYPE) +#undef FORWARD_DECL_TYPE + +class DynamicType; +using DynamicTypePtr = std::shared_ptr; + +/** + * DynamicType is designed as a low dependency type system for TorchScript. The + * existing JIT types are used for both compilation and runtime, which makes + * sense for server contexts because we often compile and run the model in + * the same process, however this doesn't hold for mobile devices where we + * always compiles a model ahead of time, therefore there will be dependencies + * which are not needed, but built with mobile runtime causing binary size + * bloat, by design. Every basic type like Int, Bool or String will bring their + * vtable, typeinfo, constructor, destructor and even more data from their + * specializations for STL types to the binary causing a long tail bloat. + * + * The core problem is about the complexity to implement and maintain a single + * type system for both analysis and execution purposes. Although they should + * have the exactly same semantics, in practice implement a unified abstraction + * adds conceptual and representational overhead for both sides of the world. + * + * To address the issues, DynamicType implements a minimal subset of JIT types + * and uses a generic algorithm to test all subtyping relations. To achieve + * this, we assign each dynamic type a single integer tag to represent its + * semantics. More specifically, a dynamic type is defined as a set of "control + * bits" and "data bits", where control bits describe the special behavior when + * testing a type and data bits map to identity of each nominal type. We use bit + * operations to perform all the tests. + * + * For example, a "covariant bit" is a control bit used to describe if a type + * is covariant, right now the most used one is tuple type, and in addition to + * the control bit, tuple type's data bit is the 8th bit from the LSB. Control + * bits start from MSB and data bits start from LSB. + * + * If two types are equal, then they are subtype of each other, also if the bits + * from one type tag is subset of the other tag, it automatically becomes a + * subtype of the other. This simplifies the subtyping logic a lot, and over the + * long term it is possible to adopt this scheme on the server side as well. + * Special cases can be added but they generally should not take too much code + * size. + * + * DynamicType may or may not inherit from c10::Type because it's not the core + * requirement of DynamicType to interface with existing JIT types, but we might + * want to inherit from c10::Type to reduce the migration cost. + */ +class DynamicType : public SharedType { + using ClassTypePtr = std::shared_ptr; + + /** + * A implementation detail to support NamedTuple. + */ + struct LabeledDynamicType { + std::optional label; + DynamicTypePtr ty; + explicit LabeledDynamicType(DynamicTypePtr t) : ty(std::move(t)) {} + + bool equals(const LabeledDynamicType& other) const; + bool isSubtypeOf(const LabeledDynamicType& other) const; + }; + + public: + // TODO Change Ptr to DynamicTypePtr when all migrations are done. + using Ptr = TypePtr; + using ElementType = DynamicType; + ~DynamicType() override; + + struct Arguments { + Arguments() = default; + Arguments(c10::ArrayRef); + Arguments(const std::vector&, c10::ArrayRef); + std::vector elems; + }; + + enum class Tag : DynamicTypeBits { +#define DYNAMIC_TYPE_ITEM(NAME, VAL, _) NAME = VAL, + FORALL_DYNAMIC_TYPES(DYNAMIC_TYPE_ITEM) + FORALL_DYNAMIC_TYPES_FAKE(DYNAMIC_TYPE_ITEM) +#undef DYNAMIC_TYPE_ITEM + }; + + bool equals(const Type& rhs) const override; + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override; + std::string str() const override; + static const TypeKind Kind = TypeKind::DynamicType; + static TORCH_API DynamicTypePtr create(Type& ty); + + explicit DynamicType(Tag, Arguments); + explicit DynamicType(Tag, std::string_view, Arguments); + + DynamicType(DynamicType&& other) = delete; + DynamicType(const DynamicType&) = delete; + DynamicType& operator=(const DynamicType&) = delete; + DynamicType& operator=(DynamicType&&) = delete; + + TypePtr containedType(size_t) const override; + size_t containedTypeSize() const override; + Tag tag() const { + return tag_; + } + const std::optional& name() const { + return name_; + } + const Arguments& arguments() const { + return arguments_; + } + TORCH_API TypeKind dynamicKind() const; + + // Should be used only on the server side to restore static type information. +#ifndef C10_MOBILE + TORCH_API +#endif + TypePtr fallback() const; + + private: + bool symmetric() const override { + return false; + } + friend struct Type; + static std::shared_ptr create(const Type& ty); + DynamicType(const Type& other); + bool equals(const DynamicType& other) const; + + template + bool compareArguments(const DynamicType& other, const F& f) const { + if (arguments_.elems.size() != other.arguments_.elems.size()) { + return false; + } + for (size_t i = 0; i < arguments_.elems.size(); i++) { + if (!f(arguments_.elems[i], other.arguments_.elems[i])) { + return false; + } + } + return true; + } + + Tag tag_; + std::optional name_; + union { + Arguments arguments_; + ClassTypePtr class_; + }; +}; + +template +struct DynamicTypeTrait { + C10_NOINLINE static auto tagValue() { + TORCH_CHECK(false); + return DynamicType::Tag::Any; + } +}; + +namespace detail { +C10_NOINLINE DynamicTypePtr makeBaseType(DynamicType::Tag tag); +} + +#define DYNAMIC_TYPE_TAG_VALUE(NAME, _, IS_BASE_TYPE) \ + template <> \ + struct TORCH_API DynamicTypeTrait { \ + C10_ERASE static auto tagValue() { \ + return DynamicType::Tag::NAME; \ + } \ + static constexpr bool isBaseType = IS_BASE_TYPE; \ + template \ + static std::enable_if_t getBaseType() { \ + static auto type = detail::makeBaseType(tagValue()); \ + return type; \ + } \ + }; // namespace c10 +FORALL_DYNAMIC_TYPES(DYNAMIC_TYPE_TAG_VALUE) +FORALL_DYNAMIC_TYPES_FAKE(DYNAMIC_TYPE_TAG_VALUE) +#undef DYNAMIC_TYPE_TAG_VALUE + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/enum_tag.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/enum_tag.h new file mode 100644 index 0000000000000000000000000000000000000000..51829df452eda7a5ec69a8e2d73a84092d0359b6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/enum_tag.h @@ -0,0 +1,22 @@ +#pragma once + +// @generated by torchgen/gen.py from enum_tag.h + +namespace at { + // Enum of valid tags obtained from the entries in tags.yaml + enum class Tag { + core, + data_dependent_output, + dynamic_output_shape, + flexible_layout, + generated, + inplace_view, + maybe_aliasing_or_mutating, + needs_fixed_stride_order, + nondeterministic_bitwise, + nondeterministic_seeded, + pointwise, + pt2_compliant_tag, + view_copy + }; +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/enum_type.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/enum_type.h new file mode 100644 index 0000000000000000000000000000000000000000..e292f58487fbdaea129765db3ff13f4dba3f5299 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/enum_type.h @@ -0,0 +1,102 @@ +#pragma once + +#include + +#include + +namespace c10 { + +struct EnumType; +using EnumTypePtr = std::shared_ptr; +using EnumNameValue = std::pair; +struct TORCH_API EnumType : public NamedType { + friend struct Type; + static const TypeKind Kind = TypeKind::EnumType; + + static EnumTypePtr create( + const c10::QualifiedName& qualified_class_name, + TypePtr value, + std::vector enum_names_values, + std::weak_ptr<::torch::jit::CompilationUnit> cu) { + switch (value->kind()) { + case TypeKind::IntType: + case TypeKind::FloatType: + case TypeKind::StringType: + return EnumTypePtr(new EnumType( + qualified_class_name, + std::move(value), + std::move(enum_names_values), + std::move(cu))); + default: + TORCH_CHECK( + false, + "Cannot create Enum with value type '", + value->str(), + "', only int, float and string are supported"); + } + } + + std::string str() const override { + return "Enum<" + annotation_str() + ">"; + } + + std::string repr_str() const override { + return str(); + } + + const TypePtr& getValueType() const { + return value_type_; + } + + bool equals(const Type& rhs) const override { + if (auto* enum_rhs = rhs.castRaw()) { + return name().has_value() && name() == enum_rhs->name() && + *getValueType() == *(enum_rhs->getValueType()) && + this->compilation_unit() == enum_rhs->compilation_unit(); + } + return false; + } + + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override; + + std::shared_ptr compilation_unit() + const { + auto cu = cu_.lock(); + return cu; + } + + const QualifiedName& qualifiedClassName() const { + // NOLINTNEXTLINE(bugprone-unchecked-optional-access) + return name().value(); + } + + at::ArrayRef containedTypes() const override { + return value_type_; + } + + const at::ArrayRef enumNamesValues() const { + return enum_names_values_; + } + + private: + EnumType( + c10::QualifiedName qualified_class_name, + TypePtr value_type, + std::vector enum_names_values, + std::weak_ptr cu) + : NamedType(TypeKind::EnumType, std::move(qualified_class_name)), + value_type_(std::move(value_type)), + enum_names_values_(std::move(enum_names_values)), + cu_(std::move(cu)) {} + + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + return qualifiedClassName().qualifiedName(); + } + + TypePtr value_type_; + std::vector enum_names_values_; + std::weak_ptr<::torch::jit::CompilationUnit> cu_; +}; + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/function.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/function.h new file mode 100644 index 0000000000000000000000000000000000000000..7e8a765a05abc1c26addac095316834ee026b4e3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/function.h @@ -0,0 +1,114 @@ +#pragma once + +#include +#include +#include +#include +#include + +namespace c10 { +struct FunctionSchema; +} + +namespace at { +TORCH_API void launch(std::function func); +} + +namespace torch::jit { + +struct Graph; +struct Code; + +namespace mobile { +struct Code; +} + +using Stack = std::vector; +using Kwargs = std::unordered_map; +struct RecursiveMethodCallError : public std::exception {}; +using TaskLauncher = std::function)>; + +TORCH_API void preoptimizeGraph( + std::shared_ptr& graph, + bool disable_autocast = false); + +// A Function is a pure Graph with no implicit `self` object bound. +// It contains schema information and the executor that manages the +// execution of the function. Method is a wrapper around an +// underlying Function that also provides a `self` object. +struct TORCH_API Function { + Function() = default; + Function(const Function&) = default; + Function& operator=(const Function&) = default; + Function(Function&&) noexcept = default; + Function& operator=(Function&&) noexcept = default; + virtual std::string_view doc_string() const { + static constexpr std::string_view no_doc_string; + return no_doc_string; + } + + virtual bool isGraphFunction() const { + return false; + } + + virtual void run(Stack& stack) = 0; + + virtual c10::intrusive_ptr runAsync( + Stack& /*stack*/, + // NOLINTNEXTLINE(performance-unnecessary-value-param) + [[maybe_unused]] TaskLauncher taskLauncher = at::launch) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(false); + return {}; + } + + at::IValue operator()(Stack stack, const Kwargs& kwargs = Kwargs()) { + getSchema().checkAndNormalizeInputs(stack, kwargs); + run(stack); + return stack.front(); + } + + virtual const c10::QualifiedName& qualname() const = 0; + + const std::string& name() const { + return qualname().name(); + } + + // if this isn't yet defined, run its method_creator function + virtual void ensure_defined() = 0; + + virtual const c10::FunctionSchema& getSchema() const = 0; + + virtual size_t num_inputs() const = 0; + + virtual Function& setSchema(c10::FunctionSchema schema) = 0; + + // call() defines how different interpreter implementations interacts with + // Function objects. Basically interpreters need to provide a callback to + // communicate to Functions what to do if provided a Code object. + // Alternatively we could design the signature to return an optional Code + // object, but that requires special handling the null case in interpreter + // and the fallback behavior is not well defined by interpreter but rather + // Function themselves, so a callback approach is more reasonable than + // returning values. + // If call() returns true, then callback completes successfully, otherwise + // call() returns false. + + // Overload for server interpreter, a bailout size is needed for graph + // executor. + virtual bool call( + Stack&, + std::optional, + c10::function_ref) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(false); + return false; + } + + // Overload for mobile interpreter. + virtual bool call(Stack&, c10::function_ref) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(false); + return false; + } + + virtual ~Function() = default; +}; +} // namespace torch::jit diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/function_schema.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/function_schema.h new file mode 100644 index 0000000000000000000000000000000000000000..c3e1520dc9868a7d7849169b895fc786a1f7d55b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/function_schema.h @@ -0,0 +1,690 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace c10 { + +// schema as used in the compiler for resolving function calls and reporting +// errors. These objects should be constructed from C10 schema once those +// are available. + +struct Argument; +struct FunctionSchema; + +using AliasTypeSet = std::vector; + +bool operator==(const Argument& lhs, const Argument& rhs); + +struct TORCH_API Argument { + Argument( + std::string name = "", + const TypePtr& type = nullptr, + std::optional N = std::nullopt, + std::optional default_value = std::nullopt, + bool kwarg_only = false, + std::optional alias_info = std::nullopt) + : Argument(std::move(name), type, type, N, std::move(default_value), kwarg_only, std::move(alias_info)) {} + + Argument( + std::string name, + TypePtr fake_type, + TypePtr real_type, + std::optional N = std::nullopt, + std::optional default_value = std::nullopt, + bool kwarg_only = false, + std::optional alias_info = std::nullopt) + : name_(std::move(name)), + type_(fake_type ? std::move(fake_type) : TensorType::get()), + real_type_(real_type ? std::move(real_type) : type_), + N_(N), + default_value_(std::move(default_value)), + alias_info_(alias_info ? std::make_unique(std::move(*alias_info)) : nullptr), + kwarg_only_(kwarg_only) { + // this is an softly-enforced invariant for out arguments. + bool is_alias = alias_info_ != nullptr && alias_info_->isWrite(); + is_out_ = kwarg_only_ && is_alias; + } + + Argument(Argument&& rhs) noexcept = default; + + Argument(const Argument& rhs) + : name_(rhs.name_), + type_(rhs.type_), + real_type_(rhs.real_type_), + N_(rhs.N_), + default_value_(rhs.default_value_), + alias_info_(rhs.alias_info_ ? std::make_unique(*rhs.alias_info_) : nullptr), + kwarg_only_(rhs.kwarg_only_), + is_out_(rhs.is_out_) {} + + Argument& operator=(Argument&& rhs) = default; + + Argument& operator=(const Argument& rhs) { + if (this != &rhs) { + name_ = rhs.name_; + type_ = rhs.type_; + real_type_ = rhs.real_type_; + N_ = rhs.N_; + default_value_ = rhs.default_value_; + alias_info_ = rhs.alias_info_ ? std::make_unique(*rhs.alias_info_) : nullptr; + kwarg_only_ = rhs.kwarg_only_; + is_out_ = rhs.is_out_; + } + return *this; + } + ~Argument() = default; + + const std::string& name() const { + return name_; + } + const TypePtr& type() const { + return type_; + } + // if type() is non-null, this is guaranteed to be non-null (if no real + // type was provided, this takes on type()'s value) + const TypePtr& real_type() const { + return real_type_; + } + const std::optional& N() const { + return N_; + } + const std::optional& default_value() const { + return default_value_; + } + bool kwarg_only() const { + return kwarg_only_; + } + + bool is_out() const { + return is_out_; + } + + [[nodiscard]] const AliasInfo* alias_info() const { + return alias_info_.get(); + } + + bool is_inferred_type() const { + bool is_inferred_type = false; + TORCH_INTERNAL_ASSERT(type_); + if (auto pt = type_->cast()) { + if (pt->isInferredType()) { + is_inferred_type = true; + } + } + return is_inferred_type; + } + + std::string formatTypeMismatchMsg(const std::string& actual_type) const { + std::string inferred_type_hint; + if (is_inferred_type()) { + inferred_type_hint = c10::str( + "Inferred '", + name(), + "' to be of type 'Tensor' ", + "because it was not annotated with an explicit type.\n"); + } + return c10::str( + "Expected a value of type '", + type()->repr_str(), + "' for argument '", + name(), + "' but instead found type '", + actual_type, + "'.\n", + inferred_type_hint); + } + + Argument cloneWithType(const TypePtr& new_type) const { + return Argument( + name_, + new_type, + N_, + default_value_, + kwarg_only_, + alias_info_ ? std::optional(*alias_info_) : std::nullopt); + } + + // this function checks whether this Argument is backward compatible with + // the old one. we consider the following cases are backward compatible: + // 1) two arguments are equal + // 2) this arg's type should be subtype of old + // 3) this arg must provide the same default value if old arg has one, + bool isBackwardCompatibleWith( + const Argument& old, + std::ostream* why_not=nullptr) const; + + // this function checks whether this Argument is forward compatible with + // the old one. we consider the following cases are forward compatible: + // 1) two arguments are equal + // 2) this arg's type should be subtype of old + // 3) this arg must provide the same default value if old arg has one, + bool isForwardCompatibleWith( + const Argument& old, + std::ostream* why_not = nullptr) const; + + private: + std::string name_; + TypePtr type_; + TypePtr real_type_; // this is ScalarType, not int, e.g. + // for list types, an optional statically known length for the list + // e.g. for int[3]: type = ListType::ofInts(), N = 3 + // If present, this will allow scalars to be broadcast to this length to + // become a list. + std::optional N_; + + std::optional default_value_; + // AliasInfo is huge, so let's only allocate memory for it if + // necessary (which it isn't during schema parsing on startup, to + // give a pertinent example). + std::unique_ptr alias_info_; + // is this only specifiable as a keyword argument? + bool kwarg_only_; + // marks if the argument is out variant of the schema + bool is_out_; +}; + +inline bool operator==(const Argument& lhs, const Argument& rhs) { + return lhs.name() == rhs.name() + && *lhs.type() == *rhs.type() + && lhs.N() == rhs.N() + && lhs.default_value() == rhs.default_value() + && lhs.kwarg_only() == rhs.kwarg_only() + && (lhs.alias_info() == rhs.alias_info() + || (lhs.alias_info() != nullptr && rhs.alias_info() != nullptr + && *lhs.alias_info() == *rhs.alias_info())); +} + +inline bool operator!=(const Argument& lhs, const Argument& rhs) { + return !(lhs == rhs); +} + +enum struct TORCH_API SchemaArgType { input, output }; + +/** + * struct SchemaArgument + * + * Structure used to represent arguments or returns for a schema. + */ +struct TORCH_API SchemaArgument { + SchemaArgType type; + size_t index; + SchemaArgument(SchemaArgType tpe, size_t idx) : type(tpe), index(idx) {} + bool operator==(const SchemaArgument& rhs) const { + return type == rhs.type && index == rhs.index; + } +}; + +bool operator==(const FunctionSchema& lhs, const FunctionSchema& rhs); + +struct TORCH_API FunctionSchema { + FunctionSchema( + std::string name, + std::string overload_name, + std::vector arguments, + std::vector returns, + bool is_vararg = false, + bool is_varret = false) + : name_({std::move(name), std::move(overload_name)}), + arguments_(std::move(arguments)), + returns_(std::move(returns)), + is_vararg_(is_vararg), + is_varret_(is_varret) { + checkSchema(); + } + + FunctionSchema( + Symbol name, + std::string overload_name, + std::vector arguments, + std::vector returns, + bool is_vararg = false, + bool is_varret = false) + : FunctionSchema( + name.toQualString(), + std::move(overload_name), + std::move(arguments), + std::move(returns), + is_vararg, + is_varret) { + checkSchema(); + } + + // Checks whether this schema is backward compatible with the old one. + // The following conditions must be true: + // [Function structure] The new schema's name, overload-name, varargs, and + // return arity are the same. + // [Output Narrowing] The new schema's output type must be the same class + // or inherit from the old schema's output type. + // [Argument count] The new schema must have at least as many arguments as + // the old schema (considering the list of positional and kwargs). + // [Arg Compatibility] Every argument in the old schema has a corresponding + // argument in the new schema that: + // * is at the same position. + // * has the same name. + // * is either positional, or kwarg and the old argument was kwarg. + // * has the same type, or the old argument's type inherits from the + // new argument's type. + // [Default Values] Every new argument must have a default value. + // E.g. + // OK f_new(a, b, c=1) => f_old(a, b) + // NOK f_new(a, c=1, *, b) => f_old(a, *, b) + // OK f_new(a, b, *, c) => f_old(a, *, b, c) + // NOK f_new(a, *, b, c) -> f_old(a, b, *, c) + // NOK f_new(a, *, c, b) => f_old(a, *, b, c) + // OK f_new(a, *, b, c, d=1) => f_old(a, *, b, c) + bool isBackwardCompatibleWith( + const FunctionSchema& old, + std::ostream* why_not = nullptr) const; + + // Checks whether this schema is forward compatible with the old one. + // The following conditions must be true: + // [Function structure] The new schema's name, overload-name, varargs, and + // return arity are the same. + // [Output Narrowing] The new schema's output type must be the same class + // or inherit from the old schema's output type. + // [Arg Compatibility] Every argument in the old schema has a corresponding + // argument in the new schema that: + // * is at the same position. + // * has the same name. + // * is either positional, or kwarg and the old argument was kwarg. + // * has the same type, or the old argument's type inherits from the + // new argument's type. + // [Default Values] Every new argument must have a default value. + // Each default value type should NOT be a container type. + // [Positioning] All defaults arguments MUST go after either old + // default arguments or the end of positional arguments + // and right BEFORE all out arguments + bool isForwardCompatibleWith( + const FunctionSchema& old, + std::ostringstream& why_not) const; + + private: + OperatorName name_; + std::vector arguments_; + std::vector returns_; + // if true then this schema takes an arbitrary number of additional arguments + // after the argument specified in arguments + // currently this is used primarily to represent 'primitive' operators whose + // arguments are not checked by schema + bool is_vararg_; + bool is_varret_; + + // if no alias information is directly specified, what kind of "default" + // alias information should we infer? + // NB: due to alias analysis kind merging, this may be nullopt. Eventually + // this should always be set no matter what + std::optional alias_kind_; + + template + void checkArg(const IValue& value, const Argument& argument, std::optional pos) const; + + void checkSchema() const { + bool seen_default_arg = false; + for (const auto& arg : arguments()) { + if (arg.default_value()) { + seen_default_arg = true; + } else { + // we have historically serialized broadcasting lists wo/default values, + // so to not break BC allow lists here + if (arg.type()->kind() == ListType::Kind) { + continue; + } + TORCH_INTERNAL_ASSERT( + !seen_default_arg || arg.kwarg_only(), + "Non-default positional argument follows default argument. Parameter ", + arg.name(), + " in ", + *this); + } + } + } + + public: + + void dump() const; + + const OperatorName& operator_name() const { + return name_; + } + const std::string& name() const { + return name_.name; + } + const std::string& overload_name() const { + return name_.overload_name; + } + const std::vector& arguments() const { + return arguments_; + } + const std::vector& returns() const { + return returns_; + } + bool is_vararg() const { + return is_vararg_; + } + bool is_varret() const { + return is_varret_; + } + bool is_aliasing(const c10::SchemaArgument &argument) const { + TORCH_INTERNAL_ASSERT( + argument.index < getCorrectList(argument.type).size(), + "Invalid index for schema."); + const AliasInfo* aliasInfo = getCorrectList(argument.type)[argument.index].alias_info(); + return aliasInfo; + } + bool is_mutable() const { + return std::any_of( + arguments_.cbegin(), arguments_.cend(), [](const Argument& arg) { + const AliasInfo* aliasInfo = arg.alias_info(); + return aliasInfo && aliasInfo->isWrite(); + }); + } + bool is_mutable(const c10::SchemaArgument &argument) const { + TORCH_INTERNAL_ASSERT( + argument.index < getCorrectList(argument.type).size(), + "Invalid index for schema."); + const AliasInfo* aliasInfo = getCorrectList(argument.type)[argument.index].alias_info(); + return aliasInfo && aliasInfo->isWrite(); + } + bool is_mutable(std::string_view name) const { + std::optional index = argumentIndexWithName(name); + TORCH_INTERNAL_ASSERT( + index.has_value(), "Schema has no argument named ", name); + + return is_mutable({c10::SchemaArgType::input, static_cast(*index)}); + } + + // Returns whether lhs and rhs may alias directly. + // This does not account for cases where lhs or rhs are a container that + // may contain elements that alias the other argument. + // FunctionSchema::may_contain_alias will include that functionality. + bool may_alias(const SchemaArgument& lhs, const SchemaArgument& rhs) const; + + // Returns whether lhs and rhs may alias directly or whether lhs/rhs are a container + // that may contain elements that alias the other argument. + // bidirectional = false only returns whether lhs may contain an alias of rhs + // while bidirectional = true returns both directions. + bool may_contain_alias(const SchemaArgument& lhs, const SchemaArgument& rhs, bool bidirectional = true) const; + + // Returns whether the two AliasTypeSets contain any similarities + // ie: whether the two type sets can alias. + bool canAliasTypeSetsAlias(const std::optional &lhs, const std::optional &rhs) const; + + // Recursively Finds all contained types within the AliasTypeSet. + std::optional getAliasTypeSetContainedTypes(const std::optional &aliasTypeSet) const; + + // Similar to mapTypeToAliasTypeSet defined in alias_analysis.cpp. + // Used to map types to a type such that all types that can alias will be mapped to the same type. + // For example, calling this method on 'Optional[List[int]]' is the same as calling this method + // on 'List[int]'. + std::optional mapTypeToAliasTypeSet(const TypePtr& type) const; + + // Returns either arguments() or returns() depending on the SchemaArgType + // output => returns(), input => arguments() + const std::vector& getCorrectList(SchemaArgType type) const; + + std::optional argumentIndexWithName(std::string_view name) const { + for (const auto i : c10::irange(arguments().size())) { + if(name == arguments()[i].name()) + return i; + } + return std::nullopt; + } + FunctionSchema cloneWithName(std::string name, std::string overload_name) const { + return FunctionSchema( + std::move(name), + std::move(overload_name), + arguments(), + returns(), + is_vararg(), + is_varret() + ); + } + FunctionSchema cloneWithArguments(std::vector new_arguments) const { + return FunctionSchema( + name(), + overload_name(), + std::move(new_arguments), + returns(), + is_vararg(), + is_varret()); + } + FunctionSchema cloneWithReturns(std::vector new_returns) const { + return FunctionSchema( + name(), + overload_name(), + arguments(), + std::move(new_returns), + is_vararg(), + is_varret()); + } + + std::string formatTypeMismatchMsg( + const Argument& expected, + const std::string& actual_type, + std::optional position = std::nullopt, + std::optional value = std::nullopt) const; + + FunctionSchema cloneWithRemappedTypes( + const std::function type_map) const; + + FunctionSchema cloneWithRealTypes(bool with_symint=true) const; + + // Check that inputs have the correct types and appends any missing default + // values. + template + void checkAndNormalizeInputs( + std::vector& inputs, + const std::unordered_map& kwargs = + std::unordered_map{}) const; + + std::string findErrorInKwargs(const std::vector& kwargs) const; + + bool hasAnyAliasInfo() const { + for (const auto& arg : arguments_) { + if (arg.alias_info() != nullptr) { + return true; + } + } + for (const auto& ret : returns_) { + if (ret.alias_info() != nullptr) { + return true; + } + } + return false; + } + + + // TODO remove the mutation here + bool isDefaultAliasAnalysisKind() const { + return !alias_kind_; + } + AliasAnalysisKind aliasAnalysis() const { + return alias_kind_.value_or(AliasAnalysisKind::CONSERVATIVE); + } + void setAliasAnalysis(AliasAnalysisKind v) { + alias_kind_ = v; + } + + std::optional getNamespace() const { + return name_.getNamespace(); + } + + // Returns true if we successfully set the namespace (as there + // was none set, and false otherwise) + bool setNamespaceIfNotSet(const char* ns) { + return name_.setNamespaceIfNotSet(ns); + } + + // can a function with this schema be substituted for a function of rhs's + // schema and have the program typecheck? + // as_method - if true, treat this schema as a method and ignore + // the first argument, which will be the object in both cases + bool isSubtypeOf(const FunctionSchema& rhs, bool as_method, std::ostream* why_not=nullptr) const; +}; + +inline bool operator==(const FunctionSchema& lhs, const FunctionSchema& rhs) { + return lhs.name() == rhs.name() + && lhs.overload_name() == rhs.overload_name() + && lhs.arguments() == rhs.arguments() + && lhs.returns() == rhs.returns() + && lhs.is_vararg() == rhs.is_vararg() + && lhs.is_varret() == rhs.is_varret(); +} + +inline bool operator!=(const FunctionSchema& lhs, const FunctionSchema& rhs) { + return !(lhs == rhs); +} + +// print out Argument, which is compatible with FunctionSchema parser +// full format: Type(alias)? name=default_value +inline std::ostream& operator<<(std::ostream& out, const Argument& arg) { + + // for adjusting the ? position. + // in schema, we have Tensor?(a!) input, and t(a!)?. + // however, t?(a!) doesn't work with schema parser. + // so we always use Type(alias)? format + // real_type versus fake_type: in order to be compatible with FunctionSchema + // parser, printing an argument with either MemoryFormat or Layout type should + // give us the original schema string, hence printing out real_type. + auto type = arg.real_type(); + bool is_opt = type->kind() == OptionalType::Kind; + auto unopt_type = is_opt ? type->castRaw()->getElementType() : type; + + if (unopt_type->kind() == ListType::Kind) { + // sized lists get size N from arg, not type + auto list = unopt_type->cast(); + out << list->getElementType()->str(); + if (arg.alias_info() && !arg.alias_info()->containedTypes().empty()){ + out << arg.alias_info()->containedTypes()[0]; + } + std::string N; + if (arg.N()) { + N = std::to_string(*arg.N()); + } + out << "[" << N << "]"; + } else { + out << unopt_type->str(); + } + + // print alias info if it has beforeSets. + if (arg.alias_info() && !arg.alias_info()->beforeSets().empty()) { + out << *arg.alias_info(); + } + + if (is_opt) { + out << "?"; + } + + if (!arg.name().empty()) { + out << " " << arg.name(); + } + + if (arg.default_value()) { + out << "="; + if ((type->kind() == c10::TypeKind::StringType || + unopt_type->kind() == c10::TypeKind::StringType) && + arg.default_value().value().isString()) { + printQuotedString(out, arg.default_value().value().toStringRef()); + } else if (type->kind() == TypeKind::ListType && type->castRaw()->getElementType()->kind() == c10::TypeKind::IntType) { + // We want to faithfully replicate JIT schema. + // in native_functions.yaml defaults for int arrays with a single value always look like + // int[2] stride=1 + // instead of + // int[2] stride=[1, 1] + auto default_val = arg.default_value().value().toIntList(); + if (default_val.size() > 1) { + auto all_defaults_the_same = true; + for (const auto i : c10::irange(1, default_val.size())) { + if (default_val[0] != default_val[i]) all_defaults_the_same = false; + } + if (all_defaults_the_same) { + out << default_val[0]; + } else { + out << arg.default_value().value(); + } + } else { + out << arg.default_value().value(); + } + } else { + out << arg.default_value().value(); + } + } + + return out; +} + +TORCH_API std::ostream& operator<<(std::ostream& out, const FunctionSchema& schema); + +inline std::string toString(const FunctionSchema& schema) { + std::ostringstream str; + str << schema; + return str.str(); +} + +} // namespace c10 + +namespace std { +template<> + struct hash { + size_t operator()(const c10::SchemaArgument& arg) const + { + return c10::hash_combine(std::hash()(arg.index), std::hash()(static_cast(arg.type))); + } + }; +template<> + struct hash { + size_t operator()(const c10::Argument& arg) const + { + auto hash = std::hash{}(arg.name()); + auto type_hash = std::hash{}(arg.type()); + auto kwarg_only_hash = std::hash{}(arg.kwarg_only()); + hash = c10::hash_combine(hash, type_hash); + hash = c10::hash_combine(hash, kwarg_only_hash); + // hashing optional fields if they exist + if (arg.default_value().has_value()) { + // NOLINTNEXTLINE(bugprone-unchecked-optional-access) + auto default_value_hash = c10::hash{}(*arg.default_value()); + hash = c10::hash_combine(hash, default_value_hash); + } + if (arg.N().has_value()) { + // NOLINTNEXTLINE(bugprone-unchecked-optional-access) + auto N_hash = std::hash{}(*arg.N()); + hash = c10::hash_combine(hash, N_hash); + } + if (arg.alias_info()) { + auto alias_info_hash = std::hash{}(*arg.alias_info()); + hash = c10::hash_combine(hash, alias_info_hash); + } + return hash; + } + }; +template<> + struct hash { + size_t operator()(const c10::FunctionSchema& schema) const + { + auto hash = std::hash{}(schema.operator_name()); + auto args_hash = c10::hash>{}(schema.arguments()); + auto returns_hash = c10::hash>{}(schema.returns()); + auto is_vararg_hash = std::hash{}(schema.is_vararg()); + auto is_varret_hash = std::hash{}(schema.is_varret()); + hash = c10::hash_combine(hash, args_hash); + hash = c10::hash_combine(hash, returns_hash); + hash = c10::hash_combine(hash, is_vararg_hash); + hash = c10::hash_combine(hash, is_varret_hash); + return hash; + } + }; +} // namespace std + + +#include // IWYU pragma: keep diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/function_schema_inl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/function_schema_inl.h new file mode 100644 index 0000000000000000000000000000000000000000..f4d5ee6a3fd36637806f8f799ba0817576b9a1d0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/function_schema_inl.h @@ -0,0 +1,78 @@ +#pragma once +#include +#include + +namespace c10 { + +template +inline void FunctionSchema::checkArg( + const IValue& value, + const Argument& argument, + std::optional pos) const { + if (value.isTensor() && argument.type() == TensorType::get()) { + // Fast-path for the common case + return; + } + if (value.isGenericDict() && value.toGenericDict().empty()) { + return; + } + if (!value.type()->isSubtypeOf(*argument.type())) { + TORCH_CHECK( + false, + formatTypeMismatchMsg( + argument, value.type()->repr_str(), pos)); + } +} + +template +inline void FunctionSchema::checkAndNormalizeInputs( + std::vector& inputs, + const std::unordered_map& kwargs) const { + // Do we have more inputs than the schema accepts? + TORCH_CHECK( + inputs.size() <= arguments().size(), + "Expected at most ", + arguments().size(), + " argument(s) for operator '", + name(), + "', but received ", + inputs.size(), + " argument(s). Declaration: ", + *this); + + size_t consumed_kwargs = 0; + for (const auto pos : c10::irange(arguments().size())) { + const auto& argument = arguments()[pos]; + if (pos < inputs.size()) { + checkArg(inputs[pos], argument, pos); + continue; + } + auto it = kwargs.find(argument.name()); + if (it != kwargs.end()) { + checkArg(it->second, argument, std::nullopt); + inputs.push_back(it->second); + consumed_kwargs++; + continue; + } + if (argument.default_value()) { + inputs.push_back(*argument.default_value()); + continue; + } + TORCH_CHECK(false, + name(), + "() is missing value for argument '", + argument.name(), + "'. Declaration: ", + *this); + } + if (consumed_kwargs != kwargs.size()) { + std::vector names; + names.reserve(kwargs.size()); + for(const auto& k : kwargs) { + names.emplace_back(k.first); + } + throw std::runtime_error(findErrorInKwargs(names)); + } +} + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/functional.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/functional.h new file mode 100644 index 0000000000000000000000000000000000000000..1ddc67418201024f6f94907340689e81f0493c35 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/functional.h @@ -0,0 +1,54 @@ +#pragma once + +#include +#include + +namespace c10 { + +// The passed in function must take T by value (T), or by +// const reference (const T&); taking T by non-const reference +// will result in an error like: +// +// error: no type named 'type' in 'class std::invoke_result' +// +// No explicit template parameters are required. + +// Overload for explicit function and ArrayRef +template +inline auto fmap(const T& inputs, const F& fn) -> std::vector { + std::vector r; + r.reserve(inputs.size()); + for(const auto & input : inputs) + r.push_back(fn(input)); + return r; +} + +// C++ forbids taking an address of a constructor, so here's a workaround... +// Overload for constructor (R) application +template +inline std::vector fmap(const T& inputs) { + std::vector r; + r.reserve(inputs.size()); + for(auto & input : inputs) + r.push_back(R(input)); + return r; +} + +template +inline std::vector filter(at::ArrayRef inputs, const F& fn) { + std::vector r; + r.reserve(inputs.size()); + for(auto & input : inputs) { + if (fn(input)) { + r.push_back(input); + } + } + return r; +} + +template +inline std::vector filter(const std::vector& inputs, const F& fn) { + return filter(static_cast>(inputs), fn); +} + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/grad_mode.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/grad_mode.h new file mode 100644 index 0000000000000000000000000000000000000000..47051525c59beece9e8e11accacd926d9c5e587e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/grad_mode.h @@ -0,0 +1,10 @@ +#pragma once + +#include +#include + +namespace at { + using GradMode = c10::GradMode; + using AutoGradMode = c10::AutoGradMode; + using NoGradGuard = c10::NoGradGuard; +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/interned_strings.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/interned_strings.h new file mode 100644 index 0000000000000000000000000000000000000000..38942031befcd62ed216002f549b67fb547088b0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/interned_strings.h @@ -0,0 +1,355 @@ +#pragma once + +#include + +#include +#include + +namespace c10 { + +#define FORALL_NS_SYMBOLS(_) \ + _(namespaces, prim) \ + _(namespaces, prims) \ + _(namespaces, nvprims) \ + _(namespaces, aten) \ + _(namespaces, cuda) \ + _(namespaces, onnx) \ + _(namespaces, attr) \ + _(namespaces, scope) \ + _(namespaces, user) \ + _(namespaces, _caffe2) \ + _(namespaces, dimname) \ + _(namespaces, namespaces) \ + _(prim, Assign) \ + _(prim, BroadcastingChunk) \ + _(prim, BroadcastSizes) \ + _(prim, ReductionSizes) \ + _(prim, Constant) \ + _(prim, ChunkSizes) \ + _(prim, ConstantMKLDNNTensor) \ + _(prim, BroadcastMKLDNNTensors) \ + _(prim, MKLDNNGroup) \ + _(prim, MKLDNNHardSwish) \ + _(prim, MKLDNNHardSigmoid) \ + _(prim, MKLDNNHardTanh) \ + _(prim, MKLDNNClamp) \ + _(prim, StaticRuntimeCopyOuts) \ + _(prim, Drop) \ + _(prim, Eval) \ + _(prim, Expand) /* onnx */ \ + _(prim, FusionGroup) \ + _(prim, CudaFusionGroup) \ + _(prim, CudaFusionGuard) \ + _(prim, oneDNNFusionGroup) \ + _(prim, oneDNNFusionGuard) \ + _(prim, FunctionalGraph) \ + _(prim, add_optional) \ + _(prim, view_copy) \ + _(prim, permute_copy) \ + _(prim, reshape_copy) \ + _(prim, squeeze_copy) \ + _(prim, t_copy) \ + _(prim, transpose_copy) \ + _(prim, unsqueeze_copy) \ + _(prim, flatten_copy) \ + _(prim, expand_copy) \ + _(prim, expand_as_copy) \ + _(prim, DifferentiableGraph) \ + _(prim, TensorExprGroup) \ + _(prim, TensorExprDynamicGroup) \ + _(prim, StaticSubgraph) \ + _(prim, If) \ + _(prim, Jump) /* debug */ \ + _(prim, JumpNZ) /* debug */ \ + _(prim, JumpZ) /* debug */ \ + _(prim, Load) \ + _(prim, Loop) \ + _(prim, Param) \ + _(prim, PackPadded) /* onnx */ \ + _(prim, PadPacked) /* onnx */ \ + _(prim, Placeholder) /* debug */ \ + _(prim, Print) \ + _(prim, EmptyListLiteral) \ + _(prim, LegacyTypedConstructor) \ + _(prim, PythonOp) \ + _(prim, IgnoredPythonOp) \ + _(prim, Reverse) \ + _(prim, Return) \ + _(prim, ReturnStmt) \ + _(prim, BreakStmt) \ + _(prim, ContinueStmt) \ + _(prim, ComprehensionScope) \ + _(prim, Store) \ + _(prim, AutogradZero) \ + _(prim, AutogradAnyNonZero) \ + _(prim, AutogradAllNonZero) \ + _(prim, AutogradAllZero) \ + _(prim, Starred) \ + _(prim, TupleConstruct) \ + _(prim, TupleUnpack) \ + _(prim, TupleIndex) \ + _(prim, TupleSlice) \ + _(prim, ListConstruct) \ + _(prim, ListUnpack) \ + _(prim, DictConstruct) \ + _(prim, ModuleContainerIndex) \ + _(prim, EnumName) \ + _(prim, EnumValue) \ + _(prim, StringIndex) \ + _(prim, NumToTensor) \ + _(prim, Uninitialized) \ + _(prim, VarConcat) \ + _(prim, VarStack) \ + _(prim, With) \ + _(prim, Enter) \ + _(prim, Exit) \ + _(prim, IfThenElse) \ + _(aten, Bool) \ + _(aten, Int) \ + _(aten, FloatImplicit) \ + _(aten, ComplexImplicit) \ + _(aten, IntImplicit) \ + _(aten, ScalarImplicit) \ + _(aten, Float) \ + _(aten, Complex) \ + _(aten, str) \ + _(aten, Delete) \ + _(prim, device) \ + _(prim, dtype) \ + _(prim, layout) \ + _(prim, id) \ + _(prim, requires_grad) \ + _(prim, MakeTestTensor) /* test */ \ + _(prim, AutogradAdd) \ + _(prim, GradOf) \ + _(aten, grad) \ + _(aten, backward) \ + _(prim, Guard) \ + _(prim, BailOut) \ + _(prim, TypeCheck) \ + _(prim, RequiresGradCheck) \ + _(prim, FallbackGraph) \ + _(prim, FusedConcat) \ + _(prim, ConstantChunk) \ + _(prim, MMTreeReduce) \ + _(prim, MMBatchSide) \ + _(prim, list) \ + _(prim, dict) \ + _(prim, min) \ + _(prim, max) \ + _(prim, abs) \ + _(aten, divmod) \ + _(prim, zip) \ + _(prim, enumerate) \ + _(prim, range) \ + _(prim, rangelist) \ + _(prim, isinstance) \ + _(prim, tolist) \ + _(prim, unchecked_cast) \ + _(aten, _grad_sum_to_size) \ + _(aten, _size_if_not_equal) \ + _(aten, _ncf_unsqueeze) \ + _(aten, warn) \ + _(aten, sorted) \ + _(aten, floordiv) \ + _(aten, __range_length) \ + _(aten, __derive_index) \ + _(aten, __round_to_zero_floordiv) \ + _(aten, is_scripting) \ + _(aten, _unwrap_optional) \ + _(prim, fork) \ + _(prim, awaitable) \ + _(prim, forkClosure) \ + _(prim, awaitableClosure) \ + _(prim, awaitable_nowait) \ + _(prim, awaitable_wait) \ + _(prim, RaiseException) \ + _(prim, Closure) \ + _(prim, CreateObject) \ + _(prim, SetAttr) \ + _(prim, GetAttr) \ + _(prim, HasAttr) \ + _(prim, profile) \ + _(prim, profile_ivalue) \ + _(prim, AddStatValue) \ + _(prim, TimePoint) \ + _(prim, CallFunction) \ + _(prim, CallMethod) \ + _(prim, LoopContinuation) \ + _(prim, annotate) \ + _(prim, TracedModuleForward) \ + _(prim, TracedFork) \ + _(prim, TracedAttr) \ + _(prim, rpc_async) \ + _(prim, rpc_sync) \ + _(prim, rpc_remote) \ + _(prim, is_cuda) \ + _(aten, append) \ + _(aten, as_tensor) \ + _(aten, adaptive_avg_pool2d_backward) \ + _(aten, dim) \ + _(aten, format) \ + _(aten, percentFormat) \ + _(aten, __not__) \ + _(aten, __is__) \ + _(aten, __isnot__) \ + _(aten, _ger) \ + _(aten, __getitem__) \ + _(aten, _set_item) \ + _(aten, manual_seed) \ + _(aten, device) \ + _(aten, hash) \ + _(aten, len) \ + _(aten, list) \ + _(aten, dict) \ + _(aten, wait) \ + _(aten, save) \ + _(aten, keys) \ + _(aten, ord) \ + _(aten, chr) \ + _(aten, hex) \ + _(aten, oct) \ + _(aten, clear) \ + _(aten, setdefault) \ + _(aten, bin) \ + _(aten, pop) \ + _(aten, insert) \ + _(aten, tensor) \ + _(prim, unchecked_unwrap_optional) \ + _(aten, __contains__) \ + _(prim, BailoutTemplate) \ + _(prim, grad) \ + _(cuda, _set_device) \ + _(cuda, set_stream) \ + _(cuda, _current_device) \ + _(cuda, synchronize) \ + _(aten, has_torch_function) \ + _(aten, is_autocast_enabled) \ + _(aten, is_autocast_cpu_enabled) \ + _(aten, is_autocast_xla_enabled) \ + _(aten, get_autocast_dtype) \ + _(aten, is_autocast_mps_enabled) \ + FORALL_ATEN_BASE_SYMBOLS(_) \ + _(onnx, Add) \ + _(onnx, Concat) \ + _(onnx, Constant) \ + _(onnx, ConstantFill) \ + _(onnx, Div) \ + _(onnx, GRU) \ + _(onnx, Gather) \ + _(onnx, Gemm) \ + _(onnx, LSTM) \ + _(onnx, MatMul) \ + _(onnx, Min) \ + _(onnx, Max) \ + _(onnx, Mul) \ + _(onnx, Pow) \ + _(onnx, RNN) \ + _(onnx, Shape) \ + _(onnx, Size) \ + _(onnx, Slice) \ + _(onnx, Softmax) \ + _(onnx, Squeeze) \ + _(onnx, Sub) \ + _(onnx, Transpose) \ + _(onnx, Unsqueeze) \ + _(onnx, Loop) \ + _(onnx, If) \ + _(onnx, Reshape) \ + _(onnx, Expand) \ + _(onnx, Equal) \ + _(onnx, Greater) \ + _(onnx, GreaterOrEqual) \ + _(onnx, Less) \ + _(onnx, LessOrEqual) \ + _(onnx, Not) \ + _(aten, ATen) \ + _(onnx, Split) \ + _(onnx, ConstantOfShape) \ + _(onnx, Cast) \ + _(onnx, Mod) \ + _(onnx, Sqrt) \ + _(onnx, SplitToSequence) \ + _(onnx, SequenceAt) \ + _(onnx, SequenceConstruct) \ + _(onnx, SequenceEmpty) \ + _(onnx, SequenceInsert) \ + _(onnx, SequenceErase) \ + _(onnx, ConcatFromSequence) \ + _(onnx, Identity) \ + _(onnx, SoftmaxCrossEntropyLoss) \ + _(onnx, NegativeLogLikelihoodLoss) \ + _(onnx, LogSoftmax) \ + _(onnx, ReduceL1) \ + _(onnx, ReduceL2) \ + _(onnx, Conv) \ + _(onnx, BatchNormalization) \ + _(onnx, ReduceMean) \ + _(onnx, ReduceProd) \ + _(onnx, Relu) \ + _(onnx, Neg) \ + _(onnx, NonZero) \ + _(onnx, Range) \ + _(onnx, Tile) \ + _(onnx, Where) \ + _(onnx, Optional) \ + _(onnx, OptionalGetElement) \ + _(onnx, OptionalHasElement) \ + FORALL_ATTR_BASE_SYMBOLS(_) \ + _(attr, Subgraph) \ + _(attr, ReverseSubgraph) \ + _(attr, f_real_outputs) \ + _(attr, df_input_vjps) \ + _(attr, df_input_captured_inputs) \ + _(attr, df_input_captured_outputs) \ + _(attr, df_output_vjps) \ + _(attr, axes) \ + _(attr, symbolic_shape_inputs) \ + _(attr, allow_stack_outputs) \ + _(attr, striding_inputs_desc) \ + _(attr, striding_outputs_desc) \ + _(attr, broadcast) \ + _(attr, direction) \ + _(attr, ends) \ + _(attr, inplace) \ + _(attr, input_as_shape) \ + _(attr, is_zero) \ + _(attr, num_none) \ + _(attr, num_present) \ + _(attr, perm) \ + _(attr, starts) \ + _(attr, profiled_type) \ + _(attr, transA) \ + _(attr, transB) \ + _(attr, name) \ + _(attr, module) \ + _(attr, beg) \ + _(attr, idx) \ + _(attr, split) \ + _(attr, slot) \ + _(attr, kinds) \ + _(attr, types) \ + _(attr, scope) \ + _(attr, keepdims) \ + _(attr, cache_id) \ + _(attr, new_axis) \ + _(attr, warn_id) \ + _(attr, output_layouts) \ + _(attr, allowzero) \ + _(attr, seen_none) \ + _(attr, overload_name) \ + _(attr, node_stack_idx) + +enum class _keys : unique_t { + #define DEFINE_KEY(ns, s) ns##_##s, + FORALL_NS_SYMBOLS(DEFINE_KEY) + #undef DEFINE_KEY + num_symbols +}; + +#define DEFINE_SYMBOL(ns, s) \ + namespace ns { constexpr Symbol s(static_cast(_keys::ns##_##s)); } +FORALL_NS_SYMBOLS(DEFINE_SYMBOL) +#undef DEFINE_SYMBOL + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/interned_strings_class.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/interned_strings_class.h new file mode 100644 index 0000000000000000000000000000000000000000..a215fa62c7e91827425a86df4c556428bf249bea --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/interned_strings_class.h @@ -0,0 +1,32 @@ +#include +#include +#include +#include +#include +#include + +namespace c10 { + +struct TORCH_API InternedStrings { + InternedStrings(); + Symbol symbol(const std::string& s); + std::pair string(Symbol sym); + Symbol ns(Symbol sym); + + private: + // prereq - holding mutex_ + Symbol _symbol(const std::string& s); + std::pair customString(Symbol sym); + std::unordered_map string_to_sym_; + + struct SymbolInfo { + Symbol ns; + std::string qual_name; + std::string unqual_name; + }; + std::vector sym_to_info_; + + std::mutex mutex_; +}; + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ivalue.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ivalue.h new file mode 100644 index 0000000000000000000000000000000000000000..175860dc99a7ccbe3742d27d24346b136eee4e12 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ivalue.h @@ -0,0 +1,1589 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace torch { +class TORCH_API CustomClassHolder : public c10::intrusive_ptr_target {}; +namespace jit { +using ::torch::CustomClassHolder; +struct Function; +struct CompilationUnit; +struct Module; +} // namespace jit +} // namespace torch +namespace c10 { +template +class Dict; +template +class List; +template +class IListRef; +struct IValue; +struct ClassType; +struct Type; +class RRefInterface; + +struct ClassType; +using ClassTypePtr = std::shared_ptr; + +TORCH_API bool _fastEqualsForContainer(const IValue& lhs, const IValue& rhs); + +TORCH_API torch::jit::Function* checkObjectSortSchema( + const c10::ClassTypePtr& t, + std::stringstream& why_not); + +// A comparator that checks ordering of two IValues of same type. +typedef std::function IValueComparator; + +TORCH_API IValueComparator getLessThanComparator(const IValue& v); +TORCH_API IValueComparator getGreaterThanComparator(const IValue& v); + +namespace ivalue { +struct Tuple; +struct Future; +struct Await; +struct ConstantString; +struct GenericDict; +struct Object; +struct PyObjectHolder; +struct EnumHolder; +// We need a ComplexHolder because currently the payloads in the Union +// only take 64 bits. Since ComplexDouble takes up 128 bits, and is too big +// to fit in the IValue directly, we indirect complex numbers through an +// intrusive pointer to ComplexHolder (which contains a c10::complex). +struct ComplexHolder : c10::intrusive_ptr_target { + public: + template + ComplexHolder(c10::complex c) { + val = convert>(c); + } + ComplexHolder() = default; + c10::complex val; +}; + +// Similar to ComplexHolder, for StreamData3 +struct StreamData3Holder : c10::intrusive_ptr_target { + public: + StreamData3Holder(struct c10::StreamData3 d) : val(d) {} + StreamData3Holder() = delete; + struct c10::StreamData3 val; +}; + +} // namespace ivalue + +// This is an owning wrapper for a std::optional> +// that can be implicitly converted to a (non-owning) std::optional>. +// Its purpose is to be used in generated code to keep the vector alive +// either until the end of a statement (as a temporary), or as a saved arg +// in autograd. +template +struct OptionalArray { + std::optional> list; + + OptionalArray() = default; + OptionalArray(std::vector val) : list(std::move(val)) {} + + // Used when saving an argument for the backwards pass. + OptionalArray& operator=(std::optional> ref) { + if (ref) { + list = std::vector(ref->begin(), ref->end()); + } else { + list = std::nullopt; + } + return *this; + } + + // Used when saving an argument for the backwards pass. + OptionalArray& operator=(c10::OptionalArrayRef ref) { + if (ref) { + list = std::vector(ref->begin(), ref->end()); + } else { + list = std::nullopt; + } + return *this; + } + + operator std::optional>() { + if (!list) { + return std::nullopt; + } + return *list; + } + + operator c10::OptionalArrayRef() { + if (!list) { + return std::nullopt; + } + return *list; + } +}; + +// Capsule is an internal implementation detail of custom C++ classes. We +// define it as an owning wrapper for +// c10::intrusive_ptr This wrapper is here to serve as +// an abstraction of the type erased custom class object pointer. It also allow +// pybind11 to treat this as a standalone class to register as a separate type +// caster, instead of a custom pointer holder which the pointer holder type +// caster try to "unwrap" it automatically. +struct Capsule { + c10::intrusive_ptr obj_ptr; + explicit Capsule(c10::intrusive_ptr ptr) + : obj_ptr(std::move(ptr)) {} +}; + +// IValue is the generic tagged union used by the interpreter to hold +// all value types. +// It is a 16-byte object with an 8-byte payload and an 8-byte tag. +// The tag is currently 4 bytes to determine the type, and 1 byte +// to mark whether that type is a subtype of c10::intrusive_ptr_target and needs +// retain/release calls. + +#define TORCH_FORALL_TAGS(_) \ + _(None) \ + _(Tensor) \ + _(Storage) \ + _(Double) \ + _(ComplexDouble) \ + _(Int) \ + _(SymInt) \ + _(SymFloat) \ + _(SymBool) \ + _(Bool) \ + _(Tuple) \ + _(String) \ + _(Blob) \ + _(GenericList) \ + _(GenericDict) \ + _(Future) \ + _(Await) \ + _(Device) \ + _(Stream) \ + _(Object) \ + _(PyObject) \ + _(Uninitialized) \ + _(Capsule) \ + _(RRef) \ + _(Quantizer) \ + _(Generator) \ + _(Enum) + +// [doxygen private] +// These methods are not actually private but we don't want to document them, so +// they are marked `@private`, which hides them on the doxygen documentation for +// this page. + +/// IValue (Interpreter Value) is a tagged union over the types +/// supported by the TorchScript interpreter. IValues contain their +/// values as an `IValue::Payload`, which holds primitive types +/// (`int64_t`, `bool`, `double`, `Device`) and `Tensor` as values, +/// and all other types as a `c10::intrusive_ptr`. In order to +/// optimize performance of the destructor and related operations by +/// making the `Tensor` and `c10::intrusive_ptr` paths generate the +/// same code, we represent a null `c10::intrusive_ptr` as +/// `UndefinedTensorImpl::singleton()`, *not* `nullptr`. +/// +/// IValues are used as inputs to and outputs from the TorchScript interpreter. +/// To retrieve the value contained within an IValue, use the `.toX()` methods, +/// where `X` is the type you are trying to get. Note that neither the `.toX()` +/// methods nor the templated `.to` functions do any kind of casting, they +/// only unwrap the contained value. For example: +/// +/// \rst +/// .. code-block:: cpp +/// +/// // Make the IValue +/// torch::IValue my_ivalue(26); +/// std::cout << my_ivalue << "\n"; +/// +/// // Unwrap the IValue +/// int64_t my_int = my_ivalue.toInt(); +/// std::cout << my_int << "\n"; +/// +/// // This will throw an error! +/// // `my_ivalue` is tagged as an int and cannot be used as another type +/// torch::Tensor my_tensor = my_ivalue.toTensor(); +/// \endrst +struct TORCH_API IValue final { + IValue(const IValue& rhs) : IValue(rhs.payload, rhs.tag) { + if (isIntrusivePtr() && + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton()) { + c10::raw::intrusive_ptr::incref(payload.u.as_intrusive_ptr); + } + } + + IValue(IValue&& rhs) noexcept : tag(rhs.tag) { + moveFrom(std::move(rhs)); + } + + /// @private [doxygen private] + ~IValue() { + destroy(); + } + + C10_ALWAYS_INLINE IValue& operator=(IValue&& rhs) & noexcept { + if (&rhs == this) { + return *this; + } + + destroy(); + moveFrom(std::move(rhs)); + return *this; + } + + IValue& operator=(IValue const& rhs) & { + *this = IValue(rhs); + return *this; + } + + void dump() const; + + /** + * Equality comparison. The semantics are the same as Python's `==`: + * 1. Numerical types are compared by value. + * 2. Tensors compute element-wise equality, returning a BoolTensor (see: + * `torch.eq()`) + * 3. Strings are compared by value. + * 4. Sequence types (list, tuple) are compared lexicographically by + * comparing their elements. Different sequence types never compare equal. + * 5. Mappings (dict) must have equal (key, value) pairs. + * 6. If not listed above, the default behavior for is to test identity + * equality (e.g. pointer equality). + * + * Why does this return an IValue instead of a bool? Because in PyTorch, + * `tensor1 == tensor2` returns a `BoolTensor`, not a bool. + * + * NOTE: we (like Python) assume that identity equality implies value equality + * for efficiency. + * TODO: need to support customizing equality + */ + IValue equals(const IValue& rhs) const; + /** + * This implements the same semantics as `bool(lhs == rhs)` in Python. which + * is the same as `equals()` except for Tensor types. + */ + TORCH_API friend bool operator==(const IValue& lhs, const IValue& rhs); + TORCH_API friend bool operator!=(const IValue& lhs, const IValue& rhs); + + /** + * Identity comparison. Checks if `this` is the same object as `rhs`. The + * semantics are the same as Python's `is` operator. + * + * NOTE: Like in Python, this operation is poorly defined for primitive types + * like numbers and strings. Prefer to use `==` unless you really want to + * check identity equality. + */ + bool is(const IValue& rhs) const; + + /** + * Hashing for IValues. Returns an IValue-boxed int. + * + * Some notes: + * - Like eager, Tensors are hashed by looking at the pointer. This is not + * strictly correct because two value-equal tensors with different tensor + * pointers will hash differently, but we choose to reproduce the eager + * semantics. + * - Hashing is not defined on all built-in IValue types (e.g. list and + * dict), following Python. Calling `hash()` on these types will throw. + */ + IValue hash() const { + return (int64_t)IValue::hash(*this); + } + // This is defined because `c10::hash` dispatches to a function of this + // signature. See the member function `hash()`. + static size_t hash(const IValue& iv); + + /** + * @private [doxygen private] + * [container equality] + * This is an equality implementation that assumes objects with the same + * identity equal themselves, for efficiency reasons. We primarily have this + * for consistency, because Python does the same thing. This actually + * provokes user-visible changes in behavior due to quirks in torch: + * [tensor1] == [tensor1] -> True (because container equality will first + * compare identity) [tensor1] == [tensor1_copy] -> RuntimeError: + * Boolean value of Tensor with more than one value is ambiguous + */ + TORCH_API friend bool _fastEqualsForContainer( + const IValue& lhs, + const IValue& rhs); + + private: + static bool isAliasOf(const at::Tensor& a, const at::Tensor& b) { + if (a.is_sparse()) { + return isAliasOf(a._values(), b) || isAliasOf(a._indices(), b); + } + if (b.is_sparse()) { + return isAliasOf(a, b._values()) || isAliasOf(a, b._indices()); + } + if (a.is_sparse_csr()) { + return isAliasOf(a.values(), b) || isAliasOf(a.crow_indices(), b) || + isAliasOf(a.col_indices(), b); + } + if (b.is_sparse_csr()) { + return isAliasOf(a, b.values()) || isAliasOf(a, b.crow_indices()) || + isAliasOf(a, b.col_indices()); + } + + // Opaque tensors such as the ones constructed by the MKL-DNN backend + // don't have storage so we just compare their TensorImpls. + // TODO: Find way to expose alias info for opaque tensors. + if (!a.has_storage() || !b.has_storage()) { + return a.unsafeGetTensorImpl() == b.unsafeGetTensorImpl(); + } + + return a.is_alias_of(b); + } + + template + bool isListOf() const; + + public: + /// @private [doxygen private] + bool isAliasOf(const IValue& rhs) const { + if (this->tag != rhs.tag) { + // Trivially don't alias if the type is different + return false; + } + + // Tensors should be compared based on internal storage + if (this->isTensor()) { + return isAliasOf(this->toTensor(), rhs.toTensor()); + } + + if (!isIntrusivePtr()) { + // Primitive types don't alias anything + return false; + } + + AT_ASSERT(rhs.isIntrusivePtr()); + + // Other types can be compared by their ptr value + return this->payload.u.as_intrusive_ptr == rhs.payload.u.as_intrusive_ptr; + } + + /// @private [doxygen private] + size_t use_count() const noexcept { + if (isTensor()) { + return payload.as_tensor.use_count(); + } + + if (!isIntrusivePtrLegacyBehavior()) { + return 1; + } + + if (payload.u.as_intrusive_ptr == c10::UndefinedTensorImpl::singleton()) { + return 0; + } + return c10::raw::intrusive_ptr::use_count(payload.u.as_intrusive_ptr); + } + + /// @private [doxygen private] + void swap(IValue& rhs) noexcept { + if (isTensor() && rhs.isTensor()) { + std::swap(payload.as_tensor, rhs.payload.as_tensor); + } else if (isTensor()) { + at::Tensor t = std::move(payload.as_tensor); + // As far as I can tell, omitting the usual explicit destructor call + // is not UB in and of itself, and it's a slight perf win. The + // destructor is a no-op, because the moved-from Tensor is + // effectively an intrusive_ptr in the null state, so we don't need + // the behavior for correctness reasons either. Leaving this + // explanatory comment, including commented-out destructor call, to + // make this abundantly clear. + // + // payload.as_tensor.~Tensor(); + payload.u = rhs.payload.u; + new (&rhs.payload.as_tensor) at::Tensor(std::move(t)); + } else if (rhs.isTensor()) { + rhs.swap(*this); + return; + } else { + std::swap(payload.u, rhs.payload.u); + } + std::swap(tag, rhs.tag); + } + + // Accessors for subtypes are arranged together below + // While some of these accessors could be generated through templates, + // we prefer to write them manually for clarity + + IValue(at::TensorBase t) : tag(Tag::Tensor) { + new (&payload.as_tensor) at::Tensor(std::move(t)); + } + bool isTensor() const { + return Tag::Tensor == tag; + } + + private: + // Outlined error path so that toTensor() can be inlined. + [[noreturn]] void reportToTensorTypeError() const; + + public: + at::Tensor toTensor() &&; + at::Tensor& toTensor() &; + const at::Tensor& toTensor() const&; + at::TensorImpl* unsafeToTensorImpl() const { + TORCH_INTERNAL_ASSERT(isTensor()); + return payload.as_tensor.unsafeGetTensorImpl(); + } + + IValue(at::Storage s) : tag(Tag::Storage) { + payload.u.as_intrusive_ptr = + null_to_undefined_tensor(s.unsafeReleaseStorageImpl()); + } + bool isStorage() const { + return Tag::Storage == tag; + } + c10::Storage toStorage() &&; + c10::Storage toStorage() const&; + + const IValue& toIValue() const { + return *this; + } + IValue& toIValue() { + return *this; + } + + /// @private [doxygen private] + IValue(intrusive_ptr blob) : tag(Tag::Blob) { + // TODO (after Tensor merge) If we pass in a Blob holding a Tensor, extract + // and store it as a Tensor instead. + payload.u.as_intrusive_ptr = null_to_undefined_tensor(blob.release()); + } + + /// @private [doxygen private] + bool isBlob() const { + return Tag::Blob == tag; + } + + /// @private [doxygen private] + c10::intrusive_ptr toBlob() &&; + + /// @private [doxygen private] + c10::intrusive_ptr toBlob() const&; + + // Capsule. No new callsites of these APIs should + // be introduced. + static inline IValue make_capsule( + intrusive_ptr blob); + bool isCapsule() const { + return Tag::Capsule == tag; + } + c10::intrusive_ptr toCapsule() &&; + c10::intrusive_ptr toCapsule() const&; + + // Custom C++ classes + template < + typename T, + std::enable_if_t, int> = 0> + IValue(intrusive_ptr custom_class); + bool isCustomClass() const; + template + c10::intrusive_ptr toCustomClass() &&; + template + c10::intrusive_ptr toCustomClass() const&; + + // Tuple + IValue(c10::intrusive_ptr v); + + template < + typename... Args, + std::enable_if_t< + !std::disjunction_v< + std::is_lvalue_reference..., + std::negation>...>, + std::nullptr_t> = nullptr> + IValue(const std::tuple& t); + template < + typename... Args, + std::enable_if_t< + !std::disjunction_v< + std::is_lvalue_reference..., + std::negation>...>, + std::nullptr_t> = nullptr> + IValue(std::tuple&& t); + bool isTuple() const { + return Tag::Tuple == tag; + } + c10::intrusive_ptr toTuple() &&; + c10::intrusive_ptr toTuple() const&; + [[nodiscard]] ivalue::Tuple& toTupleRef() const; + + // Double + IValue(double d) : tag(Tag::Double) { + payload.u.as_double = d; + } + bool isDouble() const { + return Tag::Double == tag; + } + double toDouble() const { + if (isDouble()) { + return payload.u.as_double; + } else if (isSymFloat()) { + return toSymFloat().guard_float(__FILE__, __LINE__); + } else { + TORCH_INTERNAL_ASSERT(0, "expected double"); + } + } + + // ComplexDouble + template + IValue(c10::complex c); + bool isComplexDouble() const { + return Tag::ComplexDouble == tag; + } + c10::complex toComplexDouble() const; + + // Future + IValue(c10::intrusive_ptr v); + bool isFuture() const { + return Tag::Future == tag; + } + c10::intrusive_ptr toFuture() &&; + c10::intrusive_ptr toFuture() const&; + + IValue(c10::intrusive_ptr v); + bool isAwait() const { + return Tag::Await == tag; + } + c10::intrusive_ptr toAwait() &&; + c10::intrusive_ptr toAwait() const&; + + // RRef + IValue(c10::intrusive_ptr v); + bool isRRef() const { + return Tag::RRef == tag; + } + c10::intrusive_ptr toRRef() &&; + c10::intrusive_ptr toRRef() const&; + + // Quantizer + IValue(c10::intrusive_ptr v); + bool isQuantizer() const { + return Tag::Quantizer == tag; + } + c10::intrusive_ptr toQuantizer() &&; + c10::intrusive_ptr toQuantizer() const&; + + // Int + IValue(int64_t i) : tag(Tag::Int) { + payload.u.as_int = i; + } + + IValue(const c10::SymInt& i) { + if (auto mi = i.maybe_as_int()) { + tag = Tag::Int; + payload.u.as_int = *mi; + } else { + tag = Tag::SymInt; + payload.u.as_intrusive_ptr = i.toSymNode().release(); + } + } + + bool isSymInt() const { + return Tag::SymInt == tag; + } + + c10::SymInt toSymInt() &&; + c10::SymInt toSymInt() const&; + + IValue(const c10::SymFloat& i) { + if (i.is_symbolic()) { + tag = Tag::SymFloat; + payload.u.as_intrusive_ptr = i.toSymNodeImpl().release(); + } else { + tag = Tag::Double; + payload.u.as_double = i.as_float_unchecked(); + } + } + + bool isSymFloat() const { + return Tag::SymFloat == tag; + } + + c10::SymFloat toSymFloat() &&; + c10::SymFloat toSymFloat() const&; + + IValue(const c10::SymBool& i) { + if (auto mi = i.maybe_as_bool()) { + tag = Tag::Bool; + payload.u.as_int = *mi; + } else { + tag = Tag::SymBool; + payload.u.as_intrusive_ptr = i.toSymNodeImpl().release(); + } + } + + bool isSymBool() const { + return Tag::SymBool == tag; + } + + c10::SymBool toSymBool() &&; + c10::SymBool toSymBool() const&; + + // allow you to pass literals (3, 4) without ambiguity + IValue(int32_t i) : IValue(static_cast(i)) {} + + bool isInt() const { + return Tag::Int == tag; + } + + int64_t toInt() const { + if (isInt()) { + return payload.u.as_int; + } else if (isSymInt()) { + return toSymInt().guard_int(__FILE__, __LINE__); + } else { + TORCH_INTERNAL_ASSERT(0, "expected int"); + } + } + + // Bool + IValue(bool b) : tag(Tag::Bool) { +#if defined(__clang__) && defined(__x86_64__) + // Initializing entire payload stops valgrind's from reporting + // "jump or move depends on uninitialised value" in IValue copy constructor + // See https://github.com/pytorch/pytorch/issues/37117 + payload.u.as_int = b; +#else + payload.u.as_bool = b; +#endif + } + bool isBool() const { + return Tag::Bool == tag; + } + bool toBool() const { + if (isBool()) { + return payload.u.as_bool; + } else if (isSymBool()) { + return toSymBool().guard_bool(__FILE__, __LINE__); + } else { + TORCH_INTERNAL_ASSERT(0, "expected bool"); + } + } + + // IntList + bool isIntList() const; + bool isSymIntList() const; + c10::List toIntList() &&; + c10::List toIntList() const&; + std::vector toIntVector() const; + c10::List toSymIntList() &&; + c10::List toSymIntList() const&; + std::vector toSymIntVector() const; + at::DimVector toDimVector() const; + + // ConstantString + IValue(c10::intrusive_ptr v); + IValue(std::string v); + IValue(const char* v) : IValue(std::string(v)) {} + IValue(std::string_view v) : IValue(std::string(v)){} + bool isString() const { + return Tag::String == tag; + } + c10::intrusive_ptr toString() &&; + c10::intrusive_ptr toString() const&; + const std::string& toStringRef() const; + std::optional> toOptionalStringRef() + const; + std::string_view toStringView() const; + + // DoubleList + bool isDoubleList() const; + c10::List toDoubleList() &&; + c10::List toDoubleList() const&; + std::vector toDoubleVector() const; + + // ComplexDoubleList + bool isComplexDoubleList() const; + c10::List> toComplexDoubleList() &&; + c10::List> toComplexDoubleList() const&; + std::vector> toComplexDoubleVector() const; + + // BoolList + bool isBoolList() const; + c10::List toBoolList() &&; + c10::List toBoolList() const&; + + // TensorList + bool isTensorList() const; + c10::List toTensorList() &&; + c10::List toTensorList() const&; + std::vector toTensorVector() const; + + // OptionalTensorList + bool isOptionalTensorList() const; + c10::List> toOptionalTensorList() &&; + c10::List> toOptionalTensorList() const&; + std::vector> toOptionalTensorVector() const; + + // GenericList + IValue(c10::List v); + bool isList() const { + return Tag::GenericList == tag; + } + c10::List toList() &&; + c10::List toList() const&; + c10::ArrayRef toListRef() const; + + // Some template constructors of IValue calls another constructor recursively. + // This SFINAEs the called constructor exists. + template + using enable_if_ivalue_constructible = + std::enable_if_t, std::nullptr_t>; + + // The rule for lists is more complicated; the generic constructor is only + // acceptable if your element isn't SymInt. If you do have a SymInt element, + // then you must also, at construction time, check if you can decay the list + // into an int list (this is MANDATORY, as at a use site we may expect + // toIntList to work even if at the call site you had a SymIntArrayRef + // argument). In practice, only SymIntArrayRef is used this way, so we + // didn't bother making it work for the other constructors, we just make sure + // they're not selectable. + template + using enable_if_list_is_ivalue_constructible = std::enable_if_t< + std::is_constructible_v && !std::is_same_v, + std::nullptr_t>; + + template = nullptr> + IValue(c10::List&& v); + template = nullptr> + IValue(const c10::List& v); + template = nullptr> + IValue(at::ArrayRef v); + template = nullptr> + IValue(const std::vector& v); + template = nullptr> + IValue(std::vector&& v); + template + IValue(std::array v); + + // Manual constructors for lists of symints, which decay to int list if + // possible. To avoid ambiguous overload situations, we template them + // to prevent implicit conversions + template + using enable_if_symint = + std::enable_if_t, std::nullptr_t>; + + template = nullptr> + IValue(at::ArrayRef v); + template = nullptr> + IValue(at::OptionalArrayRef v); + template = nullptr> + IValue(const std::vector& v); + template = nullptr> + IValue(std::vector&& v); + + template + using enable_if_ilist_is_ivalue_constructible = std::enable_if_t< + std::is_constructible_v && + std::is_constructible_v::boxed_type> && + !std::is_same_v, + std::nullptr_t>; + + template = nullptr> + IValue(c10::IListRef v); + + // GenericDict + IValue(c10::Dict v); + bool isGenericDict() const { + return Tag::GenericDict == tag; + } + c10::Dict toGenericDict() &&; + c10::Dict toGenericDict() const&; + + template + IValue(c10::Dict v); + + template + /// \cond + /// DOXYGEN_CANNOT_HANDLE_CONSTRUCTORS_WITH_MACROS_SO_EXCLUDE_THIS_LINE_FROM_DOXYGEN + C10_DEPRECATED_MESSAGE( + "IValues based on std::unordered_map are slow and deprecated. Please use c10::Dict instead.") + /// \endcond + IValue(std::unordered_map v); + + template = nullptr> + IValue(std::optional v); + template = nullptr> + IValue(c10::OptionalArrayRef v); + IValue(std::nullopt_t); + + // ClassType + IValue(c10::intrusive_ptr v); + bool isObject() const { + return tag == Tag::Object; + } + c10::intrusive_ptr toObject() &&; + c10::intrusive_ptr toObject() const&; + ivalue::Object& toObjectRef() const; + + torch::jit::Module toModule() const; + bool isModule() const; + + // PyObject + IValue(c10::intrusive_ptr v); + bool isPyObject() const { + return tag == Tag::PyObject; + } + c10::intrusive_ptr toPyObjectHolder() &&; + c10::intrusive_ptr toPyObjectHolder() const&; + PyObject* toPyObject() const; + + // Enum + explicit IValue(c10::intrusive_ptr v); + bool isEnum() const { + return tag == Tag::Enum; + } + c10::intrusive_ptr toEnumHolder() &&; + c10::intrusive_ptr toEnumHolder() const&; + + // None + IValue() = default; + bool isNone() const { + return Tag::None == tag; + } + std::string toNone() const { + AT_ASSERT(isNone()); + return "None"; + } + + static IValue uninitialized() { + auto i = IValue(); + i.tag = Tag::Uninitialized; + return i; + } + + // Scalar, which gets encoded as either an Int, a Double or a ComplexDouble + IValue(const at::Scalar& s) : IValue() { + // NB: do the symbolic versions first, as isFloatingPoint is true + // for both SymFloat and double + if (s.isSymInt()) { + tag = Tag::SymInt; + payload.u.as_intrusive_ptr = s.toSymInt().toSymNode().release(); + } else if (s.isSymFloat()) { + tag = Tag::SymFloat; + payload.u.as_intrusive_ptr = s.toSymFloat().toSymNodeImpl().release(); + } else if (s.isSymBool()) { + tag = Tag::SymBool; + payload.u.as_intrusive_ptr = s.toSymBool().toSymNodeImpl().release(); + } else if (s.isFloatingPoint()) { + tag = Tag::Double; + payload.u.as_double = s.toDouble(); + } else if (s.isComplex()) { + *this = s.toComplexDouble(); + } else if (s.isBoolean()) { + tag = Tag::Bool; + payload.u.as_bool = s.toBool(); + } else { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + s.isIntegral(false), "Unknown type in Scalar"); + tag = Tag::Int; + payload.u.as_int = s.toLong(); + } + } + + bool isScalar() const { + return isDouble() || isInt() || isComplexDouble() || isBool() || + isSymInt() || isSymFloat() || isSymBool(); + } + + at::Scalar toScalar() const { + if (isDouble()) + return toDouble(); + else if (isInt()) + return toInt(); + else if (isComplexDouble()) + return toComplexDouble(); + else if (isBool()) + return toBool(); + else if (isSymInt()) + return toSymInt(); + else if (isSymFloat()) + return toSymFloat(); + else if (isSymBool()) + return toSymBool(); + TORCH_CHECK(false, "IValue is not a Scalar"); + } + + // Device + IValue(c10::Device d) : tag(Tag::Device) { + payload.u.as_device.type = d.type(); + payload.u.as_device.index = d.index(); + } + bool isDevice() const { + return Tag::Device == tag; + } + c10::Device toDevice() const { + AT_ASSERT(isDevice()); + return c10::Device(payload.u.as_device.type, payload.u.as_device.index); + } + + // Stream + IValue(c10::Stream s) : tag(Tag::Stream) { + auto v = c10::make_intrusive(s.pack3()); + payload.u.as_intrusive_ptr = v.release(); + } + c10::Stream toStream() &&; + c10::Stream toStream() const&; + bool isStream() const { + return Tag::Stream == tag; + } + + // ScalarType + IValue(ScalarType t) + : IValue(static_cast>(t)) {} + at::ScalarType toScalarType() const { + return static_cast(toInt()); + } + + // Layout + IValue(Layout l) : IValue(static_cast>(l)) {} + at::Layout toLayout() const { + return static_cast(toInt()); + } + + // MemoryFormat + IValue(MemoryFormat m) + : IValue(static_cast>(m)) {} + at::MemoryFormat toMemoryFormat() const { + return static_cast(toInt()); + } + + // QScheme + IValue(at::QScheme qscheme) : tag(Tag::Int) { + payload.u.as_int = static_cast(qscheme); + } + + at::QScheme toQScheme() const { + return static_cast(toInt()); + } + + // Dimname + IValue(at::Dimname dimname) : IValue(dimname.symbol().toQualString()) {} + + at::Dimname toDimname() const { + return at::Dimname::fromSymbol(Symbol::fromQualString(toStringRef())); + } + + // Generator + IValue(at::Generator g) : tag(Tag::Generator) { + payload.u.as_intrusive_ptr = + null_to_undefined_tensor(g.unsafeReleaseGeneratorImpl()); + } + bool isGenerator() const { + return Tag::Generator == tag; + } + at::Generator toGenerator() &&; + at::Generator toGenerator() const&; + + // for debugging + std::string tagKind() const { + switch (tag) { +#define DEFINE_CASE(x) \ + case Tag::x: \ + return #x; + TORCH_FORALL_TAGS(DEFINE_CASE) +#undef DEFINE_CASE + } + return "InvalidTag(" + std::to_string(static_cast(tag)) + ")"; + } + + // generic v.to() implementations + // that can be used in special functions like pop/push + // that use template meta-programming. + // prefer the directly named methods when you can, + // since they are simpler to understand + + // Note: if you get linker errors saying one of these is missing, + // change it to ... && = delete; and you will see better error messages for + // why However, we cannot commit this because some compiler versions barf on + // it. + template + T to() &&; + template + typename c10::detail::ivalue_to_const_ref_overload_return::type to() + const&; + + // ToOptional: convert a IValue to the Optional obj that accepts both T and + // None + template + std::optional toOptional(); + template + std::optional toOptional() const; + + /// @private [doxygen private] + /// this is a shallow comparison of two IValues to test the object identity + bool isSameIdentity(const IValue& rhs) const; + + // Computes the "official" string representation of an IValue. This produces a + // TorchScript expression that can be used to recreate an IValue with the same + // value (e.g. when we are printing constants in the serializer). + // + // Callers can use `customFormatter` to override how `repr()` prints out an + // IValue. This is useful if you have some other environment where you can + // look up values, and you want to print a reference to that environment (like + // the serializer's constant table). + // + // repr() is not necessarily defined on all objects! + std::ostream& repr( + std::ostream& stream, + std::function customFormatter) + const; + + // Computes an "informal" string representation of an IValue. This should be + // used for debugging, or servicing `print()`-like functions. + // This is different from `repr()` in that there is no expectation that we can + // exactly reconstruct an IValue from the output; feel free to use a + // concise/pretty form + TORCH_API friend std::ostream& operator<<(std::ostream& out, const IValue& v); + + bool isPtrType() const { + if (isTensor()) { + return payload.as_tensor.defined(); + } + return isIntrusivePtrLegacyBehavior(); + } + + /// @private [doxygen private] + const void* internalToPointer() const { + TORCH_INTERNAL_ASSERT( + isPtrType(), "Can only call internalToPointer() for pointer types"); + if (isTensor()) { + return payload.as_tensor.unsafeGetTensorImpl(); + } else { + return payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton() + ? payload.u.as_intrusive_ptr + : nullptr; + } + } + + template + TypePtr type() const; + + // Detect aliased tensors. + struct HashAliasedIValue { + size_t hashTensor(const at::Tensor& ten) const { + if (ten.is_sparse()) { + // COO sparse tensors have a "values" tensor and an "indices" tensor + // so this will detect overlap of sparse tensors that share a values + // tensor, but not sparse tensors that share an indices tensor. + return hashTensor(ten._values()); + } else if (ten.is_sparse_csr()) { + // COO sparse tensors have a "values" tensor and an "indices" tensor + // so this will detect overlap of sparse tensors that share a values + // tensor, but not sparse tensors that share an indices tensor. + return hashTensor(ten.values()); + } else if (!ten.has_storage()) { + // Opaque tensors such as the ones constructed by the MKL-DNN backend + // don't have storage so we just use their TensorImpls. + // TODO: Find way to expose alias info for opaque tensors. + return reinterpret_cast(ten.unsafeGetTensorImpl()); + } else { + return reinterpret_cast(ten.storage().unsafeGetStorageImpl()); + } + } + size_t operator()(const IValue& val) const { + if (val.isTensor()) { + return hashTensor(val.toTensor()); + } + // If it is not a Tensor, then two mutable IValues alias each other only + // if they are the same pointer. + return val.payload.u.as_int; + } + }; + + struct CompAliasedIValues { + bool operator()(const IValue& lhs, const IValue& rhs) const { + return lhs.isAliasOf(rhs); + } + }; + + using HashAliasedIValues = + std::unordered_set; + using HashAliasedIValueMap = + std::unordered_map; + + struct HashIdentityIValue { + size_t operator()(const IValue& val) const { + return val.payload.u.as_int; + } + }; + + struct CompIdentityIValues { + bool operator()(const IValue& lhs, const IValue& rhs) const { + return lhs.is(rhs); + } + }; + + using HashIdentityIValues = + std::unordered_set; + using HashIdentityIValueMap = + std::unordered_map; + + // Chechs if this and rhs has a subvalues in common. + // [t1,t2] and [t2, t3] returns true. + bool overlaps(const IValue& rhs) const; + + // Inserts all subvalues of this in subValues. + void getSubValues(HashAliasedIValues& subValues) const; + + // Apply visitor to every subvalue. + // TODO: There are several places that recurse over IValue. This is fragile. + // This visitor should be used to recurse over ivalues. + void visit(const std::function& visitor) const; + IValue deepcopy(std::optional device = std::nullopt) const; + IValue deepcopy( + HashIdentityIValueMap& memo, + std::optional device = std::nullopt) const; + + private: + static c10::intrusive_ptr_target* null_to_undefined_tensor( + c10::intrusive_ptr_target* p) { + return p ? p + : static_cast( + c10::UndefinedTensorImpl::singleton()); + } + + static bool ptrEqual(const IValue& lhs, const IValue& rhs); + // NOTE: IValue tags are intentionally private. In the future we may encode + // this value different (e.g. using NaN boxing), and this would make it more + // costly to determine the tag for all types vs just determining if something + // is a particular type. Instead we want clients to use the `isX` methods when + // possible. If for performance reasons you really, absolutely, must have a jump + // table, then we can revisit this. + enum class Tag : uint32_t { +#define DEFINE_TAG(x) x, + TORCH_FORALL_TAGS(DEFINE_TAG) +#undef DEFINE_TAG + }; + +#define COUNT_TAG(x) 1 + + static constexpr auto kNumTags = TORCH_FORALL_TAGS(COUNT_TAG) 0; +#undef COUNT_TAG + + template < + class T, + class NullType = c10::detail::intrusive_target_default_null_type> + c10::intrusive_ptr moveToIntrusivePtr(); + template < + typename T, + class NullType = c10::detail::intrusive_target_default_null_type> + c10::intrusive_ptr toIntrusivePtr() const; + + void destroy() { + // We carefully construct this call to both 1) avoid UB by using + // the "wrong" one of as_tensor and as_intrusive_ptr and 2) enable + // the compiler to generate the same code for each case. It is + // surprisingly difficult to get this right. + if (isTensor() || isIntrusivePtr()) { + c10::intrusive_ptr_target* p = isTensor() + ? payload.as_tensor.unsafeGetTensorImpl() + : payload.u.as_intrusive_ptr; + c10::intrusive_ptr:: + reclaim(p); + // No need to make this destructor call! + // payload.as_tensor.~Tensor(); + } + } + + // NOLINTNEXTLINE(cppcoreguidelines-rvalue-reference-param-not-moved) + C10_ALWAYS_INLINE void moveFrom(IValue&& rhs) noexcept { + if (rhs.isTensor()) { + new (&payload.as_tensor) at::Tensor(std::move(rhs.payload.as_tensor)); + // As far as I can tell, omitting the usual explicit destructor call + // is not UB in and of itself, and it's a slight perf win. The + // destructor is a no-op, because the moved-from Tensor is + // effectively an intrusive_ptr in the null state, so we don't need + // the behavior for correctness reasons either. Leaving this + // explanatory comment, including commented-out destructor call, to + // make this abundantly clear. + // + // rhs.payload.as_tensor.~Tensor(); + } else { + payload.u = rhs.payload.u; + } + tag = rhs.tag; + rhs.clearToNone(); + } + + void clearToNone() noexcept { + payload.u.as_int = 0; + tag = Tag::None; + } + + private: + // This is the source of truth for isIntrusivePtr; edit results here + // as needed and isIntrusivePtr will pick them up. + // NOLINTBEGIN(bugprone-branch-clone) + static constexpr bool isIntrusivePtrConstexpr(Tag tag) { + switch (tag) { + case Tag::None: + return false; + case Tag::Tensor: + return false; + case Tag::Storage: + return true; + case Tag::Generator: + return true; + case Tag::Double: + return false; + case Tag::ComplexDouble: + return true; + case Tag::Int: + return false; + case Tag::SymInt: + return true; + case Tag::SymFloat: + return true; + case Tag::SymBool: + return true; + case Tag::Bool: + return false; + case Tag::Tuple: + return true; + case Tag::String: + return true; + case Tag::Blob: + return true; + case Tag::GenericList: + return true; + case Tag::GenericDict: + return true; + case Tag::Future: + return true; + case Tag::Await: + return true; + case Tag::Device: + return false; + case Tag::Stream: + return true; + case Tag::Object: + return true; + case Tag::PyObject: + return true; + case Tag::Uninitialized: + return false; + case Tag::Capsule: + return true; + case Tag::RRef: + return true; + case Tag::Quantizer: + return true; + case Tag::Enum: + return true; + } + return false; + } + // NOLINTEND(bugprone-branch-clone) + + public: + // Don't edit this just to add results for new tags; edit + // isIntrusivePtrConstexpr above. + bool isIntrusivePtr() const { + // Implementation NOTE: the switch in isIntrusivePtrConstexpr + // above is the previous production implementation of this + // function. We observed that, at least on x86_64, the generated + // instruction sequence was a similar bit vector test to what we + // have manually implemented below, except that there was an extra + // "bounds check" branch confirming, essentially, that `tag < + // kNumTags` and providing a consistent result in that case. We + // don't care about the result if tag is out of bounds, so we'd + // like to eliminate that comparison and branch; manually + // implementing this function as a bit test is the simplest way I + // could find to accomplish that elimination. + static constexpr uint32_t kTruthTableBitVector = +#define TRUTH_TABLE_ENTRY(tag) \ + (uint32_t(isIntrusivePtrConstexpr(Tag::tag)) << uint32_t(Tag::tag)) | + TORCH_FORALL_TAGS(TRUTH_TABLE_ENTRY) +#undef TRUTH_TABLE_ENTRY + 0; + + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + static_cast(tag) < kNumTags, + "unexpected tag ", + static_cast(tag)); + return kTruthTableBitVector & (1 << (uint32_t(tag) % 32)); + } + + // Storage and Generator were treated specially when + // is_intrusive_ptr was stored as explicit state. This getter + // preserves the old behavior for use with WeakIValue for now. + bool isIntrusivePtrLegacyBehavior() const { + if (tag == Tag::Storage || tag == Tag::Generator) { + return payload.u.as_intrusive_ptr != + c10::UndefinedTensorImpl::singleton(); + } else { + return isIntrusivePtr(); + } + } + + union Payload { + // [TriviallyCopyablePayload] + // We use a nested union here so that we can make the copy easy + // and efficient in the non-tensor (i.e., trivially copyable) + // case. Specifically, we do not have to do a switch-on-tag to + // figure out which union member to assign; we can just use + // TriviallyCopyablePayload::operator=. + union TriviallyCopyablePayload { + TriviallyCopyablePayload() : as_int(0) {} + int64_t as_int; + double as_double; + bool as_bool; + // Invariant: never nullptr; null state is represented as + // c10::UndefinedTensorImpl::singleton() for consistency of + // representation with Tensor. + c10::intrusive_ptr_target* as_intrusive_ptr; + struct { + c10::DeviceType type; + DeviceIndex index; + } as_device; + } u; + static_assert(std::is_trivially_copyable_v); + at::Tensor as_tensor; + Payload() : u() {} + Payload(const Payload&) = delete; + Payload(Payload&&) = delete; + Payload& operator=(const Payload&) = delete; + Payload& operator=(Payload&&) = delete; + // NOLINTNEXTLINE(modernize-use-equals-default) + ~Payload() {} + }; + + IValue(const Payload& p, Tag t) : tag(t) { + if (isTensor()) { + new (&payload.as_tensor) at::Tensor(p.as_tensor); + } else { + payload.u = p.u; + } + } + + template + struct TagType {}; + + friend MaybeOwnedTraits; + + Payload payload; + Tag tag{IValue::Tag::None}; + friend struct WeakIValue; +}; + +struct TORCH_API WeakIValue final { + WeakIValue() = default; + + WeakIValue(const WeakIValue& rhs) + : payload(rhs.payload), + tag(rhs.tag), + is_intrusive_ptr(rhs.is_intrusive_ptr) { + if (is_intrusive_ptr && + payload.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton()) { + c10::raw::weak_intrusive_ptr::incref(payload.as_intrusive_ptr); + } + } + WeakIValue(const IValue& rhs) + : tag(rhs.tag), is_intrusive_ptr(rhs.isIntrusivePtrLegacyBehavior()) { + if (rhs.isTensor()) { + payload.as_intrusive_ptr = rhs.unsafeToTensorImpl(); + is_intrusive_ptr = true; + } else { + payload = rhs.payload.u; + } + if (is_intrusive_ptr) { + if (payload.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton()) { + c10::raw::weak_intrusive_ptr::incref(payload.as_intrusive_ptr); + } + } + } + WeakIValue(WeakIValue&& rhs) noexcept : WeakIValue() { + swap(rhs); + } + ~WeakIValue() { + if (is_intrusive_ptr && + payload.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton()) { + c10::raw::weak_intrusive_ptr::decref(payload.as_intrusive_ptr); + } + } + WeakIValue& operator=(WeakIValue&& rhs) & noexcept { + WeakIValue(std::move(rhs)).swap(*this); // this also sets rhs to None + return *this; + } + WeakIValue& operator=(WeakIValue const& rhs) & { + WeakIValue(rhs).swap(*this); + return *this; + } + void swap(WeakIValue& rhs) noexcept { + std::swap(payload, rhs.payload); + std::swap(is_intrusive_ptr, rhs.is_intrusive_ptr); + std::swap(tag, rhs.tag); + } + + bool isSameIdentity(const WeakIValue& rhs) const { + return payload.as_int == rhs.payload.as_int && tag == rhs.tag && + is_intrusive_ptr == rhs.is_intrusive_ptr; + } + + IValue lock() const { + if (!is_intrusive_ptr) { + IValue::Payload newPayload; + newPayload.u = payload; + return IValue(newPayload, tag); + } + if (IValue::Tag::Tensor == tag) { + auto temp = + c10::weak_intrusive_ptr:: + reclaim(static_cast(payload.as_intrusive_ptr)); + c10::intrusive_ptr ip( + temp.lock()); + temp.release(); + if (!ip) { + return IValue(); + } else { + return IValue(at::Tensor(std::move(ip))); + } + } else { + auto temp = c10::weak_intrusive_ptr::reclaim( + payload.as_intrusive_ptr == c10::UndefinedTensorImpl::singleton() + ? nullptr + : payload.as_intrusive_ptr); + IValue::Payload pl; + pl.u.as_intrusive_ptr = temp.lock().release(); + temp.release(); + if (!pl.u.as_intrusive_ptr) { + return IValue(); + } else { + return IValue(pl, tag); + } + } + } + + size_t use_count() const noexcept { + if (!is_intrusive_ptr) { + return 1; + } + auto temp = c10::weak_intrusive_ptr< + c10::intrusive_ptr_target, + c10::UndefinedTensorImpl>::reclaim(payload.as_intrusive_ptr); + size_t result = temp.use_count(); + temp.release(); + return result; + } + + size_t weak_use_count() const noexcept { + if (!is_intrusive_ptr) { + return 1; + } + auto temp = c10::weak_intrusive_ptr< + c10::intrusive_ptr_target, + c10::UndefinedTensorImpl>::reclaim(payload.as_intrusive_ptr); + size_t result = temp.weak_use_count(); + temp.release(); + return result; + } + size_t hash() const { + return payload.as_int; + } + + private: + using Payload = IValue::Payload::TriviallyCopyablePayload; + Payload payload; + IValue::Tag tag{IValue::Tag::None}; + bool is_intrusive_ptr{false}; +}; + +// An owning pointer to a type. When the type is class type, it requires a pair +// of shared_ptrs to the class type and its owning CU, so that the class type is +// guaranteed to stay alive as long as we hold this object. +struct TORCH_API StrongTypePtr { + StrongTypePtr(std::shared_ptr cu, TypePtr type); + + std::shared_ptr cu_; + TypePtr type_; +}; + +// [Constant Object Weak CompilationUnit Reference] +// A non owning pointer to a type. When a class get inserted as a constant +// into a graph, if we used a strong pointer we would have a circular reference +// from Object -> CompilationUnit and CompilationUnit -> Graph (which owns the +// Constant Object) +struct TORCH_API WeakTypePtr { + WeakTypePtr(std::weak_ptr cu, TypePtr type); + + std::weak_ptr cu_; + TypePtr type_; +}; + +// internal build errors with std::variant :/ +struct WeakOrStrongCompilationUnit { + explicit WeakOrStrongCompilationUnit( + std::shared_ptr shared_cu) + : strong_ptr_(std::move(shared_cu)), weak_ptr_(std::nullopt) {} + + explicit WeakOrStrongCompilationUnit( + std::weak_ptr weak_cu) + : strong_ptr_(std::nullopt), weak_ptr_(std::move(weak_cu)) {} + + std::shared_ptr getStrongRefOrThrow() const { + TORCH_INTERNAL_ASSERT(strong_ptr_.has_value()); + return *strong_ptr_; + } + + std::weak_ptr getWeakRefOrThrow() const { + TORCH_INTERNAL_ASSERT(weak_ptr_.has_value()); + return *weak_ptr_; + } + + bool holdingStrongRef() const { + return strong_ptr_.has_value(); + } + + bool holdingEmptyStrongRef() const { + return strong_ptr_ == nullptr; + } + + std::optional> strong_ptr_; + std::optional> weak_ptr_; +}; + +// An Object will hold a non-owning Compilation Unit reference if it is a +// Constant in the graph and a Owning reference otherwise +struct TORCH_API WeakOrStrongTypePtr { + explicit WeakOrStrongTypePtr(WeakTypePtr weak) + : cu_(WeakOrStrongCompilationUnit(std::move(weak.cu_))), + type_(std::move(weak.type_)) {} + explicit WeakOrStrongTypePtr(StrongTypePtr strong) + : cu_(WeakOrStrongCompilationUnit(std::move(strong.cu_))), + type_(std::move(strong.type_)) {} + explicit WeakOrStrongTypePtr(WeakOrStrongCompilationUnit cu, TypePtr type) + : cu_(std::move(cu)), type_(std::move(type)) {} + WeakTypePtr asWeakTypePtr() const; + + WeakOrStrongCompilationUnit cu_; + TypePtr type_; + + bool holds_strong_ref() const { + return cu_.holdingStrongRef(); + } + + bool holds_empty_strong_ref() const { + return cu_.holdingEmptyStrongRef(); + } +}; + +} // namespace c10 + +#include // IWYU pragma: keep diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ivalue_inl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ivalue_inl.h new file mode 100644 index 0000000000000000000000000000000000000000..1251c4c0c210dd139b72491763122176184ce67e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ivalue_inl.h @@ -0,0 +1,2569 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace torch { +namespace jit { +struct Function; +struct CompilationUnit; +} // namespace jit +TORCH_API bool isCustomClass(const c10::IValue& v); +} // namespace torch +namespace c10 { +struct IValue; +struct ClassType; +struct TupleType; +struct EnumType; +struct InferredType; + +// For custom class __init__ registration, we need to pass in a function +// that looks like this: [](IValue x, args...) + +// However, make_boxed_from_unboxed_functor.h automatically sets the input types +// of the function by introspecting the types of the functor (which is IValue in +// this case). However, we need the type it binds to be Foo. + +// Instead, we pass in a lambda [](ivalue_holder x, args...) from +// which getTypePtr can recover the original class pointer. + +template +struct tagged_capsule { + IValue ivalue; +}; + +template +c10::intrusive_ptr IValue::moveToIntrusivePtr() { + auto t = c10::intrusive_ptr::reclaim( + payload.u.as_intrusive_ptr == c10::UndefinedTensorImpl::singleton() + ? NullType::singleton() + : static_cast(payload.u.as_intrusive_ptr)); + clearToNone(); + return t; +} +template +c10::intrusive_ptr IValue::toIntrusivePtr() const { + if (payload.u.as_intrusive_ptr == c10::UndefinedTensorImpl::singleton()) { + return c10::intrusive_ptr(); + } + c10::raw::intrusive_ptr::incref(payload.u.as_intrusive_ptr); + return c10::intrusive_ptr::reclaim( + static_cast(payload.u.as_intrusive_ptr)); +} + +template +intrusive_ptr static_intrusive_pointer_cast(intrusive_ptr r) { + return intrusive_ptr::reclaim(static_cast(r.release())); +} + +template +intrusive_ptr dynamic_intrusive_pointer_cast(intrusive_ptr r) { + return intrusive_ptr::reclaim(dynamic_cast(r.release())); +} + +inline c10::intrusive_ptr IValue::toFuture() && { + AT_ASSERT(isFuture(), "Expected Future but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toFuture() const& { + AT_ASSERT(isFuture(), "Expected Future but got ", tagKind()); + return toIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toAwait() && { + AT_ASSERT(isAwait(), "Expected Await but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toAwait() const& { + AT_ASSERT(isAwait(), "Expected Await but got ", tagKind()); + return toIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toRRef() && { + AT_ASSERT(isRRef(), "Expected RRef but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toRRef() const& { + AT_ASSERT(isRRef(), "Expected RRef but got ", tagKind()); + return toIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toQuantizer() && { + AT_ASSERT(isQuantizer(), "Expected Quantizer but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toQuantizer() const& { + AT_ASSERT(isQuantizer(), "Expected Quantizer but got ", tagKind()); + return toIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toString() && { + AT_ASSERT(isString(), "Expected String but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toString() const& { + AT_ASSERT(isString(), "Expected String but got ", tagKind()); + return toIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toObject() && { + AT_ASSERT(isObject(), "Expected Object but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toObject() const& { + AT_ASSERT(isObject(), "Expected Object but got ", tagKind()); + return toIntrusivePtr(); +} +inline c10::intrusive_ptr IValue:: + toPyObjectHolder() && { + TORCH_INTERNAL_ASSERT(isPyObject(), "Expected PyObject but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toPyObjectHolder() + const& { + TORCH_INTERNAL_ASSERT(isPyObject(), "Expected PyObject but got ", tagKind()); + return toIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toEnumHolder() && { + TORCH_INTERNAL_ASSERT(isEnum(), "Expected Enum but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toEnumHolder() const& { + TORCH_INTERNAL_ASSERT(isEnum(), "Expected Enum but got ", tagKind()); + return toIntrusivePtr(); +} +inline c10::complex IValue::toComplexDouble() const { + TORCH_INTERNAL_ASSERT(isComplexDouble(), "Expected ComplexDouble but got ", tagKind()); + auto ptr = toIntrusivePtr(); + return (*ptr).val; +} +inline at::Tensor IValue::toTensor() && { + if (C10_UNLIKELY(!isTensor())) { + reportToTensorTypeError(); + } + auto result = std::move(payload.as_tensor); + // As far as I can tell, omitting the usual explicit destructor call + // is not UB in and of itself, and it's a slight perf win. The + // destructor is a no-op, because the moved-from Tensor is + // effectively an intrusive_ptr in the null state, so we don't need + // the behavior for correctness reasons either. Leaving this + // explanatory comment, including commented-out destructor call, to + // make this abundantly clear. + // + // payload.as_tensor.~Tensor(); + clearToNone(); + return result; +} +inline at::Tensor& IValue::toTensor() & { + if (C10_UNLIKELY(!isTensor())) { + reportToTensorTypeError(); + } + return payload.as_tensor; +} +inline const at::Tensor& IValue::toTensor() const& { + if (C10_UNLIKELY(!isTensor())) { + reportToTensorTypeError(); + } + return payload.as_tensor; +} +inline c10::Storage IValue::toStorage() && { + AT_ASSERT(isStorage(), "Expected Storage but got ", tagKind()); + return c10::Storage( + moveToIntrusivePtr()); +} +inline c10::Storage IValue::toStorage() const& { + AT_ASSERT(isStorage(), "Expected Storage but got ", tagKind()); + return c10::Storage(toIntrusivePtr()); +} +inline c10::Stream IValue::toStream() && { + AT_ASSERT(isStream(), "Expected Stream but got ", tagKind()); + auto ptr = toIntrusivePtr(); + return c10::Stream::unpack3((*ptr).val.stream_id, + (*ptr).val.device_index, + (*ptr).val.device_type); +} +inline c10::Stream IValue::toStream() const& { + AT_ASSERT(isStream(), "Expected Stream but got ", tagKind()); + auto ptr = toIntrusivePtr(); + return c10::Stream::unpack3((*ptr).val.stream_id, + (*ptr).val.device_index, + (*ptr).val.device_type); +} +inline c10::intrusive_ptr IValue::toBlob() && { + AT_ASSERT(isBlob(), "Expected Blob but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toBlob() const& { + AT_ASSERT(isBlob(), "Expected Blob but got ", tagKind()); + return toIntrusivePtr(); + ; +} +inline c10::intrusive_ptr IValue::toCapsule() && { + TORCH_INTERNAL_ASSERT(isCapsule()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toCapsule() const& { + TORCH_INTERNAL_ASSERT(isCapsule()); + return toIntrusivePtr(); +} +inline at::Generator IValue::toGenerator() && { + AT_ASSERT(isGenerator(), "Expected Generator but got ", tagKind()); + return at::Generator(moveToIntrusivePtr()); +} +inline at::Generator IValue::toGenerator() const& { + AT_ASSERT(isGenerator(), "Expected Generator but got ", tagKind()); + return at::Generator(toIntrusivePtr()); +} +inline c10::SymInt IValue::toSymInt() && { + AT_ASSERT(isSymInt() || isInt(), "Expected SymInt or int but got ", tagKind()); + if (isSymInt()) { + return c10::SymInt(moveToIntrusivePtr()); + } else { + return c10::SymInt(payload.u.as_int); + } +} +inline c10::SymInt IValue::toSymInt() const& { + AT_ASSERT(isSymInt() || isInt(), "Expected SymInt or int but got ", tagKind()); + if (isSymInt()) { + return c10::SymInt(toIntrusivePtr()); + } else { + return c10::SymInt(payload.u.as_int); + } +} +inline c10::SymFloat IValue::toSymFloat() && { + AT_ASSERT(isSymFloat() || isDouble(), "Expected SymFloat or double but got ", tagKind()); + if (isSymFloat()) { + return c10::SymFloat(moveToIntrusivePtr()); + } else { + return c10::SymFloat(payload.u.as_double); + } +} +inline c10::SymFloat IValue::toSymFloat() const& { + AT_ASSERT(isSymFloat() || isDouble(), "Expected SymFloat or double but got ", tagKind()); + if (isSymFloat()) { + return c10::SymFloat(toIntrusivePtr()); + } else { + return c10::SymFloat(payload.u.as_double); + } +} +inline c10::SymBool IValue::toSymBool() && { + AT_ASSERT(isSymBool() || isBool(), "Expected SymBool or boolean but got ", tagKind()); + if (isSymBool()) { + return c10::SymBool(moveToIntrusivePtr()); + } else { + return c10::SymBool(payload.u.as_bool); + } +} + +inline c10::SymBool IValue::toSymBool() const& { + AT_ASSERT(isSymBool() || isBool(), "Expected SymBool or boolean but got ", tagKind()); + if (isSymBool()) { + return c10::SymBool(toIntrusivePtr()); + } else { + return c10::SymBool(payload.u.as_bool); + } +} + +namespace ivalue { + +void TORCH_API +checkCustomClassType(const ClassType* expected_type, const Type* actual_type); + +template +using Shared = c10::intrusive_ptr; + +// string +struct TORCH_API ConstantString final : c10::intrusive_ptr_target { + private: + // NOLINTNEXTLINE(cppcoreguidelines-avoid-const-or-ref-data-members) + const std::string str_; + + public: + ConstantString(std::string str) : str_(std::move(str)) {} + ConstantString(std::string_view str) : str_(std::string(str)) {} + static c10::intrusive_ptr create(std::string str_); + static c10::intrusive_ptr create(std::string_view str_); + static c10::intrusive_ptr create(const char* str_); + + const std::string& string() const { + return str_; + } + std::string_view string_view() const { + return str_; + } + + operator const std::string&() const { + return string(); + } + TORCH_API friend std::ostream& operator<<( + std::ostream& out, + const ConstantString& v); +}; + +struct Future; + +struct TORCH_API TupleElements { + private: + size_t inlineSize_; + // We represent TupleElements this way to save doing a heap + // allocation in the common (at least for unpickling) case where we + // have only 3 elements. We have our own union instead of + // c10::SmallVector because c10::SmallVector always + // stores the begin/end/capacity pointers, which would be a waste of + // space in our use case. + union { + std::vector elementsVector_; + // Don't want to declare a std::array because the convenient + // iteration and size members are a footgun in this case -- the + // actual size of the array may be smaller than 3! + // NOLINTNEXTLINE(*c-arrays*) + IValue elementsInline_[3]; + }; + + void destroyInline() { + for (const auto ii : c10::irange(inlineSize_)) { + elementsInline_[ii].~IValue(); + } + } + public: + + using iterator = IValue*; + using const_iterator = const IValue*; + + TupleElements() : inlineSize_(0) { + new (&elementsVector_) std::vector(); + } + + explicit TupleElements(std::vector elements) + : inlineSize_(0), elementsVector_(std::move(elements)) {} + + explicit TupleElements(c10::ArrayRef elements) + : inlineSize_(elements.size() <= 3 ? elements.size() : 0) { + switch (inlineSize_) { + case 3: + new (&elementsInline_[2]) IValue(elements[2]); + [[fallthrough]]; + case 2: + new (&elementsInline_[1]) IValue(elements[1]); + [[fallthrough]]; + case 1: + new (&elementsInline_[0]) IValue(elements[0]); + break; + case 0: + new (&elementsVector_) std::vector(elements.begin(), elements.end()); + break; + } + } + + explicit TupleElements(IValue&& e1) + : inlineSize_(1) { + new (&elementsInline_[0]) IValue(std::move(e1)); + } + + explicit TupleElements(IValue&& e1, IValue&& e2) + : inlineSize_(2) { + new (&elementsInline_[0]) IValue(std::move(e1)); + new (&elementsInline_[1]) IValue(std::move(e2)); + } + + explicit TupleElements(IValue&& e1, IValue&& e2, IValue&& e3) + : inlineSize_(3) { + new (&elementsInline_[0]) IValue(std::move(e1)); + new (&elementsInline_[1]) IValue(std::move(e2)); + new (&elementsInline_[2]) IValue(std::move(e3)); + } + + ~TupleElements() { + if (inlineSize_) { + destroyInline(); + } else { + elementsVector_.~vector(); + } + } + + // It would be nice to make this noncopyable to prevent people from + // writing code like `auto output = + // forward(...).toTupleRef().elements()` (which does refcount bumps on + // each element, unlike the more efficient but verbose + // ``` + // auto outputIntrusivePtr = forward(...).toTuple(); + // const auto& output = outputIntrusivePtr->elements(); + // ``` + // ), but there is simply an overwhelming amount of code that does + // it the inefficient way. + // See also operator std::vector below. + TupleElements(const TupleElements& rhs) + : inlineSize_(rhs.inlineSize_) { + if (rhs.inlineSize_) { + for (const auto ii : c10::irange(inlineSize_)) { + new (&elementsInline_[ii]) IValue(rhs.elementsInline_[ii]); + } + } else { + new (&elementsVector_) std::vector(rhs.elementsVector_); + } + } + + TupleElements& operator=(const TupleElements& rhs) { + if (inlineSize_) { + if (rhs.inlineSize_) { + for (const auto ii : c10::irange(std::min(inlineSize_, rhs.inlineSize_))) { + elementsInline_[ii] = rhs.elementsInline_[ii]; + } + if (rhs.inlineSize_ > inlineSize_) { + for (const auto ii : c10::irange(inlineSize_, rhs.inlineSize_)) { + new (&elementsInline_[ii]) IValue(rhs.elementsInline_[ii]); + } + } else { + for (const auto ii : c10::irange(rhs.inlineSize_, inlineSize_)) { + elementsInline_[ii].~IValue(); + } + } + } else { + destroyInline(); + new (&elementsVector_) std::vector(rhs.elementsVector_); + } + } else { + if (rhs.inlineSize_) { + elementsVector_.~vector(); + for (const auto ii : c10::irange(rhs.inlineSize_)) { + new (&elementsInline_[ii]) IValue(rhs.elementsInline_[ii]); + } + } else { + elementsVector_ = rhs.elementsVector_; + } + } + inlineSize_ = rhs.inlineSize_; + return *this; + } + + TupleElements(TupleElements&& rhs) noexcept + : inlineSize_(rhs.inlineSize_) { + if (inlineSize_) { + for (const auto ii : c10::irange(inlineSize_)) { + new (&elementsInline_[ii]) IValue(std::move(rhs.elementsInline_[ii])); + } + } else { + new (&elementsVector_) std::vector(std::move(rhs.elementsVector_)); + } + } + + TupleElements& operator=(TupleElements&& rhs) noexcept { + if (inlineSize_) { + if (rhs.inlineSize_) { + for (const auto ii : c10::irange(std::min(inlineSize_, rhs.inlineSize_))) { + elementsInline_[ii] = std::move(rhs.elementsInline_[ii]); + } + if (rhs.inlineSize_ > inlineSize_) { + for (const auto ii : c10::irange(inlineSize_, rhs.inlineSize_)) { + new (&elementsInline_[ii]) IValue(std::move(rhs.elementsInline_[ii])); + } + } else { + for (const auto ii : c10::irange(rhs.inlineSize_, inlineSize_)) { + elementsInline_[ii].~IValue(); + } + } + } else { + destroyInline(); + new (&elementsVector_) std::vector(std::move(rhs.elementsVector_)); + } + } else { + if (rhs.inlineSize_) { + elementsVector_.~vector(); + for (const auto ii : c10::irange(rhs.inlineSize_)) { + new (&elementsInline_[ii]) IValue(std::move(rhs.elementsInline_[ii])); + } + } else { + elementsVector_ = std::move(rhs.elementsVector_); + } + } + inlineSize_ = rhs.inlineSize_; + return *this; + } + + [[nodiscard]] c10::ArrayRef asArrayRef() const { + if (inlineSize_) { + return c10::ArrayRef(elementsInline_, inlineSize_); + } else { + return elementsVector_; + } + } + + // Mimic implicit conversion from std::vector to ArrayRef. + operator c10::ArrayRef() const { + return asArrayRef(); + } + + static size_t hash(const TupleElements& v) { + return c10::hash>()(v.asArrayRef()); + } + + void setContents(std::vector&& contents) { + if (inlineSize_) { + destroyInline(); + new (&elementsVector_) std::vector(std::move(contents)); + inlineSize_ = 0; + } else { + elementsVector_ = std::move(contents); + } + } + + [[nodiscard]] bool empty() const { + return inlineSize_ ? false : elementsVector_.empty(); + } + + [[nodiscard]] size_t size() const { + return inlineSize_ ? inlineSize_ : elementsVector_.size(); + } + + [[nodiscard]] IValue& operator[](size_t idx) { + if (inlineSize_) { + return elementsInline_[idx]; + } else { + return elementsVector_[idx]; + } + } + + [[nodiscard]] const IValue& operator[](size_t idx) const { + if (inlineSize_) { + return elementsInline_[idx]; + } else { + return elementsVector_[idx]; + } + } + + [[nodiscard]] IValue& at(size_t idx) { + if (inlineSize_) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(inlineSize_ <= 3); + TORCH_CHECK(idx < inlineSize_, "TupleElements: invalid index Index = ", idx, "; Length = ", inlineSize_); + return elementsInline_[idx]; + } else { + return elementsVector_.at(idx); + } + } + + [[nodiscard]] const IValue& at(size_t idx) const { + if (inlineSize_) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(inlineSize_ <= 3); + TORCH_CHECK(idx < inlineSize_, "TupleElements: invalid index Index = ", idx, "; Length = ", inlineSize_); + return elementsInline_[idx]; + } else { + TORCH_CHECK(idx < elementsVector_.size(), "TupleElements: invalid index Index = ", idx, "; Length = ", elementsVector_.size()); + return elementsVector_.at(idx); + } + } + + [[nodiscard]] iterator begin() { + if (inlineSize_) { + return elementsInline_; + } else { + return elementsVector_.data(); + } + } + + [[nodiscard]] iterator end() { + if (inlineSize_) { + return elementsInline_ + inlineSize_; + } else { + return elementsVector_.data() + elementsVector_.size(); + } + } + + [[nodiscard]] const_iterator begin() const { + if (inlineSize_) { + return elementsInline_; + } else { + return elementsVector_.data(); + } + } + + [[nodiscard]] const_iterator end() const { + if (inlineSize_) { + return elementsInline_ + inlineSize_; + } else { + return elementsVector_.data() + elementsVector_.size(); + } + } + + [[nodiscard]] const_iterator cbegin() const { + return begin(); + } + + [[nodiscard]] const_iterator cend() const { + return end(); + } + + [[nodiscard]] std::vector vec() const& { + return asArrayRef().vec(); + } + + [[nodiscard]] IValue& back() { + return *(end() - 1); + } + + [[nodiscard]] const IValue& back() const { + return *(end() - 1); + } + + [[nodiscard]] std::vector vec() && { + std::vector result; + result.reserve(size()); + for (auto&& iv : *this) { + result.push_back(std::move(iv)); + } + return result; + } + + // More compatibility shims for the overwhelming amount of code that + // likes to copy tuple elements into a vector; see comment above the + // copy constructor. + operator std::vector() const & { + return vec(); + } + + operator std::vector() && { + return vec(); + } +}; + +template +struct TupleTypeFactory {}; + +template <> +struct TORCH_API TupleTypeFactory { + static TupleTypePtr create(std::vector types) { + return TupleType::create(std::move(types)); + } + static TupleTypePtr fallback(const Type& type); +}; + +template <> +struct TORCH_API TupleTypeFactory { + static DynamicTypePtr create(const std::vector& elemTypes); + static DynamicTypePtr fallback(const Type&); +}; + +struct TORCH_API Tuple : c10::intrusive_ptr_target { + private: + TupleElements elements_; + mutable c10::TypePtr type_; // lazily computed for unnamed tuples + + public: + // named tuples have additional type information, so we + // directly create them tagged + static c10::intrusive_ptr createNamed( + std::vector elements_, + c10::TypePtr type_) { + return c10::make_intrusive(std::move(elements_), std::move(type_)); + } + + static c10::intrusive_ptr createNamed( + TupleElements elements_, + std::shared_ptr type_) { + return c10::make_intrusive(std::move(elements_), std::move(type_)); + } + + static c10::intrusive_ptr createNamed( + std::initializer_list elements_, + std::shared_ptr type_) { + return createNamed(TupleElements(c10::ArrayRef(elements_)), std::move(type_)); + } + + // MSVC apparently can't disambiguate the other two overloads of + // create when passed an initializer_list without this. + static c10::intrusive_ptr create(std::initializer_list elements_) { + return create(c10::ArrayRef(elements_)); + } + + static c10::intrusive_ptr create(std::vector elements_) { + return c10::make_intrusive(std::move(elements_)); + } + + static c10::intrusive_ptr create(TupleElements elements_) { + return c10::make_intrusive(std::move(elements_)); + } + + static c10::intrusive_ptr create(c10::ArrayRef elements_) { + return create(TupleElements(elements_)); + } + + static c10::intrusive_ptr create(IValue e1) { + return c10::make_intrusive(std::move(e1)); + } + + static c10::intrusive_ptr create(IValue e1, IValue e2) { + return c10::make_intrusive(std::move(e1), std::move(e2)); + } + + static c10::intrusive_ptr create(IValue e1, IValue e2, IValue e3) { + return c10::make_intrusive(std::move(e1), std::move(e2), std::move(e3)); + } + + private: + // Workaround inability to use `>` operator in template argument list. + template + static constexpr bool hasMoreThanThreeArgs() { + return sizeof...(Args) > 3; + } + + public: + template + static c10::intrusive_ptr create(Args&&... elements_) { + switch (sizeof...(Args)) { + case 1: + case 2: + case 3: + return create(IValue(std::forward(elements_))...); + default: + return create( + std::vector{IValue(std::forward(elements_))...}); + } + } + + // Again, it would be nice to make this noncopyable, but there's a + // lot of extant code that copies Tuples. + // Tuple(const Tuple& rhs) = delete; + + const TupleElements& elements() const& { + return elements_; + } + + TupleElements elements() && { + return std::move(elements_); + } + + void setElements(std::vector&& elements) { + elements_.setContents(std::move(elements)); + } + + void setElements(TupleElements&& elements) { + elements_ = std::move(elements); + } + + void unsafeSetElement(size_t idx, const IValue& element) { + elements_[idx] = element; + } + + void unsafeSetElement(size_t idx, IValue&& element) { + elements_[idx] = std::move(element); + } + + size_t size() const { + return elements_.size(); + } + + template + std::shared_ptr type() const { + if (!type_) { + type_ = TupleTypeFactory::create(fmap(elements(), [&](const IValue& v) { + return v.type(); + })); + } + if (auto t = type_->cast()) { + return t; + } + return TupleTypeFactory::fallback(*type_); + } + + static size_t hash(const Tuple& t) { + return c10::get_hash(t.elements()); + } + + TORCH_API friend bool operator==( + const ivalue::Tuple& lhs, + const ivalue::Tuple& rhs); + + private: + // NOTE: If we try to avoid the overloads without + // `std::shared_ptr type` by defaulting it to nullptr, we + // end up having to call (part of) the shared_ptr destructor for + // `type` even though we should know statically it won't do + // anything. + explicit Tuple(std::vector elements) + : elements_(std::move(elements)){} + + explicit Tuple(std::vector elements, c10::TypePtr type) + : elements_(std::move(elements)), type_(std::move(type)) {} + + explicit Tuple(TupleElements&& elements) + : elements_(std::move(elements)) {} + + explicit Tuple(TupleElements&& elements, std::shared_ptr type) + : elements_(std::move(elements)), type_(std::move(type)) {} + + explicit Tuple(IValue&& e1) + : elements_(std::move(e1)) {} + + explicit Tuple(IValue&& e1, std::shared_ptr type) + : elements_(std::move(e1)), type_(std::move(type)) {} + + explicit Tuple(IValue&& e1, IValue&& e2) + : elements_(std::move(e1), std::move(e2)) {} + + explicit Tuple(IValue&& e1, IValue&& e2, std::shared_ptr type) + : elements_(std::move(e1), std::move(e2)), type_(std::move(type)) {} + + explicit Tuple(IValue&& e1, IValue&& e2, IValue&& e3) + : elements_(std::move(e1), std::move(e2), std::move(e3)) {} + + explicit Tuple(IValue&& e1, IValue&& e2, IValue&& e3, std::shared_ptr type) + : elements_(std::move(e1), std::move(e2), std::move(e3)), type_(std::move(type)) {} + + friend class c10::intrusive_ptr; +}; + +struct Object; +struct PyObjectHolder; +struct EnumHolder; +} // namespace ivalue + +// Future +struct C10_EXPORT ivalue::Future final : c10::intrusive_ptr_target { + private: + // Keep this private in order to force users to go through make_intrusive and + // thus prevent creating a Future that's not held by an intrusive_ptr. + explicit Future(TypePtr type, std::vector devices={}) + : type_(std::move(type)), + impl_(getTypeOfDevices(devices)), + devices_(sortAndDeduplicateDevices(impl_, std::move(devices))) {} + + friend c10::intrusive_ptr; + + struct FutureCallback { + std::function callback; + bool uses_future; // whether the Future& passed in is actually used + + template + FutureCallback(T callback, bool uses_future) + : callback(std::move(callback)), uses_future(uses_future) {} + }; + + public: + Future(const Future&) = delete; + Future(Future&&) = delete; + Future& operator=(const Future&) = delete; + Future& operator=(Future&&) = delete; + + // Destructor + // Explicitly destroy events under device guard, otherwise it can lead to + // extra context being created on device 0. Reason: python garbage collector + // calls this destructor, but python GC does not have a device context, so a + // "default" one (usually on device 0) could be created when we go down the + // line of event destroy. + ~Future() override { + while (!events_.empty()) { + c10::OptionalDeviceGuard deviceGuard(events_.back().device()); + events_.pop_back(); + } + } + + struct TORCH_API FutureError final : public std::exception { + explicit FutureError(std::string&& error_msg_) + : error_msg(std::move(error_msg_)) {} + + FutureError() = default; + + const char* what() const noexcept override { + return error_msg.c_str(); + } + + std::string error_msg; + }; + + /** + * Wait on the future until it completes. + */ + void wait() { + std::unique_lock lock(mutex_); + finished_cv_.wait(lock, [&]() -> bool { return completed_; }); + synchronizeWithCurrentStreams(); + } + + /** + * Wait on the future until it completes and throw an + * exception if an error exists. + */ + void waitAndThrow() { + wait(); + + if (eptr_) { + std::rethrow_exception(eptr_); + } + } + + /** + * Explicitly mark the future as completed with the output value. Optionally, + * the storages for all tensors in IValue can be passed as well. The DataPtrs + * of these storages are used to synchronize CUDA streams. If storages isn't + * given we will attempt to extract it from the value, if we need to (this + * happens if a non-empty set of devices was given to the constructor). Thus + * one only needs to provide storages when 1) they cannot be extracted through + * IValue::getSubValues() or through pickling in case of Python object; or + * when 2) customized storage extraction is more efficient. + */ + using WeakStorage = c10::weak_intrusive_ptr; + void markCompleted( + IValue value, + std::optional> storages = std::nullopt) { + // Start by performing all steps that can throw, before setting any field. + // Do this before even acquiring the mutex, because extractStorages might + // acquire the GIL, which could lead to a lock inversion with our mutex. + // See https://github.com/pytorch/pytorch/issues/58239. + std::vector actualStorages; + std::vector usedDevices; + try { + // FIXME We should always extract DataPtrs, in order to catch the case of + // users using CUDA values but forgetting to set devices, which currently + // leads to a silent synchronization/correctness issue. However, as this + // might worsen perf in CPU-only cases, we should only do so after careful + // benchmarks. + if (impl_.type() != c10::kCPU) { + actualStorages = + storages.has_value() ? std::move(*storages) : extractStorages(value); + usedDevices = getDevicesOfStorages(impl_, actualStorages); + ensureIsSubsetOfDevices(usedDevices, devices_); + } + } catch (const std::exception&) { + setError(std::current_exception()); + return; + } + + std::unique_lock lock(mutex_); + TORCH_CHECK( + !completed(), + "Attempting to mark a completed Future as complete again. Note that " + "a Future can only be marked completed once."); + + // Only set value_ and completed_ flag once all checks and preparation steps + // have returned successfully to allow for proper error propagation. + value_ = std::move(value); + completed_ = true; + + currentDevice_ = impl_.getDevice(); + storages_ = std::move(actualStorages); + for (const c10::Device& device : usedDevices) { + c10::Event event(impl_.type()); + event.record(impl_.getStream(device)); + events_.push_back(std::move(event)); + } + + std::vector cbs; + cbs.swap(callbacks_); + lock.unlock(); + + finished_cv_.notify_all(); + for (const auto& callback : cbs) { + invokeCallback(callback.callback, callback.uses_future); + } + } + + void markCompleted() { + markCompleted(IValue{}); + } + + void setError(std::exception_ptr eptr) { + std::unique_lock lock(mutex_); + setErrorInternal(std::move(eptr), lock); + } + + void setErrorIfNeeded(std::exception_ptr eptr) { + std::unique_lock lock(mutex_); + if (completed_) { + // This should be rare and shouldn't cause log spew. Its important to + // log errors and thats why we have this log here. + std::string msg = c10::str( + "Skipping setting following error on the Future since " + "it is already marked completed (this is not necessarily " + "an error):\n", + tryRetrieveErrorMessageInternal(std::move(eptr))); + if (eptr_) { + msg += c10::str( + ", \nOriginal exception:\n", + tryRetrieveErrorMessageInternal(eptr_)); + } + LOG(INFO) << msg; + return; + } else { + setErrorInternal(std::move(eptr), lock); + } + } + + // Get the result of the current future. + IValue value() { + std::unique_lock lock(mutex_); + AT_ASSERT(completed()); + if (eptr_) { + std::rethrow_exception(eptr_); + } + return value_; + } + + // This accessor should only be used if we know that the future is + // completed() with no error. + const IValue& constValue() const { + std::unique_lock lock(mutex_); + AT_ASSERT(completed()); + TORCH_INTERNAL_ASSERT( + !eptr_, + "value() accessor should only be used when future is not completed with ", + "an error, but future had the following error: ", + tryRetrieveErrorMessageInternal(eptr_) + ); + return value_; + } + + // This accessor should only be used if we know that the future is + // completed() with no error. + const std::vector& storages() const { + std::unique_lock lock(mutex_); + AT_ASSERT(completed()); + AT_ASSERT(!eptr_); + return storages_; + } + + /** + * Add a callback to the future. + * The callbacks will be executed once the future completes. + * If the future has already completed, + * this function will execute the callback immediately. + */ + template + void addCallback(T callback, bool uses_future = true) { + static_assert( + std::is_invocable_r_v, + "The callback must have signature void(Future&)"); + + std::unique_lock lock(mutex_); + if (completed()) { + lock.unlock(); + invokeCallback(callback, uses_future); + return; + } + callbacks_.emplace_back(std::move(callback), uses_future); + } + + /** + * Add a callback to the future, and return another Future to hold the return + * value of the callback. This is necessary when the callback provider needs + * to know for sure when the callback has finished. + */ + template + c10::intrusive_ptr then(T callback, TypePtr type) { + using IValueWithStorages = std::tuple>; + static_assert( + std::disjunction_v< + std::is_invocable_r, + std::is_invocable_r>, + "The callback must have signature IValue(Future&) or " + "std::tuple>(Future&)"); + + auto childFut = createInstance(::std::move(type)); + addCallback([childFut, + cb = std::move(callback)](Future& parentFut) { + try { + if constexpr (::std::is_convertible_v, IValueWithStorages>) { + auto [ivalue, storages] = cb(parentFut); + childFut->markCompleted(::std::move(ivalue), ::std::move(storages)); + } else { + childFut->markCompleted(cb(parentFut)); + } + } catch (std::exception&) { + childFut->setError(std::current_exception()); + } + }); + return childFut; + } + + template + c10::intrusive_ptr thenAsync(T callback, TypePtr type) { + static_assert( + std::is_invocable_r_v, T, Future&>, + "The callback must have signature c10::intrusive_ptr(Future&)"); + + auto childFut = createInstance(std::move(type)); + addCallback( + [childFut, cb = std::move(callback)](Future& parentFut) mutable { + c10::intrusive_ptr intermediateFut; + try { + intermediateFut = cb(parentFut); + } catch (std::exception&) { + childFut->setError(std::current_exception()); + return; + } + intermediateFut->addCallback( + [childFut = std::move(childFut)](Future& intermediateFut) { + if (intermediateFut.hasError()) { + childFut->setError(intermediateFut.exception_ptr()); + } else { + childFut->markCompleted( + intermediateFut.value(), intermediateFut.storages()); + } + }); + }); + return childFut; + } + + // Tries to retrieve the error message from std::exception_ptr. + std::string tryRetrieveErrorMessage() const { + TORCH_CHECK(hasError(), "No error present on the future."); + std::unique_lock lock(mutex_); + return tryRetrieveErrorMessageInternal(eptr_); + } + + // Check if the current future has completed + bool completed() const { + return completed_; + } + + bool hasValue() const { + std::unique_lock lock(mutex_); + return completed_ && !eptr_; + } + + bool hasError() const { + std::unique_lock lock(mutex_); + return eptr_ ? true : false; + } + + std::exception_ptr exception_ptr() const { + std::unique_lock lock(mutex_); + return eptr_; + } + + TORCH_API friend std::ostream& operator<<( + std::ostream& out, + const Future& v); + + const TypePtr& elementType() const { + return type_; + } + + const std::vector& devices() const { + return devices_; + } + + // This method should be used when one intends to manually create a child + // future, for example when implementing a customized version of then(). + c10::intrusive_ptr createInstance(at::TypePtr type) { + return c10::make_intrusive(std::move(type), devices_); + } + + private: + + // This method should always be used when invoking a callback (regardless of + // how/when that happens) as it will ensure that the proper "environment" is + // set up before running the callback, as in, it will set up the CUDA streams, + // synchronize them with the value, and so on (if needed). + template + void invokeCallback(T& callback, bool uses_future) { + static_assert( + std::is_invocable_r_v, + "The callback must have signature void(Future&)"); + + // The synchronization performed below shouldn't be needed when the future + // is not used by the callback. + if (uses_future) { + c10::OptionalDeviceGuard deviceGuard(currentDevice_); + + std::vector streams; + streams.reserve(devices_.size()); + for (const c10::Device& device : devices_) { + streams.push_back(impl_.getStreamFromGlobalPool(device)); + } + c10::MultiStreamGuard streamGuard(streams); + synchronizeWithCurrentStreams(); + callback(*this); + } else { + callback(*this); + } + } + + // This method should be called before this future's value is used, as it + // ensures that the CUDA streams that are "current" at the callsite properly + // synchronize with the value. + void synchronizeWithCurrentStreams() { + for (c10::Event& event : events_) { + event.block(impl_.getStream(event.device())); + } + + for (const WeakStorage& weak_storage : storages_) { + c10::intrusive_ptr storage = weak_storage.lock(); + if (!storage) { + continue; + } + if (!storage->device().is_cpu()) { + impl_.recordDataPtrOnStream( + storage->data_ptr(), impl_.getStream(storage->device())); + } + } + } + + void setErrorInternal( + std::exception_ptr eptr, + std::unique_lock& lock) { + TORCH_CHECK( + !eptr_, + "Error already set on this Future: ", + tryRetrieveErrorMessageInternal(eptr_), + ", trying to set error: ", + tryRetrieveErrorMessageInternal(eptr)); + TORCH_INTERNAL_ASSERT(!completed(), "Future is already marked completed"); + completed_ = true; + eptr_ = std::move(eptr); + + std::vector cbs; + cbs.swap(callbacks_); + lock.unlock(); + + finished_cv_.notify_all(); + for (const auto& callback : cbs) { + invokeCallback(callback.callback, callback.uses_future); + } + } + + // Tries to retrieve the error message from std::exception_ptr. + std::string tryRetrieveErrorMessageInternal(std::exception_ptr eptr) const { + try { + std::rethrow_exception(std::move(eptr)); + } catch (const std::exception& e) { + return e.what(); + } catch (...) { + return "Unknown Exception Type"; + } + } + + // Defined in ivalue.cpp. + static std::vector extractStorages( + const at::IValue& value); + + static std::vector getDevicesOfStorages( + const c10::impl::VirtualGuardImpl& impl, + const std::vector& storages) { + c10::DeviceIndex deviceCount = impl.deviceCount(); + std::vector isDeviceUsed(deviceCount, false); + for (const WeakStorage& weak_storage : storages) { + c10::intrusive_ptr storage = weak_storage.lock(); + if (!storage) { + continue; + } + c10::Device device = storage->device(); + if (!device.is_cpu()) { + TORCH_CHECK_VALUE( + device.type() == impl.type(), + "Expected all data ptrs to be on a device of type ", + impl.type(), + ", got one on device ", + device); + isDeviceUsed[device.index()] = true; + } + } + std::vector devices; + for (c10::DeviceIndex idx = 0; idx < deviceCount; idx++) { + if (isDeviceUsed[idx]) { + devices.emplace_back(impl.type(), idx); + } + } + return devices; + } + + static std::string formatSetOfDevices( + const std::vector& devices) { + if (devices.empty()) { + return "(none)"; + } + std::ostringstream oss; + oss << devices[0]; + for (const auto idx : c10::irange(1, devices.size())) { + if (idx == devices.size() - 1) { + oss << " and "; + } else { + oss << ", "; + } + oss << devices[idx]; + } + return oss.str(); + } + + static c10::DeviceType getTypeOfDevices( + const std::vector& devices) { + if (devices.empty()) { + return c10::kCPU; + } + c10::DeviceType deviceType = devices[0].type(); + for (const auto idx : c10::irange(1, devices.size())) { + TORCH_CHECK_VALUE( + devices[idx].type() == deviceType, + "Expected all devices to be of the same type, but got a mismatch between ", + devices[0], + " and ", + devices[idx]); + } + return deviceType; + } + + // We need devices to be sorted in order to use ensureIsSubsetOfDevices. + static std::vector sortAndDeduplicateDevices( + const c10::impl::VirtualGuardImpl& /*impl*/, + std::vector devices) { + std::sort( + devices.begin(), devices.end(), + [](const c10::Device& a, const c10::Device& b) { return a.index() < b.index(); }); + // Deduplicate by compacting. + size_t targetIdx = 0; + for (const auto sourceIdx : c10::irange(devices.size())) { + TORCH_CHECK_VALUE( + devices[sourceIdx].has_index(), + "Expected devices to have indices, got ", devices[sourceIdx]); + if (targetIdx > 0 && devices[targetIdx - 1].index() == devices[sourceIdx].index()) { + // It's a duplicate, skip it. + continue; + } + if (sourceIdx != targetIdx) { + devices[targetIdx] = devices[sourceIdx]; + } + targetIdx++; + } + // If there were duplicates there's now a gap at the end: trim it. Resizing + // requires the item type to be default-constructible (which c10::Device is + // not) because in principle it could be required to create new items. Since + // we know we'll shrink the vector, we provide a custom dummy value instead. + devices.resize(targetIdx, c10::Device(c10::kCPU)); + return devices; + } + + static void ensureIsSubsetOfDevices( + const std::vector& subset, + const std::vector& superset) { + // We assume the devices in both vectors have the same consistent type, and + // their indices are unique and sorted. + std::vector excessDevices; + std::set_difference( + subset.begin(), + subset.end(), + superset.begin(), + superset.end(), + std::back_inserter(excessDevices), + [](const c10::Device& a, const c10::Device& b) { return a.index() < b.index(); }); + TORCH_CHECK_VALUE( + excessDevices.empty(), + "The result contained tensors residing on device(s) ", + formatSetOfDevices(excessDevices), + " which are not among the expected device(s) ", + formatSetOfDevices(superset)); + } + + mutable std::mutex mutex_; + std::atomic_bool completed_ = {false}; // is this future complete + std::condition_variable finished_cv_; + + IValue value_; // when finished the value + TypePtr type_; + std::vector callbacks_; + std::exception_ptr eptr_; + + // An upcast pointer to a virtual class which allows us to manipulate events, + // streams, ... in a generic way, without an explicit dependency on CUDA. + // NOLINTNEXTLINE(cppcoreguidelines-avoid-const-or-ref-data-members) + const c10::impl::VirtualGuardImpl impl_; + + // The device that was current when markCompleted was called, which we'll + // restore when invoking callbacks. It's optional because we'll only store it + // if the future completes successfully. + std::optional currentDevice_; + + // The events that correspond to the completion of the async I/O kernels. They + // are recorded on the appropriate streams when the future is marked completed + // and can then be queried/waited/blocked on. There is one event for each + // distinct device on which the value's tensors reside. + std::vector events_; + + // A cached version of the storages extracted from the value when the future + // is first marked completed. + std::vector storages_; + + // The bounding set of devices that this future, and any of its children, is + // allowed to use. This is a superset of the set of devices used by the events + // above. We need this to know what streams (for which devices) to set as + // current when invoking a callback, thus allowing the callback to use devices + // that the parent future didn't use. This field is set to the value provided + // in the constructor and will be "inherited" by all child futures. + // NOLINTNEXTLINE(cppcoreguidelines-avoid-const-or-ref-data-members) + const std::vector devices_; +}; + +struct C10_EXPORT ivalue::Await final : c10::intrusive_ptr_target { + private: + explicit Await(TypePtr elType, std::function fn) + : elType_(std::move(elType)), type_(AwaitType::create(elType_)), fn_(std::move(fn)) {} + + explicit Await(TypePtr elType) : elType_(std::move(elType)), type_(AwaitType::create(elType_)) { } + + friend c10::intrusive_ptr; + + public: + Await(const Await&) = delete; + Await(Await&&) = delete; + Await& operator=(const Await&) = delete; + Await& operator=(Await&&) = delete; + ~Await() override = default; + + IValue wait() { + if (!completed_) { + TORCH_CHECK(fn_, "Incompleted Await: fn can't be None"); + value_ = fn_(); + completed_ = true; + args_ = {}; + } + return value_; + } + + IValue value() { + TORCH_CHECK(completed_, "Await must be completed"); + return value_; + } + + void setFn(std::function fn) { + fn_ = std::move(fn); + } + + bool completed() { + return completed_; + } + + void markCompleted(IValue value) { + value_ = std::move(value); + completed_ = true; + } + + TORCH_API friend std::ostream& operator<<( + std::ostream& out, + const Await& v); + + const TypePtr& elementType() const { + return elType_; + } + + const TypePtr& type() const { + return type_; + } + + void setArgs(std::vector args) { + args_ = std::move(args); + } + + std::vector& args() { + return args_; + } + + private: + TypePtr elType_; + TypePtr type_; + std::vector args_; + std::function fn_; + IValue value_; + bool completed_{}; +}; + +// Input is a list of Futures with the same target type. +// Output is a Future to the List of completed Futures. +TORCH_API intrusive_ptr collectAll( + const c10::List>& srcs); +// Input is a List of Futures with the same target type. +// Output is a Future that will be updated with a seen value. +TORCH_API intrusive_ptr collectAny( + const c10::List>& srcs); + +// User-defined object. +struct C10_EXPORT ivalue::Object final : c10::intrusive_ptr_target { + public: + // In general, class types hold a shared_ptr to its owning CompilationUnit, + // so that its type and methods do not get deallocated while the class exists. + // However, the CompilationUnit holds ownership of the type's graphs, so + // inserting a constant object into a Graph would create a reference cycle if + // that constant object held a shared_ptr to its CU. For these objects we + // instatiate them with non-owning references to its CU + Object(WeakOrStrongTypePtr type, size_t numSlots) : type_(std::move(type)) { + slots_.resize(numSlots); + } + + Object(StrongTypePtr type, size_t numSlots) + : type_(WeakOrStrongTypePtr(std::move(type))) { + slots_.resize(numSlots); + } + + static c10::intrusive_ptr create( + WeakOrStrongTypePtr type, + size_t numSlots) { + return c10::make_intrusive(std::move(type), numSlots); + } + + static c10::intrusive_ptr create( + StrongTypePtr type, + size_t numSlots) { + return c10::make_intrusive(std::move(type), numSlots); + } + + static c10::intrusive_ptr create(ClassTypePtr classType, size_t numSlots); + + /** + * Slot API. + * + * Attributes are stored as a simple vector so that lookups are fast at + * runtime. A "slot" is just an index into that vector, which can be computed + * statically if you have access to the class type. Use this API if you are + * writing compiler stuff. + */ + void setSlot(size_t slot, IValue v) { + if (slot >= slots_.size()) { + // for module types, it is possible that the members of the class have + // expanded after the object was created. In this case, we expand + // the slots to the right size + resizeObject(slot); + } + slots_[slot] = std::move(v); + } + + const IValue& getSlot(size_t slot) const { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(slot < slots_.size()); + // NOTE: This lookup is fairly hot, so we use unchecked access to the + // vector. Errors should still be detectable with ASan. + return slots_[slot]; + } + + void unsafeRemoveSlot(size_t slot) { + TORCH_CHECK(slot < slots_.size()); + slots_.erase(slots_.begin() + static_cast(slot)); + } + + /** + * Attribute API. + * + * Wrappers around the slot stuff so that users can access attributes + * directly. Use this API if you are a user. + * + * Note: Unlike in Python, TorchScript must make a distinction between + * attributes (which are IValues) and methods (which are Methods). If you + * want a method, use `obj.type()->getMethod()` + */ + IValue getAttr(const std::string& name) const; + void setAttr(const std::string& name, IValue v); + // Remove attribute by name, caller is responsible for + // the safety of this operation + // We didn't remove the attribute in the type because the type + // might be shared by multiple objects. + // Therefore after removing attribute, the object is in an inconsistent + // state where it has more attribute types in its Type than + // the attribute slots it has, user needs to make sure the object + // has consistent by removing the attribute in type as well + void unsafeRemoveAttr(const std::string& name); + + std::string name() const; + + const std::vector& slots() const { + return slots_; + } + std::shared_ptr type() const; + + std::shared_ptr compilation_unit() { + if (type_.holds_strong_ref()) { + return type_.cu_.getStrongRefOrThrow(); + } else { + auto weak_ptr = type_.cu_.getWeakRefOrThrow(); + return std::shared_ptr(weak_ptr); + } + } + + c10::intrusive_ptr copy_to_weak_compilation_ref() const; + + void unsafe_make_weak_compilation_ref() { + type_ = WeakOrStrongTypePtr(type_.asWeakTypePtr()); + } + + c10::intrusive_ptr copy() const; + + c10::intrusive_ptr deepcopy( + std::optional device = std::nullopt) const; + + c10::intrusive_ptr deepcopy( + IValue::HashIdentityIValueMap& memo, + std::optional device = std::nullopt) const; + + bool is_weak_compilation_ref() const { + return !type_.holds_strong_ref(); + } + + bool is_empty_strong_compilation_ref() const { + return type_.holds_empty_strong_ref(); + } + + private: + void resizeObject(size_t slot); + WeakOrStrongTypePtr type_; + std::vector slots_; +}; + +// virtual ivalue PyObjectHolder that hold a py::object, we make this virtual +// because the py::object and refcounting logic should happen in libtorch_python +// see concrete implementation in python_ivalue.h +struct ivalue::PyObjectHolder : c10::intrusive_ptr_target { + public: + virtual PyObject* getPyObject() = 0; + virtual c10::InferredType tryToInferType() = 0; + virtual IValue toIValue(const TypePtr& type, std::optional N = std::nullopt) = 0; + virtual std::string toStr() = 0; + virtual std::vector extractTensors() = 0; + + ~PyObjectHolder() override = default; +}; + +struct ivalue::EnumHolder : c10::intrusive_ptr_target { + public: + EnumHolder(std::shared_ptr type, std::string name, IValue value) + : type_(std::move(type)), + name_(std::move(name)), + value_(std::move(value)) {} + + bool is(const ivalue::EnumHolder& rhs) { + return *this == rhs; + } + + friend bool operator==( + const ivalue::EnumHolder& lhs, + const ivalue::EnumHolder& rhs); + + TORCH_API friend std::ostream& operator<<( + std::ostream& out, + const ivalue::EnumHolder& v); + + TORCH_API const std::string& qualifiedClassName() const; + + const std::string& unqualifiedClassName() const; + + const std::string& name() const { + return name_; + } + + const IValue& value() const { + return value_; + } + + std::shared_ptr type() const { + return type_; + } + + private: + std::shared_ptr type_; + std::string name_; + IValue value_; +}; + +#undef TORCH_FORALL_TAGS + +namespace detail { + +struct _guarded_unsigned_long_unique_dummy final { + _guarded_unsigned_long_unique_dummy(int64_t){} +}; +using _guarded_unsigned_long = std::conditional_t< + std::is_same_v || + std::is_same_v, + _guarded_unsigned_long_unique_dummy, + unsigned long>; + +} // namespace detail + +inline ivalue::Object& IValue::toObjectRef() const { + AT_ASSERT(isObject(), "Expected Object but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), "Attempted to create null reference"); + return *static_cast(payload.u.as_intrusive_ptr); +} + +// note: when adding a DEFINE_TO case here you should also add a +// toX method to IValue. These named methods are much more discoverable +// than the to templated function. + +#define DEFINE_TO(T, method_name) \ + template <> \ + inline T IValue::to()&& { \ + return static_cast(std::move(*this).method_name()); \ + } \ + template <> \ + inline c10::detail::ivalue_to_const_ref_overload_return::type IValue::to() const& { \ + typedef c10::detail::ivalue_to_const_ref_overload_return::type return_type; \ + return static_cast(this->method_name()); \ + } + +DEFINE_TO(at::Tensor, toTensor) +DEFINE_TO(at::Storage, toStorage) +DEFINE_TO(c10::Stream, toStream) +DEFINE_TO(float, toDouble) +DEFINE_TO(double, toDouble) +DEFINE_TO(c10::complex, toComplexDouble) +DEFINE_TO(unsigned char, toInt) +DEFINE_TO(signed char, toInt) +DEFINE_TO(unsigned short, toInt) +DEFINE_TO(short, toInt) +DEFINE_TO(int, toInt) +DEFINE_TO(uint32_t, toInt) +DEFINE_TO(uint64_t, toInt) +DEFINE_TO(detail::_guarded_unsigned_long, toInt) +DEFINE_TO(int64_t, toInt) +DEFINE_TO(bool, toBool) +DEFINE_TO(c10::intrusive_ptr, toBlob) +DEFINE_TO(c10::intrusive_ptr, toString) +DEFINE_TO(c10::intrusive_ptr, toObject) +DEFINE_TO(at::Scalar, toScalar) +DEFINE_TO(c10::List, toIntList) +DEFINE_TO(c10::List, toSymIntList) +DEFINE_TO(c10::List, toDoubleList) +DEFINE_TO(c10::List>, toComplexDoubleList) +DEFINE_TO(c10::List, toBoolList) +DEFINE_TO(c10::List, toTensorList) +DEFINE_TO(c10::impl::GenericList, toList) +DEFINE_TO(c10::impl::GenericDict, toGenericDict) +DEFINE_TO(c10::intrusive_ptr, toTuple) +DEFINE_TO(std::string, toStringRef) +DEFINE_TO(std::string_view, toStringView) +DEFINE_TO(c10::intrusive_ptr, toFuture) +DEFINE_TO(c10::intrusive_ptr, toAwait) +DEFINE_TO(c10::intrusive_ptr, toRRef) +DEFINE_TO(c10::intrusive_ptr, toQuantizer) +DEFINE_TO(IValue, toIValue) +DEFINE_TO(c10::Device, toDevice) +DEFINE_TO(at::ScalarType, toScalarType) +DEFINE_TO(at::Layout, toLayout) +DEFINE_TO(at::MemoryFormat, toMemoryFormat) +DEFINE_TO(at::QScheme, toQScheme) +DEFINE_TO(at::Dimname, toDimname) +DEFINE_TO(at::Generator, toGenerator) +DEFINE_TO(c10::SymInt, toSymInt) +DEFINE_TO(c10::SymFloat, toSymFloat) +DEFINE_TO(c10::SymBool, toSymBool) + +template +struct _fake_type {}; + +// generic_to converts an IValue from a generic list or generic dict +// to a concrete list/dict type likelike List, Dict<...> or std::optional. +// Note that in the case of lists, this only works for IValue-based lists, +// i.e. not for int64_t, double, ... +// generic_to is an implementation detail of IValue::to and not +// supposed to be called directly. +// The _fake_type parameter allows us to overload +// based on the return type. +template +// TODO this is deprecated but we don't throw a warning because a lot of ops in +// native_functions.yaml still return std::vector. +// C10_DEPRECATED_MESSAGE("IValues based on std::vector are potentially slow +// and deprecated. Please use torch::List instead.") +std::vector generic_to(IValue ivalue, _fake_type>) { + // We need to do a deep copy of the vector because there might be other + // references to this same IValue that also use the list. We can't just + // move the elements out. + auto list = std::move(ivalue).template to>(); + std::vector result; + result.reserve(list.size()); + for (Elem v : list) { + result.push_back(std::move(v)); + } + return result; +} + +template +c10::intrusive_ptr IValue::toCustomClass() && { + static_assert( + std::is_base_of_v == true, + "toCustomClass requires that template parameter T must inherit " + "from torch::CustomClassHolder"); + auto obj = toObject(); + TORCH_CHECK( + obj->slots().size() == 1, + "Tried to cast IValue to custom class but it did " + "not contain a custom class!"); + const auto* expected_type = c10::getCustomClassType>().get(); + ivalue::checkCustomClassType(expected_type, type().get()); + auto userObj = + c10::static_intrusive_pointer_cast(obj->getSlot(0).toCapsule()); + return userObj; +} + +template +c10::intrusive_ptr IValue::toCustomClass() const& { + static_assert( + std::is_base_of_v == true, + "toCustomClass requires that template parameter T must inherit " + "from torch::CustomClassHolder"); + auto obj = toObject(); + TORCH_CHECK( + obj->slots().size() == 1, + "Tried to cast IValue to custom class but it did " + "not contain a custom class!"); + const auto* expected_type = c10::getCustomClassType>().get(); + ivalue::checkCustomClassType(expected_type, type().get()); + auto userObj = + c10::static_intrusive_pointer_cast(obj->getSlot(0).toCapsule()); + return userObj; +} + +template +T generic_to(IValue ivalue, _fake_type) { + using ElemType = typename std::remove_pointer::type::element_type; + return std::move(ivalue).template toCustomClass(); +} + +template +tagged_capsule generic_to(IValue ivalue, _fake_type>) { + return tagged_capsule{std::move(ivalue)}; +} + +template +c10::List generic_to(IValue ivalue, _fake_type>) { + return impl::toTypedList(std::move(ivalue).toList()); +} + +template +static T createVectorLikeFromList(const c10::detail::ListImpl* impl) { + T result; + result.reserve(impl->list.size()); + for (const auto & i : impl->list) { + result.push_back(i.to()); + } + return result; +} + +template +static std::vector createVectorFromList(const c10::detail::ListImpl* impl) { + return createVectorLikeFromList>(impl); +} + +template +std::vector createVectorFromList(const c10::List& impl) { + std::vector result; + result.reserve(impl.size()); + for (size_t i = 0, N = impl.size(); i < N; ++i) { + result.push_back(impl[i]); + } + return result; +} + +template +OptionalArray generic_to(IValue ivalue, _fake_type>) { + if (ivalue.isNone()) { + return {}; + } + return createVectorFromList( + std::move(ivalue).template to>() + ); +} + +namespace detail { +template +std::array generic_to_array( + IValue ivalue, + _fake_type>, + std::index_sequence) { + // We need to do a deep copy of the array because there might be other + // references to this same IValue that also use the list. We can't just + // move the elements out. + auto list = std::move(ivalue).template to>(); + TORCH_CHECK( + list.size() == sizeof...(I), + "Tried to convert a List with ", + list.size(), + " elements to a fixed-size array of size ", + sizeof...(I)); + return {list[I]...}; +} +} // namespace detail + +template +std::array generic_to( + IValue ivalue, + _fake_type> ft) { + return detail::generic_to_array(ivalue, ft, std::make_index_sequence()); +} + +template +c10::Dict generic_to( + IValue ivalue, + _fake_type>) { + return impl::toTypedDict(std::move(ivalue).toGenericDict()); +} + +template +C10_DEPRECATED_MESSAGE( + "IValues based on std::unordered_map are slow and deprecated. Please use c10::Dict instead.") +std::unordered_map generic_to( + IValue ivalue, + _fake_type>) { + std::unordered_map specialized_dict; + + for (const auto& item : std::move(ivalue).toGenericDict()) { + specialized_dict[item.key().template to()] = item.value().template to(); + } + + return specialized_dict; +} + +template +std::optional generic_to(IValue ivalue, _fake_type>) { + if (ivalue.isNone()) { + return std::nullopt; + } + return std::move(ivalue).template to(); +} + +namespace detail { +template +Tuple generic_to_tuple_impl( + const ivalue::TupleElements& t, + std::index_sequence) { + return std::make_tuple( + t[INDEX].to::type>()...); +} +} // namespace detail + +template < + typename... Args, + typename Indices = std::make_index_sequence, + std::enable_if_t< + !std::disjunction_v< + std::is_lvalue_reference..., + std::negation>...>, + std::nullptr_t> = nullptr> +std::tuple generic_to(const IValue& ivalue, _fake_type>) { + const auto& vals = ivalue.toTupleRef().elements(); + TORCH_CHECK(vals.size() == sizeof...(Args)); + return detail::generic_to_tuple_impl>(vals, Indices{}); +} + +template +inline T IValue::to() && { + return generic_to(std::move(*this), _fake_type{}); +} + +template <> +inline std::optional IValue::to() && { + // In the default implementation, the IValue is destroyed with std::move. + // But if the unboxed type is std::optional we cannot destroy + // the IValue. + return generic_to(*this, _fake_type>{}); +} + +template +inline typename c10::detail::ivalue_to_const_ref_overload_return::type IValue::to() const& { + return generic_to(*this, _fake_type{}); +} + +inline c10::List IValue::toIntList() && { + AT_ASSERT(isIntList(), "Expected IntList but got ", tagKind()); + return c10::List(moveToIntrusivePtr()); +} +inline c10::List IValue::toIntList() const& { + AT_ASSERT(isIntList(), "Expected IntList but got ", tagKind()); + return c10::List(toIntrusivePtr()); +} +inline std::vector IValue::toIntVector() const { + AT_ASSERT(isIntList(), "Expected IntList but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toIntVector on null intrusive_ptr IValue"); + return createVectorFromList( + static_cast(payload.u.as_intrusive_ptr)); +} +inline c10::List IValue::toSymIntList() && { + AT_ASSERT( + isSymIntList() || isIntList(), + "Expected SymIntList or IntList but got ", + tagKind()); + return c10::List(moveToIntrusivePtr()); +} +inline c10::List IValue::toSymIntList() const& { + AT_ASSERT( + isSymIntList() || isIntList(), + "Expected SymIntList or IntList but got ", + tagKind()); + return c10::List(toIntrusivePtr()); +} +inline std::vector IValue::toSymIntVector() const { + AT_ASSERT(isSymIntList() || isIntList(), "Expected SymIntList or IntList but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toSymIntVector on null intrusive_ptr IValue"); + return createVectorFromList( + static_cast(payload.u.as_intrusive_ptr)); +} +inline at::DimVector IValue::toDimVector() const { + AT_ASSERT(isIntList(), "Expected IntList but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toDimVector on null intrusive_ptr IValue"); + return createVectorLikeFromList( + static_cast(payload.u.as_intrusive_ptr)); +} +inline c10::List IValue::toDoubleList() && { + AT_ASSERT(isDoubleList(), "Expected DoubleList but got ", tagKind()); + return c10::List(moveToIntrusivePtr()); +} +inline c10::List IValue::toDoubleList() const& { + AT_ASSERT(isDoubleList(), "Expected DoubleList but got ", tagKind()); + return c10::List(toIntrusivePtr()); +} +inline std::vector IValue::toDoubleVector() const { + AT_ASSERT(isDoubleList(), "Expected DoubleList but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toDoubleVector on null intrusive_ptr IValue"); + return createVectorFromList( + static_cast(payload.u.as_intrusive_ptr)); +} +inline c10::List> IValue::toComplexDoubleList() && { + AT_ASSERT(isComplexDoubleList(), "Expected ComplexDoubleList but got ", tagKind()); + return c10::List>(moveToIntrusivePtr()); +} +inline c10::List> IValue::toComplexDoubleList() const& { + AT_ASSERT(isComplexDoubleList(), "Expected ComplexDoubleList but got ", tagKind()); + return c10::List>(toIntrusivePtr()); +} +inline std::vector> IValue::toComplexDoubleVector() const { + AT_ASSERT(isComplexDoubleList(), "Expected ComplexDoubleList but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toComplexDoubleVector on null intrusive_ptr IValue"); + return createVectorFromList>( + static_cast(payload.u.as_intrusive_ptr)); +} +inline c10::List IValue::toBoolList() && { + AT_ASSERT(isBoolList(), "Expected BoolList but got ", tagKind()); + return c10::List(moveToIntrusivePtr()); +} +inline c10::List IValue::toBoolList() const& { + AT_ASSERT(isBoolList(), "Expected BoolList but got ", tagKind()); + return c10::List(toIntrusivePtr()); +} +inline c10::List IValue::toTensorList() && { + AT_ASSERT(isTensorList(), "Expected TensorList but got ", tagKind()); + return c10::List(moveToIntrusivePtr()); +} +inline c10::List IValue::toTensorList() const& { + AT_ASSERT(isTensorList(), "Expected TensorList but got ", tagKind()); + return c10::List(toIntrusivePtr()); +} +inline std::vector IValue::toTensorVector() const { + AT_ASSERT(isTensorList(), "Expected TensorList but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toTensorVector on null intrusive_ptr IValue"); + return createVectorFromList( + static_cast(payload.u.as_intrusive_ptr)); +} +inline c10::List> IValue::toOptionalTensorList() && { + AT_ASSERT(isOptionalTensorList(), "Expected OptionalTensorList but got ", tagKind()); + return c10::List>(moveToIntrusivePtr()); +} +inline c10::List> IValue::toOptionalTensorList() const& { + AT_ASSERT(isOptionalTensorList(), "Expected OptionalTensorList but got ", tagKind()); + return c10::List>(toIntrusivePtr()); +} +inline std::vector> IValue::toOptionalTensorVector() const { + AT_ASSERT(isOptionalTensorList(), "Expected OptionalTensorList but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toOptionalTensorVector on null intrusive_ptr IValue"); + return createVectorFromList>( + static_cast(payload.u.as_intrusive_ptr)); +} +inline c10::List IValue::toList() && { + AT_ASSERT(isList(), "Expected GenericList but got ", tagKind()); + return c10::List(moveToIntrusivePtr()); +} +inline c10::List IValue::toList() const& { + AT_ASSERT(isList(), "Expected GenericList but got ", tagKind()); + return c10::List(toIntrusivePtr()); +} +inline c10::ArrayRef IValue::toListRef() const { + AT_ASSERT(isList(), "Expected GenericList but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toListRef on null intrusive_ptr IValue"); + return static_cast(payload.u.as_intrusive_ptr) + ->list; +} +inline c10::Dict IValue::toGenericDict() && { + AT_ASSERT(isGenericDict(), "Expected GenericDict but got ", tagKind()); + return c10::Dict(moveToIntrusivePtr()); +} +inline c10::Dict IValue::toGenericDict() const& { + AT_ASSERT(isGenericDict(), "Expected GenericDict but got ", tagKind()); + return c10::Dict(toIntrusivePtr()); +} +inline c10::intrusive_ptr IValue::toTuple() && { + AT_ASSERT(isTuple(), "Expected Tuple but got ", tagKind()); + return moveToIntrusivePtr(); +} +inline c10::intrusive_ptr IValue::toTuple() const& { + AT_ASSERT(isTuple(), "Expected Tuple but got ", tagKind()); + return toIntrusivePtr(); +} +inline ivalue::Tuple& IValue::toTupleRef() const { + AT_ASSERT(isTuple(), "Expected Tuple but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toTupleRef on null intrusive_ptr IValue"); + return *static_cast( + payload.u.as_intrusive_ptr); +} + +inline IValue::IValue(c10::intrusive_ptr v) + : tag(Tag::Tuple) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.release()); +} +template < + typename... Args, + std::enable_if_t< + !std::disjunction_v< + std::is_lvalue_reference..., + std::negation>...>, + std::nullptr_t>> +inline IValue::IValue(const std::tuple& t) + : IValue(std::apply(c10::ivalue::Tuple::create, t)) { +} + +template < + typename... Args, + std::enable_if_t< + !std::disjunction_v< + std::is_lvalue_reference..., + std::negation>...>, + std::nullptr_t>> +inline IValue::IValue(std::tuple&& t) + : IValue(std::apply(c10::ivalue::Tuple::create, std::move(t))) { +} + +inline IValue::IValue(c10::intrusive_ptr v) + : tag(Tag::String) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.release()); +} +inline IValue::IValue(std::string v) + : IValue(ivalue::ConstantString::create(std::move(v))) {} + +inline IValue::IValue(c10::impl::GenericList v) + : tag(Tag::GenericList) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.impl_.release()); +} + +template > +inline IValue::IValue(c10::List&& v) : IValue(impl::toList(std::move(v))) {} +template > +inline IValue::IValue(const c10::List& v) : IValue(impl::toList(v)) {} +template > +inline IValue::IValue(at::ArrayRef v) : IValue(c10::List()) { + auto list = to>(); + list.reserve(v.size()); + for (const auto& e : v) { + list.push_back(e); + } +} +template > +inline IValue::IValue(at::ArrayRef v) : IValue() { + auto vi = c10::asIntArrayRefSlowOpt(v); + if (vi.has_value()) { + // This list is entirely integers; ensure it is typed as + // an IntList so toIntList works + *this = IValue(*vi); + } else { + // This list has SymInts; type it as a SymInt + *this = IValue(impl::toList(c10::List())); + auto list = to>(); + list.reserve(v.size()); + for (const auto& e : v) { + list.push_back(e); + } + } +} +template > +inline IValue::IValue(at::OptionalArrayRef mb_v) : IValue() { + if (!mb_v.has_value()) return; + *this = IValue(*mb_v); +} +template > +inline IValue::IValue(const std::vector& v) : IValue() { + *this = IValue(at::ArrayRef(v)); +} +template > +inline IValue::IValue(std::vector&& v) : IValue() { + auto vi = c10::asIntArrayRefSlowOpt(v); + if (vi.has_value()) { + // This list is entirely integers; ensure it is typed as + // an IntList so toIntList works + *this = IValue(*vi); + } else { + // This list has SymInts; type it as a SymInt + *this = IValue(impl::toList(c10::List())); + auto list = to>(); + list.reserve(v.size()); + for (auto&& e : std::move(v)) { + list.push_back(std::move(e)); + } + } +} +template > +inline IValue::IValue(const std::vector& v) : IValue(c10::List()) { + auto list = to>(); + list.reserve(v.size()); + for (const auto& e : v) { + list.push_back(e); + } +} + +template > +inline IValue::IValue(std::vector&& v) : IValue(c10::List()) { + auto list = to>(); + list.reserve(v.size()); + if constexpr (std::is_same_v) { + for (auto e : v) { + list.push_back(e); + } + } else { + for (auto&& e : std::move(v)) { + list.push_back(std::move(e)); + } + } +} + +template > +inline IValue::IValue(c10::OptionalArrayRef v) : IValue() { + if (v.has_value()) { + *this = IValue(std::move(*v)); + } +} + +template +inline IValue::IValue(std::array v) : IValue(c10::List()) { + auto list = to>(); + list.reserve(v.size()); + for (auto& e : v) { + list.push_back(std::move(e)); + } +} + +template > +inline IValue::IValue(c10::IListRef v) : IValue() { + constexpr bool boxed_type_constructs_ivalue = + std::is_constructible_v::boxed_type>; + // First, we try to use the boxed value. + // If we fail (either it's not in the boxed state, or its boxed type + // can not construct an IValue), we fallback to copying the list. + if (boxed_type_constructs_ivalue && v.isBoxed()) { + *this = IValue(impl::toList(v.toBoxed())); + } else { + c10::List list; + list.reserve(v.size()); + for (const auto& t : v) { + list.push_back(t); + } + *this = IValue(impl::toList(std::move(list))); + } +} + +inline IValue::IValue(c10::impl::GenericDict v) + : tag(Tag::GenericDict) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.impl_.release()); +} +template +inline IValue::IValue(c10::Dict v) + : IValue(impl::toGenericDict(std::move(v))) {} + +template +inline IValue::IValue(std::unordered_map v) + : IValue(Dict()) { + auto dict = to>(); + dict.reserve(v.size()); + for (auto& e : v) { + dict.insert(std::move(e.first), std::move(e.second)); + } +} + +template > +inline IValue::IValue(std::optional v) : IValue() { + if (v.has_value()) { + *this = IValue(std::move(*v)); + } +} + +inline IValue::IValue(std::nullopt_t) : IValue() {} + +inline IValue::IValue(c10::intrusive_ptr v) + : tag(Tag::Object) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.release()); +} + +inline IValue::IValue(c10::intrusive_ptr v) + : tag(Tag::PyObject) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.release()); +} + +inline IValue::IValue(c10::intrusive_ptr v) + : tag(Tag::Enum) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.release()); +} + +inline IValue IValue::make_capsule( + intrusive_ptr blob) { + IValue iv; + iv.tag = Tag::Capsule; + iv.payload.u.as_intrusive_ptr = null_to_undefined_tensor(blob.release()); + return iv; +} + +template < + typename T, + std::enable_if_t, int>> +IValue::IValue(c10::intrusive_ptr custom_class) : tag(Tag::Object) { + auto classType = []() { + try { + return c10::getCustomClassType>(); + } catch (const c10::Error&) { + throw c10::Error( + "Trying to instantiate a class that isn't a registered custom class: " + + std::string(c10::util::get_fully_qualified_type_name())); + } + }(); + auto ivalue_obj = c10::ivalue::Object::create(std::move(classType), /* numSlots */1); + ivalue_obj->setSlot(0, IValue::make_capsule(std::move(custom_class))); + payload.u.as_intrusive_ptr = null_to_undefined_tensor(ivalue_obj.release()); + +} + +inline IValue::IValue(c10::intrusive_ptr v) + : tag(Tag::Future) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.release()); +} + +inline IValue::IValue(c10::intrusive_ptr v) + : tag(Tag::Await) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.release()); +} + +inline IValue::IValue(c10::intrusive_ptr v) + : tag(Tag::RRef) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.release()); +} + +inline IValue::IValue(c10::intrusive_ptr v) + : tag(Tag::Quantizer) { + payload.u.as_intrusive_ptr = null_to_undefined_tensor(v.release()); +} + +template +inline IValue::IValue(c10::complex c) + : tag(Tag::ComplexDouble) { + auto v = c10::make_intrusive(c); + payload.u.as_intrusive_ptr = v.release(); +} + +inline const std::string& IValue::toStringRef() const { + AT_ASSERT(isString(), "Expected String but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toStringRef on null intrusive_ptr IValue"); + return static_cast( + payload.u.as_intrusive_ptr) + ->string(); +} +inline std::optional> IValue:: + toOptionalStringRef() const { + if (isNone()) { + return std::nullopt; + } + AT_ASSERT(isString(), "Expected std::optional but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toOptionalStringRef on null intrusive_ptr IValue"); + return std::reference_wrapper( + static_cast(payload.u.as_intrusive_ptr) + ->string()); +} + +inline std::string_view IValue::toStringView() const { + AT_ASSERT(isString(), "Expected String but got ", tagKind()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + payload.u.as_intrusive_ptr != c10::UndefinedTensorImpl::singleton(), + "called toStringView on null intrusive_ptr IValue"); + return static_cast( + payload.u.as_intrusive_ptr) + ->string_view(); +} + +inline PyObject* IValue::toPyObject() const { + return toPyObjectHolder()->getPyObject(); +} + +template +inline std::optional IValue::toOptional() { + if (this->isNone()) { + return std::nullopt; + } + return this->to(); +} + +template +inline std::optional IValue::toOptional() const { + if (this->isNone()) { + return std::nullopt; + } + return this->to(); +} + +inline bool IValue::isCustomClass() const { + return torch::isCustomClass(*this); +} + +inline bool IValue::isSameIdentity(const IValue& rhs) const { + // We choose to not use memcmp for payload check due to potential random + // padding characters on union type + + // Semantics: + // 1. Immutable primitive values of the same type (Int, Double, None, Bool, + // Str) return value equality + // 2. If it is a tensor type, we need to take undefined tensor into account + // 3. Undefined_tensor is None and vice versa should be true + // 4. If it is a reference type (i.e. isIntrusivePtr()), then is True when + // the pointed-to object is the same. + // 5. False for all other comparisons. + if (this->isNone() && rhs.isNone()) { + return true; + } else if (this->isBool() && rhs.isBool()) { + // for bool type, do equality check + return this->toBool() == rhs.toBool(); + } else if (this->isTensor() && rhs.isTensor()) { + return this->payload.as_tensor.is_same(rhs.payload.as_tensor); + } else if (this->isTensor() && rhs.isNone()) { + // special case: undefined tensor and None are the same identity + return !this->payload.as_tensor.defined(); + } else if (this->isNone() && rhs.isTensor()) { + // special case: undefined tensor and None are the same identity + return !rhs.payload.as_tensor.defined(); + } else if (this->isInt() && rhs.isInt()) { + return this->toInt() == rhs.toInt(); + } else if (this->isDouble() && rhs.isDouble()) { + return this->toDouble() == rhs.toDouble(); + } else if (this->isString() && rhs.isString()) { + return this->toStringRef() == rhs.toStringRef(); + } else { + // for objects holding in IValue, do shallow compare on pointer address to + // testify the identity + return this->isIntrusivePtr() && rhs.isIntrusivePtr() && + this->payload.u.as_intrusive_ptr == rhs.payload.u.as_intrusive_ptr; + } +} + +namespace ivalue { +namespace detail { + +template +IValue from_(T&& x, std::true_type) { + return IValue(std::forward(x)); +} +template +IValue from_(c10::intrusive_ptr x, std::false_type) { + return IValue(std::move(x)); +} +template +IValue from_(T&& /*x*/, std::false_type) { + static_assert( + guts::false_t::value, + "You are calling from with a type that it doesn't support, and isn't a potential custom class (ie: is an intrusive_ptr)"); + return IValue(); +} +} // namespace detail + +template +IValue from(T&& x) { + return detail::from_( + std::forward(x), typename std::is_constructible::type{}); +} + +} // namespace ivalue + + +template <> +struct MaybeOwnedTraits { + using owned_type = IValue; + using borrow_type = IValue; + + static borrow_type createBorrow(const owned_type& from) { + if (!from.isPtrType()) { + return from; + } + if (from.isTensor()) { + return IValue(MaybeOwnedTraits::createBorrow(from.toTensor())); + } else { + return IValue(from.payload, from.tag); + } + } + + static void assignBorrow(borrow_type& lhs, const borrow_type& rhs) { + lhs.clearToNone(); + if (!rhs.isPtrType()) { + lhs = rhs; + } else if (rhs.isTensor()) { + lhs = IValue(MaybeOwnedTraits::createBorrow(rhs.toTensor())); + } else { + lhs = IValue(rhs.payload, rhs.tag); + } + } + + static void destroyBorrow(borrow_type& toDestroy) { + toDestroy.clearToNone(); + } + + static const owned_type& referenceFromBorrow(const borrow_type& borrow) { + return borrow; + } + + static const owned_type* pointerFromBorrow(const borrow_type& borrow) { + return &borrow; + } + + static bool debugBorrowIsValid(const borrow_type&) { + return true; + } +}; + +template <> +struct IValue::TagType { + static TORCH_API c10::TypePtr get(const IValue&); +}; + +template <> +struct IValue::TagType { + static TORCH_API c10::TypePtr get(const IValue&); +}; + +template +TypePtr IValue::type() const { + return IValue::TagType::get(*this); +} + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ivalue_to.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ivalue_to.h new file mode 100644 index 0000000000000000000000000000000000000000..52af58083596939106fe120abfbd360f0068db67 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/ivalue_to.h @@ -0,0 +1,36 @@ +#pragma once + +#include + +namespace at { +class Tensor; +} // namespace at + +namespace c10 { +struct IValue; +namespace detail { +// Determine the return type of `IValue::to() const &`. It's a const +// reference when possible and a copy otherwise. It is in this +// separate header so that List can use it as well. +template +struct ivalue_to_const_ref_overload_return { + using type = T; +}; + +template<> +struct ivalue_to_const_ref_overload_return { + using type = const at::Tensor&; +}; + +template<> +struct ivalue_to_const_ref_overload_return { + using type = const std::string&; +}; + +template<> +struct ivalue_to_const_ref_overload_return { + using type = const IValue&; +}; + +} // namespace detail +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/jit_type.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/jit_type.h new file mode 100644 index 0000000000000000000000000000000000000000..c15e5f72af27c1b2e1ee7d9725e1b5cd60c340c6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/jit_type.h @@ -0,0 +1,2437 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include + + +namespace torch::jit { +struct Function; +} // namespace torch::jit + + +namespace c10 { + +template +class Dict; +struct IValue; +struct FunctionSchema; +struct NamedType; +using OptNameList = std::optional>; + +void standardizeVectorForUnion(std::vector& reference, std::vector* to_fill); +void standardizeVectorForUnion(std::vector* to_flatten); + +inline bool is_contiguous_strides( + const IntArrayRef sizes, + const IntArrayRef strides) { + int n_dim = static_cast(sizes.size()); + if (n_dim == 0) { + return true; + } + + if (strides[n_dim - 1] != 1) { + return false; + } + + for (int i = n_dim - 2; i >= 0; i--) { + if (strides[i] != strides[i + 1] * sizes[i + 1]) { + return false; + } + } + return true; +} + +struct AnyType; +using AnyTypePtr = SingletonTypePtr; +// Any is the top of the type hierarchy, all other types are subtypes +// T <: Any, forall T +struct TORCH_API AnyType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "Any"; + } + static const TypeKind Kind = TypeKind::AnyType; + // global singleton + static AnyTypePtr get(); + + private: + AnyType() : Type(TypeKind::AnyType) {} +}; + +inline std::string toString(const Type& type) { + return type.str(); +} + +// Shim for compatibility with code that uses TypePtr. +inline std::string toString(const TypePtr& typePtr) { + return toString(*typePtr); +} + +inline bool operator!=(const Type& lhs, const Type& rhs) { + return !(lhs == rhs); +} + +// common base for all types that have a single sub element +// e.g. Future[T], Optional[T], List[T] +template +struct SingleElementType : public SharedType { + static const TypeKind Kind = K; + + const TypePtr& getElementType() const { + return elem; + } + + bool hasFreeVariables() const override { + return getElementType()->hasFreeVariables(); + } + + at::ArrayRef containedTypes() const override { + return elem; + } + + bool equals(const Type& rhs) const override { + if (auto rhs_ = rhs.cast()) { + return *getElementType() == *rhs_->getElementType(); + } + return false; + } + + protected: + SingleElementType(TypePtr elem) : SharedType(Kind), elem(std::move(elem)) { + if (!this->elem) { + throw std::runtime_error(c10::str( + "Can not create ", typeKindToString(Kind), " with None type")); + } + } + + private: + TypePtr elem; +}; + +struct UnionType; +using UnionTypePtr = std::shared_ptr; +struct TORCH_API UnionType : public SharedType { + friend struct Type; + + static const TypeKind Kind = TypeKind::UnionType; + + bool isSubtypeOfExt(const Type& rhs_, std::ostream* why_not) const override; + + std::string str() const override; + + static UnionTypePtr create(std::vector reference); + + bool equals(const Type& rhs) const override; + + bool isUnionType() const override { + return true; + } + + at::ArrayRef containedTypes() const override { + return types_; + } + + // For testing purposes only + at::ArrayRef getTypes() const { + return types_; + } + + TypePtr createWithContained(std::vector contained_types) const override { + return create(std::move(contained_types)); + } + + bool canHoldType(const Type& type) const; + + bool hasFreeVariables() const override { + return has_free_variables_; + } + + std::optional toOptional() const; + + std::optional subtractTypeSet(std::vector& to_subtract) const; + + protected: + explicit UnionType(std::vector types, TypeKind kind=TypeKind::UnionType); + std::string annotation_str_impl(const TypePrinter& printer = nullptr) const override; + std::string unionStr( + const TypePrinter& printer = nullptr, + bool is_annotation_str = false) const; + // NOLINTNEXTLINE(cppcoreguidelines-non-private-member-variables-in-classes) + bool has_free_variables_; + // NOLINTNEXTLINE(cppcoreguidelines-non-private-member-variables-in-classes) + std::vector types_; + // NOLINTNEXTLINE(cppcoreguidelines-non-private-member-variables-in-classes) + bool can_hold_none_; + +}; + +struct OptionalType; +using OptionalTypePtr = std::shared_ptr; +// This type represents an optional type. There is one `Optional` for +// each element type. `Optional[T]` can accept both `T` and +// `None`(`std::nullopt` in C++) +// Subtype hierarchy for Optional: +// - Optional[T] <: Optional[R] iff T <: R +// - T <: Optional[R] if T <: R +// - None <: Optional[T] for all T +// - Optional[T] == Union[T, None] for all T +struct TORCH_API OptionalType : public UnionType { + static OptionalTypePtr create(const TypePtr& contained); + + static const TypeKind Kind = TypeKind::OptionalType; + + friend struct Type; + + bool equals(const Type& rhs) const override; + + const TypePtr& getElementType() const { + return contained_; + } + + at::ArrayRef containedTypes() const override { + return contained_; + } + + std::string str() const override { + std::stringstream ss; + ss << getElementType()->str() << "?"; + return ss.str(); + } + + TypePtr createWithContained( + std::vector contained_types) const override { + AT_ASSERT(contained_types.size() == 1); + return create(contained_types[0]); + } + + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override; + + bool isUnionType() const override { + return true; + } + + // common cast Optional[Tensor] for undefined tensor type + static TypePtr ofTensor(); + // + // global singleton + static TypePtr get(TypePtr inner); + + private: + explicit OptionalType(const TypePtr& contained); + + TypePtr contained_; + + std::string annotation_str_impl(const TypePrinter& printer = nullptr) const override { + std::stringstream ss; + ss << "Optional[" << getElementType()->annotation_str(printer) << "]"; + return ss.str(); + } +}; + +template +inline std::optional merge_primitive( + const std::optional& a, + const std::optional& b) { + if (a.has_value() && b.has_value() && a.value() == b.value()) { + return a; + } + return std::optional{}; +} + +// If we see `a + b + c` and know that a, b, and c are the same size and have +// two dimensions (WxH), then we can generate a fused kernel for them. That +// fused kernel would likely have indexing math to handling both the W and H +// dimensions. However, if we knew the WxH dimensions were contiguous, we can +// pretend like we only have a single dimension, simplifying the indexing logic. +// This can be performed even if the dimensions are transposed, +// as long as a, b, and c are transposed in the same way. +// We'd like to have the compiler be able to do this dimensionality reduction, +// but simply knowing sizes is not enough. +// We can extend profiling to also record stride information. +// Rather than recording specific strides, +// we can simply order the strides from smallest to largest with +// `stride_indices` A contiguity marker on the smallest stride (c0) indicates +// the stride is precisely 1, otherwise a contiguity marker means that $stride_n +// = size_{n-1}*stride_{n-1}$ +struct TORCH_API Stride { + Stride() = default; + Stride( + const std::optional& stride_index, + std::optional contiguous, + const std::optional& stride) + : stride_index_(stride_index), contiguous_(contiguous), stride_(stride) {} + + bool operator==(const Stride& b) const { + return stride_index_ == b.stride_index_ && contiguous_ == b.contiguous_ && + stride_ == b.stride_; + } + + bool isComplete() const { + return stride_index_ && contiguous_ && stride_; + } + + std::optional stride_index_; + std::optional contiguous_; + std::optional stride_; +}; + +template <> +inline std::optional merge_primitive( + const std::optional& a, + const std::optional& b) { + std::optional left = a; + std::optional right = b; + if (!left.has_value()) { + left = {Stride()}; + } + if (!right.has_value()) { + right = {Stride()}; + } + + auto merged_index = + merge_primitive(left->stride_index_, right->stride_index_); + auto merged_cont = merge_primitive(left->contiguous_, right->contiguous_); + auto merged_stride = merge_primitive(left->stride_, right->stride_); + auto r = Stride(merged_index, merged_cont, merged_stride); + // normalize + if (!r.stride_index_.has_value() && !r.contiguous_.has_value() && + !r.stride_.has_value()) { + return std::optional{}; + } + + return r; +} + +struct TORCH_API ShapeSymbol { + // needed for use in `std::map` + ShapeSymbol() : value_(-1) {} + // is this symbol a fixed/static dimension + bool is_static() const { + return value_ >= 0; + } + bool operator==(const ShapeSymbol& b) const { + return value_ == b.value_; + } + bool operator<(const ShapeSymbol& b) const { + return value_ < b.value_; + } + + static ShapeSymbol fromStaticSize(int64_t val) { + return ShapeSymbol(val); + } + int64_t static_size() const { + TORCH_CHECK(is_static()); + return value_; + } + + int64_t value() const { + return value_; + } + + static ShapeSymbol newSymbol() { + return fromStaticSize(-static_cast(++num_symbols)); + } + friend TORCH_API std::ostream& operator<<( + std::ostream& os, + const ShapeSymbol& s); + + private: + ShapeSymbol(int64_t val) : value_(val) {} + int64_t value_; + static std::atomic num_symbols; +}; + +inline ShapeSymbol merge_primitive( + const ShapeSymbol& a, + const ShapeSymbol& b) { + if (a.is_static() && b.is_static() && a == b) { + return a; + } + return ShapeSymbol::newSymbol(); +} + +// Shape of a Tensor represented with ShapeSymbol's. Unranked, ranked unknown +// dims, partially known and fully known shapes are all supported. +struct TORCH_API SymbolicShape { + // Unranked shape constructor. + SymbolicShape() : dims_(std::nullopt) {} + + // Known rank but unknown dimentions. + SymbolicShape(std::optional rank) : dims_(std::nullopt) { + if(!rank) { + return; + } + + std::vector shape_symbols; + shape_symbols.reserve(*rank); + for(size_t i = 0; i < *rank; ++i) { + shape_symbols.push_back(ShapeSymbol::newSymbol()); + } + dims_ = shape_symbols; + } + + // Mix of known and unknown ranks + SymbolicShape(const std::vector>& dims) { + std::vector shape_symbols; + shape_symbols.reserve(dims.size()); + for(std::optional dim: dims) { + if(!dim) { + shape_symbols.push_back(ShapeSymbol::newSymbol()); + } else { + shape_symbols.push_back(ShapeSymbol::fromStaticSize(*dim)); + } + } + dims_ = shape_symbols; + } + + void dump() const; + + SymbolicShape(std::vector dims) : dims_(std::move(dims)) {} + + SymbolicShape(c10::IntArrayRef dims) { + std::vector shape_symbols; + shape_symbols.reserve(dims.size()); + for(int64_t dim : dims) { + shape_symbols.push_back(ShapeSymbol::fromStaticSize(dim)); + } + dims_ = shape_symbols; + } + + ShapeSymbol operator[](size_t i) const { + if (!dims_) { + throw std::runtime_error("Rank isn't fixed"); + } + return (*dims_).at(i); + } + + ShapeSymbol at(size_t i) const { + if (!dims_) { + throw std::runtime_error("Rank isn't fixed"); + } + return (*dims_).at(i); + } + + // Returns rank or nullopt in case of unranked shape. + std::optional rank() const { + if(!dims_) { + return std::nullopt; + } + return dims_->size(); + } + + std::optional> sizes() const { + return dims_; + } + + std::optional> symbolicDims() const { + if (!dims_) { + return std::nullopt; + } + auto symbolic_dims = std::vector(); + for (const ShapeSymbol& s : *dims_) { + symbolic_dims.push_back(!s.is_static()); + } + return symbolic_dims; + } + + // Checks whether the shape is fully defined/complete, ie. rank and sizes + // of every dimension are known. + bool isComplete() const { + if(!dims_) { + return false; + } + for(auto d : *dims_) { + if(!d.is_static()) { + return false; + } + } + return true; + } + + // Create new SymbolicShape that is result of merging self and another + // SymbolicShape. Only dimensions that are static and equal will be + // preserved. + // If either of two shapes are of unknown rank or they have unmatching rank, + // result will be unranked. + SymbolicShape merge(const SymbolicShape& other) const; + + friend bool operator==(const SymbolicShape& lhs, const SymbolicShape& rhs) { + return lhs.dims_ == rhs.dims_; + } + + friend bool operator!=(const SymbolicShape& lhs, const SymbolicShape& rhs) { + return !(lhs == rhs); + } + + private: + std::optional> dims_; +}; + +namespace detail { +inline bool isComplete(const Stride& s) { + return s.isComplete(); +} + +template +inline bool isComplete(const T& /*t*/) { + return true; +} +} + +template +struct VaryingShape { + using ListOfOptionalElements = std::vector>; + VaryingShape(const std::vector& vec) + : VaryingShape(ListOfOptionalElements(vec.begin(), vec.end())) {} + + VaryingShape(c10::ArrayRef vec) + : VaryingShape(ListOfOptionalElements(vec.begin(), vec.end())) {} + + VaryingShape(std::optional size = std::nullopt) : dims_(std::nullopt) { + if (size) { + dims_ = ListOfOptionalElements(*size); + } + } + + VaryingShape(ListOfOptionalElements dims) : dims_(std::move(dims)) {} + + VaryingShape(size_t size) : VaryingShape(std::optional(size)) {} + + bool operator==(const VaryingShape& other) const { + return dims_ == other.dims_; + } + + const std::optional &operator[](size_t i) const { + if (!dims_) { + throw std::runtime_error("Rank isn't fixed"); + } + return (*dims_).at(i); + } + + std::optional size() const { + if (!dims_) { + return std::nullopt; + } + const auto& dims = dims_.value(); + return dims.size(); + } + + const std::optional& sizes() const { + return dims_; + } + + TORCH_API VaryingShape merge(const VaryingShape& other) const; + + std::optional> concrete_sizes() const { + if (!dims_) { + return std::nullopt; + } + std::vector sizes; + sizes.reserve(dims_.value().size()); + for (auto d : *dims_) { + if (!d) { + return std::nullopt; + } + sizes.push_back(d.value()); + } + return sizes; + } + + bool isComplete() const { + if (!dims_) { + return false; + } + for (auto d : *dims_) { + if (!d || !detail::isComplete(*d)) { + return false; + } + } + return true; + } + + private: + std::optional dims_; +}; + +struct TensorType; +// TODO: investigate making this SingletonOrSharedTypePtr +using TensorTypePtr = std::shared_ptr; +// This type represents a single Tensor with a specific size +struct TORCH_API TensorType : public SharedType { + static TensorTypePtr create(const at::Tensor& t); + + // used by TensorType::create(size_t dim) which in turn used by + // shape_analysis.cpp + static TensorTypePtr create( + std::optional scalar_type, + std::optional device, + const VaryingShape& sizes, + const VaryingShape& strides, + std::optional requires_grad, + std::optional undefined = false, + bool tensor_contiguity = false); + + static TensorTypePtr create( + std::optional scalar_type, + std::optional device, + SymbolicShape sizes, + VaryingShape stride_, + std::optional requires_grad, + std::optional undefined = false); + + static TensorTypePtr create( + std::optional scalar_type, + std::optional device, + std::optional dim, + std::optional requires_grad); + + // overloaded create variadic template argument as it could not distinguish + // initializer list + static TensorTypePtr createContiguous( + at::ScalarType scalar_type, + at::Device device, + at::IntArrayRef sizes); + + static TypePtr fromNumberType(const Type& typ); + static TypePtr fromBoolType(); + + std::optional dim() const { + return sizes().size(); + } + + VaryingShape sizes() const; + + VaryingShape strides() const; + + const VaryingShape& stride_properties() const { + return strides_; + } + + const std::optional& device() const { + return device_; + } + const std::optional& scalarType() const { + return scalar_type_; + } + const std::optional& requiresGrad() const { + return requires_grad_; + } + bool requires_grad() const override { + return requires_grad_ ? *requires_grad_ : true; + } + + bool equals(const Type& rhs) const override; + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override; + + std::string str() const override; + + std::string repr_str() const override { + if (isInferredType()) { + return str() + " (inferred)"; + } else { + return str(); + } + } + + std::optional numel() const { + size_t prod = 1; + const auto& shape = sizes(); + + for (size_t i = 0; i < shape.size(); i++) { + auto const &s = shape[i]; + if (!s.has_value()) { + return std::optional{}; + } + prod *= s.value(); + } + return prod; + } + + TensorTypePtr withRequiresGrad(std::optional s) { + auto copy = clone(); + copy->requires_grad_ = s; + return copy; + } + + TensorTypePtr withScalarType(std::optional st) { + auto copy = clone(); + copy->scalar_type_ = st; + return copy; + } + + TensorTypePtr withDim(std::optional d) { + auto copy = clone(); + // withDim is only used by the legacy executor + // that only cares about the rank, so create dummy symbols)) : + copy->sizes_ = SymbolicShape(d); + copy->strides_ = VaryingShape(d); + return copy; + } + + TensorTypePtr withStrides(VaryingShape sstrides) const { + auto cloned = clone(); + cloned->strides_ = std::move(sstrides); + return cloned; + } + + TensorTypePtr withSizesStrides( + at::IntArrayRef sizes, + at::IntArrayRef strides) const { + auto cloned = clone(); + auto ssizes = SymbolicShape(sizes); + cloned->sizes_ = ssizes; + cloned->strides_ = computeStrideProps(sizes, strides); + return cloned; + } + + TensorTypePtr withSymbolicShapes(SymbolicShape ssizes) const { + auto cloned = clone(); + cloned->sizes_ = std::move(ssizes); + return cloned; + } + + TensorTypePtr withSizes(at::IntArrayRef sizes) const { + return withSizesStrides( + sizes, contiguousStridesOf(sizes)); + } + + TensorTypePtr withDevice(const std::optional device) const { + auto copy = clone(); + copy->device_ = device; + return copy; + } + + TensorTypePtr dimensionedOnly() const { + auto copy = clone(); + copy->sizes_ = SymbolicShape(sizes().size()); + copy->strides_ = VaryingShape(sizes().size()); + return copy; + } + + TensorTypePtr contiguous() const { + auto cloned = clone(); + auto concrete_sizes = sizes().concrete_sizes(); + TORCH_INTERNAL_ASSERT(concrete_sizes.has_value()); + auto strides = computeStrideProps( + *concrete_sizes, + contiguousStridesOf(*concrete_sizes)); + cloned->strides_ = strides; + return cloned; + } + + const SymbolicShape& symbolic_sizes() const; + + TensorTypePtr merge(const TensorType& other, bool merge_sizes = true) const; + + bool matchTensor(const at::Tensor& t); + + // is all information about the type specified except for autograd? + // This replaces the notion of a 'CompleteTensorType' that used to exist + // in the type-hierarchy. Excluding require_grad and undefined allows + // this to match the old behavior. + bool isComplete() const { + return scalar_type_ && device_ && sizes_.isComplete() && strides_.isComplete(); + } + + bool isInferredType() const { + return is_inferred_; + } + + static TensorTypePtr getInferred() { + static auto valueInferred = TensorType::create( + /*scalar_type=*/{}, + /*device=*/{}, + /*sizes=*/SymbolicShape(), + /*stride=*/VaryingShape{}, + /*requires_grad=*/{}, + /*undefined=*/false); + valueInferred->is_inferred_ = true; + return valueInferred; + } + + // this property is used by GuardElimination + // please see `checkInputs` for more details + bool isSummarized() const { + return !(isComplete() && requiresGrad().has_value() && + undefined().has_value()); + } + + TensorTypePtr withUndefined() { + auto r = clone(); + r->undefined_ = true; + return r; + } + + TensorTypePtr withPossiblyUndefined() { + auto r = clone(); + r->undefined_ = std::nullopt; + return r; + } + + std::optional undefined() const { return undefined_; } + + static const TensorTypePtr& get(); + + static const TypeKind Kind = TypeKind::TensorType; + + static std::vector contiguousStridesOf( + at::IntArrayRef in_sizes, + at::MemoryFormat memory_format = MemoryFormat::Contiguous) { + auto contiguous_fn = [](const at::IntArrayRef& sizes, + const std::vector& dim_order) { + std::vector strides(sizes.size()); + if (sizes.empty()) // zero-dim case + return strides; + + strides[dim_order[0]] = 1; + for (size_t i = 1; i < dim_order.size(); i++) { + auto cur_dim = dim_order[i]; + auto pre_dim = dim_order[i - 1]; + strides[cur_dim] = strides[pre_dim] * sizes[pre_dim]; + } + return strides; + }; + + std::vector dim_order(in_sizes.size()); + if (memory_format == MemoryFormat::ChannelsLast) { + dim_order = {1, 3, 2, 0}; + } else if (memory_format == MemoryFormat::ChannelsLast3d) { + dim_order = {1, 4, 3, 2, 0}; + } else { + auto ndims = in_sizes.size(); + for (size_t i = 0; i < ndims; i++) { + dim_order[i] = static_cast(ndims - i - 1); // Reverse + } + } + return contiguous_fn(in_sizes, dim_order); + } + + private: + TensorType( + std::optional scalar_type, + std::optional device, + SymbolicShape sizes, + VaryingShape strides, + std::optional requires_grad, + std::optional undefined = false); + + TensorTypePtr clone() const { + return TensorTypePtr(new TensorType( + scalar_type_, device_, sizes_, strides_, requires_grad_, undefined_)); + } + + static VaryingShape computeStrideProps( + at::IntArrayRef sizes, + at::IntArrayRef strides, + bool tensor_contiguity = false); + + std::optional scalar_type_; + std::optional device_; + SymbolicShape sizes_; + VaryingShape strides_; + std::optional requires_grad_; + // we exploit the fact certain tensors must be zero in the autograd to + // optimize gradient computation. Such zero tensors are currently implemented + // with `UndefinedTensorImpl.` They can be handled only by special operators + // (e.g. `AutogradAdd`) and their `Tensor::defined()` property returns false. + // Normally, `undefined_` is set to false, unless a type was created + // with `withUndefined` + // This will also mean that `undefined` tensors will fail + // `subtypeOf(TensorType::get())` check + // undefined_ may become `std::nullopt` if the tensor was observed to be both + // defined and undefined. However, no tensor type starts out with + // `undefined_` set to `std::nullopt` + std::optional undefined_; + // Represents whether or not this type was inferred. + bool is_inferred_ = false; +}; + +struct ListType; +using ListTypePtr = std::shared_ptr; +struct TORCH_API ListType + : public SingleElementType { + // It's not exactly a singleton, but there should be exactly one instance of + // List[T] for every T + friend struct Type; + template + static ListTypePtr create(T&&... all) { + return ListTypePtr( + new ListType(std::forward(all)...)); // NOLINT(modernize-make-shared) + } + + std::string str() const override { + std::stringstream ss; + ss << getElementType()->str() << "[]"; + return ss.str(); + } + TypePtr createWithContained( + std::vector contained_types) const override { + return create(std::move(contained_types.at(0))); + } + + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override; + + // global singleton + // Given an inner type T and an identifier, + // this function wil return the global singleton type pointer + // the type List. + // The extra "identifier" argument is needed beccause we have multiple container types + // that all re-use this function (List, array, etc.) + static TypePtr get(const std::string& identifier, TypePtr inner); + + // common cast List[Tensor] + static ListTypePtr ofTensors(); + static ListTypePtr ofOptionalTensors(); + static ListTypePtr ofInts(); + static ListTypePtr ofSymInts(); + static ListTypePtr ofFloats(); + static ListTypePtr ofComplexDoubles(); + static ListTypePtr ofBools(); + static ListTypePtr ofStrings(); + static ListTypePtr ofNumbers(); + + private: + ListType(TypePtr elem) : SingleElementType(std::move(elem)) {} + + std::string annotation_str_impl(const TypePrinter& printer = nullptr) const override { + std::stringstream ss; + ss << "List[" << getElementType()->annotation_str(printer) << "]"; + return ss.str(); + } +}; + +struct DictType; +using DictTypePtr = std::shared_ptr; +struct TORCH_API DictType : public SharedType { + friend struct Type; + static const TypeKind Kind = TypeKind::DictType; + + static DictTypePtr create(TypePtr key, TypePtr value) { + auto kind = key->kind(); + if (auto dyn = key->castRaw()) { + kind = dyn->dynamicKind(); + } + switch (kind) { + case TypeKind::AnyType: + case TypeKind::IntType: + case TypeKind::BoolType: + case TypeKind::FloatType: + case TypeKind::ComplexType: + case TypeKind::StringType: + case TypeKind::TensorType: + case TypeKind::DeviceObjType: + return DictTypePtr(new DictType(std::move(key), std::move(value))); + default: + TORCH_CHECK(false, + "Cannot create dict for key type '", + key->str(), + "', only int, float, complex, Tensor, device and string keys are supported"); + } + } + + // aligned with the format in FunctionSchema + std::string str() const override { + std::stringstream ss; + ss << "Dict(" << getKeyType()->str() << ", " << getValueType()->str() + << ")"; + return ss.str(); + } + + TypePtr createWithContained( + std::vector contained_types) const override { + if (contained_types.size() != 2) { + throw std::runtime_error("Expected 2 contained types"); + } + return create(std::move(contained_types.at(0)), std::move(contained_types.at(1))); + } + + const TypePtr& getKeyType() const { + return types.at(0); + } + + const TypePtr& getValueType() const { + return types.at(1); + } + + bool hasFreeVariables() const override { + return has_free_variables; + } + + at::ArrayRef containedTypes() const override { + return types; + } + + bool equals(const Type& rhs) const override { + if (auto* dict_rhs = rhs.castRaw()) { + return *getKeyType() == *(dict_rhs->getKeyType()) && + *getValueType() == *(dict_rhs->getValueType()); + } + return false; + } + + // global singleton + // Given an inner type T and an identifier, + // this function will return the global singleton type pointer + // the type List. + // The extra "identifier" argument is needed because we have multiple container types + // that all re-use this function (Dict and unordered_map) + static TypePtr get(const std::string& identifier, TypePtr key, TypePtr val); + + private: + DictType(TypePtr key, TypePtr value) + : SharedType(TypeKind::DictType), + has_free_variables( + key->hasFreeVariables() || value->hasFreeVariables()) { + types.reserve(2); + types.push_back(std::move(key)); + types.push_back(std::move(value)); + } + + std::string annotation_str_impl(const TypePrinter& printer = nullptr) const override; + + std::vector types; + bool has_free_variables; +}; + +struct FutureType; +using FutureTypePtr = std::shared_ptr; + +struct TORCH_API FutureType + : public SingleElementType { + friend struct Type; + template + static FutureTypePtr create(TypePtr elem) { + return FutureTypePtr( + new FutureType(std::move(elem))); // NOLINT(modernize-make-shared) + } + + std::string str() const override { + std::stringstream ss; + ss << "Future(" << getElementType()->str() << ")"; + return ss.str(); + } + TypePtr createWithContained( + std::vector contained_types) const override { + return create(std::move(contained_types.at(0))); + } + + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override { + if (Type::isSubtypeOfExt(rhs, why_not)) { + return true; + } + if (auto rhs_ = rhs.castRaw()) { + return getElementType()->isSubtypeOfExt(*rhs_->getElementType(), why_not); + } + return false; + } + + private: + FutureType(TypePtr elem) : SingleElementType(std::move(elem)) {} + + std::string annotation_str_impl(const TypePrinter& printer = nullptr) const override { + std::stringstream ss; + ss << "Future[" << getElementType()->annotation_str(printer) << "]"; + return ss.str(); + } +}; + +struct AwaitType; +using AwaitTypePtr = std::shared_ptr; + +struct TORCH_API AwaitType + : public SingleElementType { + friend struct Type; + template + static AwaitTypePtr create(TypePtr elem) { + return AwaitTypePtr( + new AwaitType(std::move(elem))); // NOLINT(modernize-make-shared) + } + + std::string str() const override { + std::stringstream ss; + ss << "Await(" << getElementType()->str() << ")"; + return ss.str(); + } + TypePtr createWithContained( + std::vector contained_types) const override { + return create(std::move(contained_types.at(0))); + } + + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override { + if (Type::isSubtypeOfExt(rhs, why_not)) { + return true; + } + if (auto rhs_ = rhs.castRaw()) { + return getElementType()->isSubtypeOfExt(*rhs_->getElementType(), why_not); + } + return false; + } + + private: + AwaitType(TypePtr elem) : SingleElementType(std::move(elem)) {} + + std::string annotation_str_impl(const TypePrinter& printer = nullptr) const override { + std::stringstream ss; + ss << "Await[" << getElementType()->annotation_str(printer) << "]"; + return ss.str(); + } +}; + +struct RRefType; +using RRefTypePtr = std::shared_ptr; + +struct TORCH_API RRefType + : public SingleElementType { + friend struct Type; + template + static RRefTypePtr create(TypePtr elem) { + return RRefTypePtr( + new RRefType(std::move(elem))); // NOLINT(modernize-make-shared) + } + + std::string str() const override { + std::stringstream ss; + ss << "RRef(" << getElementType()->str() << ")"; + return ss.str(); + } + TypePtr createWithContained( + std::vector contained_types) const override { + return create(std::move(contained_types.at(0))); + } + + private: + RRefType(TypePtr elem) : SingleElementType(std::move(elem)) {} + + std::string annotation_str_impl(const TypePrinter& printer = nullptr) const override { + std::stringstream ss; + ss << "RRef[" << getElementType()->annotation_str(printer) << "]"; + return ss.str(); + } +}; + +// Any should never appear in a named type like a class, namedtuple or +// interface. If it does, then dynamic type information will be lost in the +// Pickler, leading to hard-to-track-down bugs that will only occur +// after saving or loading a model. This is because we rely on the +// static types in named types to reconstruct type tags of loaded +// values. Lifting this restriction requires solving the serialization +// problem first. +TORCH_API void checkNoAny( + const Type& base, + const char* what, + const std::string& attrname, + const TypePtr& attrtype); + +struct TupleType; +using TupleTypePtr = std::shared_ptr; +using NameList = std::vector; +// This type represents a Tuple +struct TORCH_API TupleType : public NamedType { + + static TupleTypePtr createNamed(const std::optional& name, + const std::vector& field_names, + const std::vector& field_types, + std::vector& field_defaults); + + static TupleTypePtr createNamed(const std::optional& name, + const std::vector& field_names, + const std::vector& field_types); + + static TupleTypePtr createNamed(const std::optional& name, + const std::vector& field_names, + const std::vector& field_types); + + static TupleTypePtr create( + std::vector types) { + return TupleTypePtr(new TupleType( + std::move(types), + std::nullopt, + nullptr)); // NOLINT(modernize-make-shared) + } + static TupleTypePtr create() { + return create({}); + } + + at::ArrayRef elements() const { + return elements_; + } + + bool equals(const Type& rhs) const override; + bool isSubtypeOfExt(const Type& rhs_, std::ostream* why_not) const override; + + std::string str() const override; + bool hasFreeVariables() const override { + return has_free_variables_; + } + at::ArrayRef containedTypes() const override { + return elements_; + } + TypePtr createWithContained( + std::vector contained_types) const override { + return std::shared_ptr( + new TupleType(std::move(contained_types), name(), schema())); + } + const std::shared_ptr& schema() const { + return schema_; + } + std::optional> names() const; + + static const TypeKind Kind = TypeKind::TupleType; + + private: + template + static TupleTypePtr createWithSpec( + const std::optional& name, + const std::vector& field_names, + const std::vector& field_types, + std::vector& field_defaults); + + TupleType( + std::vector elements_, + std::optional name, + std::shared_ptr schema); + + bool compare( + const Type& rhs, + const std::function& fn) const { + if (rhs.kind() != kind()) { + return false; + } + + const auto& l_elements = elements(); + const auto& r_elements = rhs.castRaw()->elements(); + if (l_elements.size() != r_elements.size()) + return false; + for (size_t i = 0; i < l_elements.size(); ++i) { + if (!fn(*l_elements[i], *r_elements[i])) + return false; + } + return true; + } + + std::string annotation_str_impl(const TypePrinter& printer = nullptr) const override; + + std::vector elements_; + bool has_free_variables_; + std::shared_ptr schema_; +}; + +// the common supertype of all Enums, only used in operator registraion. +// EnumType <: AnyEnumType for all Enums +struct AnyEnumType; +using AnyEnumTypePtr = SingletonTypePtr; +struct TORCH_API AnyEnumType final : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "AnyEnumType"; + } + static const TypeKind Kind = TypeKind::AnyEnumType; + // global singleton + static AnyEnumTypePtr get(); +private: + AnyEnumType() + : Type(TypeKind::AnyEnumType) {} +}; + +struct NumberType; +using NumberTypePtr = SingletonTypePtr; +// This type represents a Python number +// Subtype hierarchy for Number Types (NumberType as the base type): +// IntType <: NumberType +// FloatType <: NumberType +// ComplexType <:NumberType +// +// WARNING: if you add a new subtype of NumberType that is not +// represented by a global singleton, you need to change NumberTypePtr +// to a SingletonOrSharedTypePtr and deal with NumberType needing to +// both inherit and not inherit from SharedType! +struct TORCH_API NumberType : public Type { + bool equals(const Type& rhs) const override; + + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override; + + std::string str() const override { + return "Scalar"; // match what PythonArgParser says for clarity + } + static const TypeKind Kind = TypeKind::NumberType; + // global singleton + static NumberTypePtr get(); + + protected: + NumberType(TypeKind kind = TypeKind::NumberType) : Type(kind) {} + + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + return "number"; // technically not a valid python type, but + // we need to use it when parsing back in annotations + // for implicit conversions + } +}; + +struct FloatType; +using FloatTypePtr = SingletonTypePtr; +// This type represents a Python float number +struct TORCH_API FloatType : public NumberType { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "float"; + } + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override { + // NOLINTNEXTLINE(bugprone-parent-virtual-call) + return rhs.kind() == TypeKind::NumberType || Type::isSubtypeOfExt(rhs, why_not); + } + static const TypeKind Kind = TypeKind::FloatType; + // global singleton + static FloatTypePtr get(); + + private: + FloatType() : NumberType(TypeKind::FloatType) {} + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + return "float"; + } +}; + +struct ComplexType; +using ComplexTypePtr = SingletonTypePtr; +// This type represents a Python float number +struct TORCH_API ComplexType : public NumberType { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "complex"; + } + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override { + // NOLINTNEXTLINE(bugprone-parent-virtual-call) + return rhs.kind() == TypeKind::NumberType || Type::isSubtypeOfExt(rhs, why_not); + } + static const TypeKind Kind = TypeKind::ComplexType; + // global singleton + static ComplexTypePtr get(); + + private: + ComplexType() : NumberType(TypeKind::ComplexType) {} + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + return "complex"; + } +}; + +// We need to introduce `SymIntType` to represent the `SymInt` type +// used in function schemas e.g. `aten::narrow_copy(... SymInt length) +// `SymInt` will be used to enable tracing arithmetic operations on +// dimension values. Please see [SymInt.h] for more information +struct SymIntType; +using SymIntTypePtr = SingletonTypePtr; +struct TORCH_API SymIntType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "SymInt"; + } + std::string annotation_str_impl(const TypePrinter& printer [[maybe_unused]] = nullptr) const override { + return "int"; + } + static const TypeKind Kind = TypeKind::SymIntType; + // global singleton + static SymIntTypePtr get(); + + private: + SymIntType() : Type(TypeKind::SymIntType) {} +}; + +struct SymFloatType; +using SymFloatTypePtr = SingletonTypePtr; +struct TORCH_API SymFloatType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "SymFloat"; + } + std::string annotation_str_impl(const TypePrinter& printer [[maybe_unused]] = nullptr) const override { + return "float"; + } + static const TypeKind Kind = TypeKind::SymFloatType; + // global singleton + static SymFloatTypePtr get(); + + private: + SymFloatType() : Type(TypeKind::SymFloatType) {} +}; + +struct SymBoolType; +using SymBoolTypePtr = SingletonTypePtr; +struct TORCH_API SymBoolType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "SymBool"; + } + std::string annotation_str_impl(const TypePrinter& printer [[maybe_unused]] = nullptr) const override { + return "bool"; + } + static const TypeKind Kind = TypeKind::SymBoolType; + // global singleton + static SymBoolTypePtr get(); + + private: + SymBoolType() : Type(TypeKind::SymBoolType) {} +}; + +struct IntType; +using IntTypePtr = SingletonTypePtr; +// This type represents a Python int number +struct TORCH_API IntType : public NumberType { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "int"; + } + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override { + // NOLINTNEXTLINE(bugprone-parent-virtual-call) + return rhs.kind() == TypeKind::NumberType || Type::isSubtypeOfExt(rhs, why_not); + } + static const TypeKind Kind = TypeKind::IntType; + // global singleton + static IntTypePtr get(); + + private: + IntType() : NumberType(TypeKind::IntType) {} + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + return "int"; + } +}; + +struct BoolType; +using BoolTypePtr = SingletonTypePtr; +// This node represents a Python bool value +struct TORCH_API BoolType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "bool"; + } + static const TypeKind Kind = TypeKind::BoolType; + // global singleton + static BoolTypePtr get(); + + private: + BoolType() : Type(TypeKind::BoolType) {} +}; + +struct StringType; +using StringTypePtr = SingletonTypePtr; +// This type represents a Python string +struct TORCH_API StringType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + // we only use "str" (not "string") in both FunctionSchema and script + return annotation_str(); + } + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + return "str"; + } + static const TypeKind Kind = TypeKind::StringType; + // global singleton + static StringTypePtr get(); + + private: + StringType() : Type(TypeKind::StringType) {} +}; + +struct StorageType; +using StorageTypePtr = SingletonTypePtr; +struct TORCH_API StorageType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return annotation_str(); + } + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + return "Storage"; + } + static const TypeKind Kind = TypeKind::StorageType; + // global singleton + static StorageTypePtr get(); + + private: + StorageType() : Type(TypeKind::StorageType) {} +}; + +struct FunctionType; +using FunctionTypePtr = std::shared_ptr; +struct TORCH_API FunctionType : public NamedType { + static FunctionTypePtr create(torch::jit::Function* function) { + return FunctionTypePtr( + new FunctionType(function)); // NOLINT(modernize-make-shared) + } + bool equals(const Type& rhs) const override { + if (auto func_type = rhs.cast()) { + return func_type->function_ == function_; + } + + return false; + } + std::string str() const override { + return "Function"; + } + torch::jit::Function* function() const { + return function_; + } + static const TypeKind Kind = TypeKind::FunctionType; + + private: + FunctionType(torch::jit::Function* function); + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + // NOLINTNEXTLINE(bugprone-unchecked-optional-access) + return name()->qualifiedName(); + } + torch::jit::Function* function_; +}; + +struct NoneType; +using NoneTypePtr = SingletonTypePtr; +// This type represents a Python None +struct TORCH_API NoneType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "NoneType"; + } + bool isSubtypeOfExt(const Type& rhs, std::ostream *why_not) const override; + + static const TypeKind Kind = TypeKind::NoneType; + // global singleton + static NoneTypePtr get(); + + private: + NoneType() : Type(TypeKind::NoneType) {} +}; + +struct GeneratorType; +using GeneratorTypePtr = SingletonTypePtr; +// This type represents a Generator +struct TORCH_API GeneratorType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "Generator"; + } + static const TypeKind Kind = TypeKind::GeneratorType; + // global singleton + static GeneratorTypePtr get(); + + private: + GeneratorType() : Type(TypeKind::GeneratorType) {} +}; + +struct QuantizerType; +using QuantizerTypePtr = SingletonTypePtr; +// This type represents a Quantizer +struct TORCH_API QuantizerType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "Quantizer"; + } + static const TypeKind Kind = TypeKind::QuantizerType; + // global singleton + static QuantizerTypePtr get(); + + private: + QuantizerType() : Type(TypeKind::QuantizerType) {} +}; + +struct QSchemeType; +using QSchemeTypePtr = SingletonTypePtr; +// This type represents a QScheme +struct TORCH_API QSchemeType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "QScheme"; + } + static const TypeKind Kind = TypeKind::QSchemeType; + // global singleton + static QSchemeTypePtr get(); + + private: + QSchemeType() : Type(TypeKind::QSchemeType) {} +}; + +struct DeviceObjType; +using DeviceObjTypePtr = SingletonTypePtr; +// This type represents a Device +struct TORCH_API DeviceObjType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "Device"; + } + static const TypeKind Kind = TypeKind::DeviceObjType; + // global singleton + static DeviceObjTypePtr get(); + + private: + DeviceObjType() : Type(TypeKind::DeviceObjType) {} +}; + +struct StreamObjType; +using StreamObjTypePtr = SingletonTypePtr; +// This type represents a Generator +struct TORCH_API StreamObjType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "Stream"; + } + static const TypeKind Kind = TypeKind::StreamObjType; + // global singleton + static StreamObjTypePtr get(); + +private: + StreamObjType() : Type(TypeKind::StreamObjType) {} +}; + +struct VarType; +using VarTypePtr = std::shared_ptr; +// This type represents a type variable, used in FunctionSchema +struct VarType : public SharedType { + static VarTypePtr create(std::string name_) { + return VarTypePtr(new VarType(std::move(name_))); + } + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return name(); + } + const std::string& name() const { + return name_; + } + bool hasFreeVariables() const override { + return true; + } + static const TypeKind Kind = TypeKind::VarType; + + private: + VarType(std::string name_) + : SharedType(TypeKind::VarType), name_(std::move(name_)) {} + std::string name_; +}; + +struct CapsuleType; +using CapsuleTypePtr = SingletonTypePtr; +// This type represents a Python Capsule. +// It does not appear in the IR and is only used during runtime +struct TORCH_API CapsuleType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "Capsule"; + } + static const TypeKind Kind = TypeKind::CapsuleType; + // global singleton + static CapsuleTypePtr get(); +private: + CapsuleType() + : Type(TypeKind::CapsuleType) {} +}; + +struct PyObjectType; +using PyObjectTypePtr = SingletonTypePtr; +// This type represents a PyObject Type +struct TORCH_API PyObjectType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "PyObject"; + } + static const TypeKind Kind = TypeKind::PyObjectType; + // global singleton + static PyObjectTypePtr get(); +private: + PyObjectType() + : Type(TypeKind::PyObjectType) {} +}; + +enum class TypeVerbosity { + None, + Type, + TypeAndStride, + Full, + Symbolic, + Default = Full, +}; + +TORCH_API TypeVerbosity type_verbosity(); + +TORCH_API std::ostream& operator<<(std::ostream& out, const Type& t); +template +TORCH_API std::ostream& operator<<( + std::ostream& out, + const VaryingShape& t); +TORCH_API std::ostream& operator<<(std::ostream& os, const SymbolicShape& s); +TORCH_API std::ostream& operator<<(std::ostream& os, const ShapeSymbol& s); +TORCH_API std::ostream& operator<<(std::ostream& os, const Stride& s); +// what is the type, ignoring extra size/shape information? +// e.g. Tensor(2x3) -> Dynamic, and Tuple(Tensor(2x3),...) -> Tuple(Dynamic,...) + +// `unshapedType` is used to remove Tensor subtypes. We treat all Tensor +// subtypes as simply "Tensor"; we also create a new version of any +// container types in which internal Tensors have undergone the same +// operation. This is used for type comparisons between two Tensor types +// (`unshapedType` means that we don't falsely return `false` for e.g. +// Tensors of different dimensions). It's also used in the alias +// analysis pass. +// Be careful with calls because this can be very slow. If calling this +// on a graph, use `EraseShapeInformation` in shape_analysis.h +inline TypePtr unshapedType(const TypePtr& type) { + if (type->isSubtypeOf(*TensorType::get())) { + return TensorType::get(); + } + at::ArrayRef contained = type->containedTypes(); + if (contained.empty()) { + return type; + } + return type->withContained(fmap(type->containedTypes(), unshapedType)); +} + +inline TypePtr TensorType::fromNumberType(const Type& typ) { + if (typ.isSubtypeOf(*IntType::get())) { + return TensorType::createContiguous(at::kLong, at::kCPU, {}); + } else if (typ.isSubtypeOf(*FloatType::get())) { + return TensorType::createContiguous(at::kDouble, at::kCPU, {}); + } else if (typ.isSubtypeOf(*BoolType::get())) { + return TensorType::createContiguous(at::kBool, at::kCPU, {}); + } else if (typ.kind() == NumberType::Kind) { + return TensorType::create(std::nullopt, at::kCPU, {}, std::nullopt); + } + TORCH_CHECK(false, "Unknown number type: ", typ.str()); +} +inline TypePtr TensorType::fromBoolType() { + return TensorType::createContiguous(at::kBool, at::kCPU, {}); +} + +inline std::optional tryScalarTypeFromJitType(const Type& type) { + if (type == *FloatType::get()) { + return at::typeMetaToScalarType(c10::get_default_dtype()); + } else if (type == *IntType::get()) { + return at::ScalarType::Long; + } else if (type == *BoolType::get()) { + return at::ScalarType::Bool; + } + return std::nullopt; +} + +inline at::ScalarType scalarTypeFromJitType(const Type& type) { + auto result = tryScalarTypeFromJitType(type); + TORCH_CHECK( + result, + "Add new condition, expected Float, Complex, Int, or Bool but got", + type.str()); + return *result; +} + +// Attempt to find the correct supertype of the two types `t1` and `t2`. +// If no supertype is found, then nullopt will be returned if +// `default_to_union` is false, and `Union[t1, t2]` will be returned +// if it is true. If `t1 == t2`, or `t1` is a type refinement of `t2`, +// then `t2` will be returned (and vice versa). +// +// Two different tensortypes will return dynamic. +// +// Currently we chose not to support returning a NumberType for +// two types from the set of {FloatType, IntType, ComplexType}, because +// there is a lack of operator support for NumberType. +// +// If `type_hint` is an `InterfaceType`, then we can use that as a +// potential supertype for `ClassType`s in the list. Otherwise, we have +// no way to find and use some common interface type +TORCH_API std::optional unifyTypes( + const TypePtr& t1, + const TypePtr& t2, + bool default_to_union = false, + const TypePtr& type_hint = nullptr); + +TORCH_API std::optional unifyTypeList( + at::ArrayRef elements, + std::ostream& why_not, + bool default_to_union = false, + const TypePtr& type_hint = nullptr); + +namespace detail { +template +struct getTypePtr_ final { + static decltype(auto) call() { + return ([]() { + try { + return getCustomClassType(); + } catch(const c10::Error&) { + TORCH_CHECK( + false, + "Type ", + c10::util::get_fully_qualified_type_name(), + " could not be converted to any of the known types." + ); + } + }()); + } +}; + +template +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return getTypePtr_::call(); + } +}; + +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return AnyType::get(); + } +}; + +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return TensorType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return StorageType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return StreamObjType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return FloatType::get(); + } +}; +template <> +struct getTypePtr_> final { + static decltype(auto) call() { + return ComplexType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return IntType::get(); + } +}; + +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return IntType::get(); + } +}; + +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return SymIntType::get(); + } +}; +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return IntType::get(); + } +}; + +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return SymFloatType::get(); + } +}; +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return FloatType::get(); + } +}; + +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return SymBoolType::get(); + } +}; +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return BoolType::get(); + } +}; + +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return DeviceObjType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return BoolType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return NumberType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return QSchemeType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return TypeFactory::create( + TypeFactory::get()); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return StringType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return StringType::get(); + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return StringType::get(); + } +}; +template +struct getMaybeFakeTypePtr_, fake> final { + static const auto& call() { + static auto inner_type = getMaybeFakeTypePtr_::call(); + // The "per vector" static singleton needs to live in a .cpp file, + // otherwise we'll end up with one singleton instance per shared library. + static auto type = ListType::get("vector", inner_type); + return type; + } +}; +template +struct getMaybeFakeTypePtr_, fake> final { + static const auto& call() { + static auto inner_type = getMaybeFakeTypePtr_::call(); + // The "per ArrayRef" static singleton needs to live in a .cpp file, + // otherwise we'll end up with one singleton instance per shared library. + static auto type = ListType::get("ArrayRef", inner_type); + return type; + } +}; +template +struct getMaybeFakeTypePtr_ final { + static const auto& call() { + static auto type = ListType::create(getMaybeFakeTypePtr_::call()); + return type; + } +}; +template +struct getMaybeFakeTypePtr_, fake> final { + static const auto& call() { + static auto inner_type = getMaybeFakeTypePtr_::call(); + // The "per List" static singleton needs to live in a .cpp file, + // otherwise we'll end up with one singleton instance per shared library. + static auto type = ListType::get("List", inner_type); + return type; + } +}; +template +struct getMaybeFakeTypePtr_, fake> final { + static const auto& call() { + static auto inner_type = getMaybeFakeTypePtr_::call(); + static auto type = ListType::get("List", inner_type); + return type; + } +}; +template +struct getMaybeFakeTypePtr_, fake> final { + static const auto& call() { + static auto inner_type = getMaybeFakeTypePtr_::call(); + // The "per array" static singleton needs to live in a .cpp file, + // otherwise we'll end up with one singleton instance per shared library. + // (Concatenating the length onto the end of the string because we want a unique + // type_ptr created for every std::array type). + static auto type = ListType::get(std::string("array") + std::to_string(N), inner_type); + return type; + } +}; +template +struct getMaybeFakeTypePtr_, fake> final { + static const auto& call() { + static auto inner_key_type = getMaybeFakeTypePtr_::call(); + static auto inner_val_type = getMaybeFakeTypePtr_::call(); + // The "per unordered_map" static singleton needs to live in a .cpp file, + // otherwise we'll end up with one singleton instance per shared library. + static auto type = DictType::get("unordered_map", inner_key_type, inner_val_type); + return type; + } +}; +template +struct getMaybeFakeTypePtr_, fake> final { + static const auto& call() { + static auto inner_key_type = getMaybeFakeTypePtr_::call(); + static auto inner_val_type = getMaybeFakeTypePtr_::call(); + // The "per Dict" static singleton needs to live in a .cpp file, + // otherwise we'll end up with one singleton instance per shared library. + static auto type = DictType::get("Dict", inner_key_type, inner_val_type); + return type; + } +}; + +template +struct getMaybeFakeTypePtr_, fake> final { + static const auto& call() { + static auto inner_type = getMaybeFakeTypePtr_::call(); + // The "per std::optional" static singleton needs to live in a .cpp file, + // otherwise we'll end up with one singleton instance per shared library. + static auto type = OptionalType::get(inner_type); + return type; + } +}; + + +template<> +struct getTypePtr_ final { + static const auto& call() { + static auto inner_type = getMaybeFakeTypePtr_::call(); + // The "per std::optional" static singleton needs to live in a .cpp file, + // otherwise we'll end up with one singleton instance per shared library. + static auto type = OptionalType::get(inner_type); + return type; + } +}; + +template +struct getMaybeFakeTypePtr_ final { + static const auto& call() { + // The "per std::optional" static singleton needs to live in a .cpp file, + // otherwise we'll end up with one singleton instance per shared library. + static auto inner_type = getMaybeFakeTypePtr_::call(); + static auto type = OptionalType::get(inner_type); + return type; + } +}; + +template +struct getMaybeFakeTypePtr_, fake> final { + static const auto& call() { + static auto type = ([]() { + std::vector contained_types = { + (getMaybeFakeTypePtr_::call())... + }; + return TupleType::create(std::move(contained_types)); + })(); + return type; + } +}; +template <> +struct getTypePtr_ final { + static decltype(auto) call() { + return NoneType::get(); + } +}; +} // namespace detail +template +inline decltype(auto) getTypePtr() { + // TODO: static_assert that a templated function exists, and throw a friendly + // error message if not + return detail::getMaybeFakeTypePtr_::call(); +} + +template +inline TypePtr getTypePtrCopy() { + // TODO: static_assert that a templated function exists, and throw a friendly + // error message if not + return getTypePtr(); +} + +template +inline decltype(auto) getFakeTypePtr() { + return detail::getMaybeFakeTypePtr_::call(); +} + +template +inline TypePtr getFakeTypePtrCopy() { + return getFakeTypePtr(); +} + +using TypeEnv = std::unordered_map; +struct MatchTypeReturn { + MatchTypeReturn(std::string reason) : reason_(std::move(reason)) {} + static MatchTypeReturn Success() { + return MatchTypeReturn(); + } + bool success() const { + return !reason_.has_value(); + } + const std::string& reason() const { + // NOLINTNEXTLINE(bugprone-unchecked-optional-access) + return reason_.value(); + } + + private: + MatchTypeReturn() + : reason_(std::nullopt) {} + std::optional reason_; // is there is no match, this contains the reason +}; + +// attempt to match the type variables in formal to actual, adding them to type_env. +// If no match is possible this returns a MatchTypeReturn with r.success() == false +// and a r.reason() that describes why it could not match. +// note: It is possible to successfully match a formal, but for type variables +// in the formal to still not be defined. In particular, None matches Optional[T] +// but does not define the value of T. +TORCH_API MatchTypeReturn +matchTypeVariables(const TypePtr& formal, const TypePtr& actual, TypeEnv& type_env); + +// replace type variables appearing in `type` with the values in +// `type_env`. Returns nullptr if a variable used in `type` +// does not appear in `type_env` +TORCH_API TypePtr tryEvalTypeVariables(const TypePtr& type, TypeEnv& type_env); + +TORCH_API bool elementTypeCanBeInferredFromMembers(const TypePtr& elem_type); + +struct InterfaceType; +using InterfaceTypePtr = std::shared_ptr; + +// Interfaces are a list of abstract methods that a class might meet. +// If a class provides those methods, it implicitly meets the interface. + +// Subtype relations for Interface with ClassType: +// lhs (ClassType or InterfaceType) is a subtype of rhs if: +// 1. lhs methods are a superset of rhs methods +// 2. if rhs is module interface, the lhs must be module interface or module itself +struct TORCH_API InterfaceType : public NamedType { + static InterfaceTypePtr create( + QualifiedName qualifiedName, bool is_module=false); + + bool equals(const Type& rhs) const override { + if (auto user_rhs = rhs.castRaw()) { + return isSubTypeImpl(*this, *user_rhs, nullptr) && + isSubTypeImpl(*user_rhs, *this, nullptr); + } + return false; + } + + std::string str() const override { + // NOLINTNEXTLINE(bugprone-unchecked-optional-access) + return std::string("InterfaceType<") + name()->name() + ">"; + } + + bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const override; + + // try to find a method of this interface, + // returns nullptr if not found. + const FunctionSchema* getMethod(const std::string& name) const; + void addMethod(FunctionSchema schema); + const std::vector& methods() const { + return *methods_; + } + + bool is_module() const override{ + return is_module_; + } + static const TypeKind Kind = TypeKind::InterfaceType; + ~InterfaceType() override = default; + private: + InterfaceType(QualifiedName name, bool is_module); + static bool isSubTypeImpl( + const InterfaceType& lhs, + const InterfaceType& rhs, + std::ostream* why_not); + + std::string annotation_str_impl( + [[maybe_unused]] const TypePrinter& printer = nullptr) const override { + // NOLINTNEXTLINE(bugprone-unchecked-optional-access) + return name()->qualifiedName(); + } + + // shared_ptr so that this header does not have to depend on + // FunctionSchema.h + std::shared_ptr> methods_; + // flag to distinguish if it's an interface type from a module or not + bool is_module_; +}; + +template +struct EnumerationType : public Type { +static const TypeKind Kind = K; + +bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); +} + +protected: +EnumerationType() : Type(Kind) {} +}; + +// WARNING: These enumeration types below DO NOT actually get parsed out +// from the logical schema strings, instead they are mapped as ints. To +// observe these types, use real_type() instead of type() on Argument + +struct ScalarTypeType; +using ScalarTypeTypePtr = SingletonTypePtr; +struct TORCH_API ScalarTypeType : public EnumerationType { +std::string str() const override { +return "ScalarType"; +} +static const TypeKind Kind = TypeKind::ScalarTypeType; +// global singleton +static ScalarTypeTypePtr get(); + +private: +ScalarTypeType() {} +}; + +struct MemoryFormatType; +using MemoryFormatTypePtr = SingletonTypePtr; +struct TORCH_API MemoryFormatType : public EnumerationType { +std::string str() const override { +return "MemoryFormat"; +} +static const TypeKind Kind = TypeKind::MemoryFormatType; +// global singleton +static MemoryFormatTypePtr get(); + +private: +MemoryFormatType() {} +}; + +struct LayoutType; +using LayoutTypePtr = SingletonTypePtr; +struct TORCH_API LayoutType : public EnumerationType { +std::string str() const override { +return "Layout"; +} +static const TypeKind Kind = TypeKind::LayoutType; +// global singleton +static LayoutTypePtr get(); + +private: +LayoutType() {} +}; + +namespace detail { +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return ScalarTypeType::get(); + } +}; +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return LayoutType::get(); + } +}; +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return MemoryFormatType::get(); + } +}; +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return IntType::get(); + } +}; +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return IntType::get(); + } +}; +template <> +struct getMaybeFakeTypePtr_ final { + static decltype(auto) call() { + return IntType::get(); + } +}; +} // namespace detail + +// the common supertype of all lists, +// List[T] <: AnyList for all T +struct AnyListType; +using AnyListTypePtr = SingletonTypePtr; +struct TORCH_API AnyListType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "list"; + } + static const TypeKind Kind = TypeKind::AnyListType; + // global singleton + static AnyListTypePtr get(); +private: + AnyListType() + : Type(TypeKind::AnyListType) {} +}; + +// the common supertype of all tuples, +// Tuple[T...] <: AnyTuple for all T +struct AnyTupleType; +using AnyTupleTypePtr = SingletonTypePtr; +struct TORCH_API AnyTupleType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + + std::string str() const override { + return "tuple"; + } + static const TypeKind Kind = TypeKind::AnyTupleType; + + // global singleton + static AnyTupleTypePtr get(); +private: + AnyTupleType() + : Type(TypeKind::AnyTupleType) {} +}; + +// the common supertype of all classes, +// ClassType <: AnyClassType for all classes +struct AnyClassType; +using AnyClassTypePtr = SingletonTypePtr; +struct TORCH_API AnyClassType : public Type { + bool equals(const Type& rhs) const override { + return rhs.kind() == kind(); + } + std::string str() const override { + return "AnyClassType"; + } + static const TypeKind Kind = TypeKind::AnyClassType; + // global singleton + static AnyClassTypePtr get(); +private: + AnyClassType() + : Type(TypeKind::AnyClassType) {} +}; + +template<> +inline typename detail::CastReturnType::type Type::cast() { + if (kind() == TypeKind::TupleType || kind() == TypeKind::FunctionType || + kind() == TypeKind::ClassType || kind() == TypeKind::InterfaceType) { + return std::static_pointer_cast(static_cast(this)->shared_from_this()); + } + return nullptr; +} + +template<> +inline typename detail::CastConstReturnType::type Type::cast() const { + if (kind() == TypeKind::TupleType || kind() == TypeKind::FunctionType || + kind() == TypeKind::ClassType || kind() == TypeKind::InterfaceType) { + return std::static_pointer_cast(static_cast(this)->shared_from_this()); + } + return nullptr; +} + +template<> +inline const NamedType* Type::castRaw() const { + if (kind() == TypeKind::TupleType || kind() == TypeKind::FunctionType || + kind() == TypeKind::ClassType || kind() == TypeKind::InterfaceType) { + return static_cast(this); + } + return nullptr; +} + +// Used as a return type when inferring the IValue type of a Python object. +struct InferredType { + /* implicit */ InferredType(TypePtr type) : type_(std::move(type)) {} + /* implicit */ InferredType(std::string reason) + : type_(nullptr), reason_(std::move(reason)) {} + TypePtr type() const { + TORCH_INTERNAL_ASSERT( + type_, + "Tried to get the type from an InferredType but the type is null. ", + "Reason: ", + reason_); + return type_; + } + bool success() const { + return type_ != nullptr; + } + const std::string& reason() const { + TORCH_INTERNAL_ASSERT(!type_); + return reason_; + } + +private: + TypePtr type_; + std::string reason_; +}; + +TORCH_API bool containsAnyType(const TypePtr& type); + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/jit_type_base.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/jit_type_base.h new file mode 100644 index 0000000000000000000000000000000000000000..de440787ee686ff274721fb74d1192b0a014cc17 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/jit_type_base.h @@ -0,0 +1,721 @@ +#pragma once + +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace c10 { + +#define C10_FORALL_TYPES(_) \ + _(AnyType) \ + _(EnumType) \ + _(AnyEnumType) \ + _(TensorType) \ + _(StorageType) \ + _(TupleType) \ + _(ListType) \ + _(DictType) \ + _(NumberType) \ + _(FloatType) \ + _(ComplexType) \ + _(FutureType) \ + _(AwaitType) \ + _(RRefType) \ + _(IntType) \ + _(NoneType) \ + _(StringType) \ + _(GeneratorType) \ + _(QuantizerType) \ + _(BoolType) \ + _(OptionalType) \ + _(VarType) \ + _(DeviceObjType) \ + _(StreamObjType) \ + _(FunctionType) \ + _(ClassType) \ + _(PyObjectType) \ + _(CapsuleType) \ + _(InterfaceType) \ + _(QSchemeType) \ + _(ScalarTypeType) \ + _(LayoutType) \ + _(MemoryFormatType) \ + _(AnyListType) \ + _(AnyTupleType) \ + _(AnyClassType) \ + _(SymIntType) \ + _(SymFloatType) \ + _(SymBoolType) \ + _(UnionType) \ + _(DynamicType) + +enum class TypeKind { +#define DEFINE_TYPE(T) T, + C10_FORALL_TYPES(DEFINE_TYPE) +#undef DEFINE_TYPE +}; + +TORCH_API const char* typeKindToString(TypeKind kind); + +struct Type; +struct SharedType; + +// Use this to customize how a Type is printed using `annotation_str()`. If +// std::nullopt is returned, `annotation_str()` falls through to its default +// implementation. +using TypePrinter = std::function(const Type&)>; + +namespace detail { +template +struct IsSingletonType : public std::integral_constant {}; +} // namespace detail +#define TORCH_DECLARE_SINGLETON(Type) \ + struct Type; \ + namespace detail { \ + template <> struct IsSingletonType : public std::integral_constant {}; \ + } + +TORCH_DECLARE_SINGLETON(AnyType) +TORCH_DECLARE_SINGLETON(AnyEnumType) +TORCH_DECLARE_SINGLETON(NumberType) +TORCH_DECLARE_SINGLETON(FloatType) +TORCH_DECLARE_SINGLETON(ComplexType) +TORCH_DECLARE_SINGLETON(IntType) +TORCH_DECLARE_SINGLETON(BoolType) +TORCH_DECLARE_SINGLETON(StringType) +TORCH_DECLARE_SINGLETON(StorageType) +TORCH_DECLARE_SINGLETON(NoneType) +TORCH_DECLARE_SINGLETON(GeneratorType) +TORCH_DECLARE_SINGLETON(QuantizerType) +TORCH_DECLARE_SINGLETON(QSchemeType) +TORCH_DECLARE_SINGLETON(DeviceObjType) +TORCH_DECLARE_SINGLETON(StreamObjType) +TORCH_DECLARE_SINGLETON(CapsuleType) +TORCH_DECLARE_SINGLETON(PyObjectType) +TORCH_DECLARE_SINGLETON(ScalarTypeType) +TORCH_DECLARE_SINGLETON(LayoutType) +TORCH_DECLARE_SINGLETON(MemoryFormatType) +TORCH_DECLARE_SINGLETON(AnyListType) +TORCH_DECLARE_SINGLETON(AnyTupleType) +TORCH_DECLARE_SINGLETON(AnyClassType) + +namespace detail { +template +struct CastReturnType { + using type = std::shared_ptr; +}; + +template +struct CastReturnType::value>> { + using type = SingletonTypePtr; +}; + +template +struct CastConstReturnType { + using type = std::shared_ptr; +}; + +template +struct CastConstReturnType::value>> { + using type = SingletonTypePtr; +}; + +template +struct as_shared_type { + using type = SharedType*; +}; + +template +struct as_shared_type { + using type = const SharedType *; +}; +} // namespace detail + +struct TORCH_API Type { + friend TORCH_API bool operator==(const Type& lhs, const Type& rhs); + private: + TypeKind kind_; + + protected: + Type(TypeKind kind) : kind_(kind) {} + + Type(const Type&) = default; + Type& operator=(const Type&) = default; + Type(Type&&) noexcept = default; + Type& operator=(Type&&) noexcept = default; + + virtual std::string annotation_str_impl(const TypePrinter& /*printer*/) const { + return str(); + } + // a == b + virtual bool equals(const Type& rhs) const = 0; + // a == b <=> b == a + virtual bool symmetric() const { + return true; + } + + public: + template + class SingletonOrSharedTypePtr { + public: + using element_type = typename std::shared_ptr::element_type; + + SingletonOrSharedTypePtr() = default; + + /* implicit */ SingletonOrSharedTypePtr(std::shared_ptr x) + : repr_(std::move(x)) {} + + template , bool> = true> + /* implicit */ SingletonOrSharedTypePtr(std::shared_ptr x) + : repr_(std::move(x)) {} + + /* implicit */ SingletonOrSharedTypePtr(std::nullptr_t) + : repr_(nullptr) {} + + /* implicit */ SingletonOrSharedTypePtr(SingletonTypePtr p) + : repr_(p) {} + + template , bool> = true> + /* implicit */ SingletonOrSharedTypePtr(SingletonTypePtr p) + : repr_(SingletonTypePtr(p.get())) {} + + + // We need to support construction from T* for pybind. The problem + // is that it's not clear if we are supposed to be taking shared + // ownership or not. + // + // Case 1: if T is known statically to derive from SharedType, we should use + // shared_from_this() and take shared_ownership. + // + // Case 2: if T is exactly Type, we need to do a dynamic_cast to + // check if it's a SharedType and do the right thing. + // + // Case 3: Otherwise, T is not a SharedType. (debug-check this + // assumption!) Use a singleton pointer. + + template , bool> = true> + /* implicit */ SingletonOrSharedTypePtr(T* p) : SingletonOrSharedTypePtr(static_cast::type>(p)->shared_from_this()) {} + + template , bool> = true> + /* implicit */ SingletonOrSharedTypePtr(T* p) { + if (auto* shared_p = dynamic_cast::type>(p)) { + repr_ = Repr(shared_p->shared_from_this()); + } else { + repr_ = Repr(p); + } + } + + template && !std::is_base_of_v, bool> = true> + /* implicit */ SingletonOrSharedTypePtr(T* p) + : repr_(p) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(dynamic_cast::type>(p) == nullptr); + } + + SingletonOrSharedTypePtr(const SingletonOrSharedTypePtr&) = default; + SingletonOrSharedTypePtr(SingletonOrSharedTypePtr&&) noexcept = default; + SingletonOrSharedTypePtr& operator=(const SingletonOrSharedTypePtr&) = default; + SingletonOrSharedTypePtr& operator=(SingletonOrSharedTypePtr&&) noexcept = default; + ~SingletonOrSharedTypePtr() = default; + + T* get() const { + return repr_.isSharedAndNonNull() ? repr_.shared_.repr_.get() : static_cast(repr_.rawRepr().first); + } + + operator bool() const { + return repr_.isNonNull(); + } + + bool operator==(std::nullptr_t) const { + return !repr_.isNonNull(); + } + + bool operator!=(std::nullptr_t) const { + return repr_.isNonNull(); + } + + template , void>, bool> = true> + U& operator*() const { + return *get(); + } + + T* operator->() const { + return get(); + } + + private: + // NOTE: SharedPtrWrapper exists to work around a baffling bug in + // nvcc; see comment in destroy() below. + struct SharedPtrWrapper { + SharedPtrWrapper(std::shared_ptr &&x) + : repr_(std::move(x)) {} + std::shared_ptr repr_; + }; + union Repr { + Repr() : Repr(nullptr) {} + + explicit Repr(std::shared_ptr x) + : shared_(std::move(x)) {} + + explicit Repr(std::nullptr_t) + : singletonRepr_(nullptr) {} + + explicit Repr(SingletonTypePtr p) + : singletonRepr_(p.get()) {} + + ~Repr() { + destroy(); + } + + // NOTE: the only non-UB way to access our null state is through + // rawRepr(), because our copy operation doesn't preserve which + // union member is active for null pointers. + Repr(const Repr& rhs) { + if (rhs.isSharedAndNonNull()) { + new (&shared_) SharedPtrWrapper(rhs.shared_); + } else { + singletonRepr_.singleton_ = static_cast(rhs.rawRepr().first); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(rhs.singletonRepr_.unused_ == nullptr); + singletonRepr_.unused_ = nullptr; + } + } + + Repr(Repr&& rhs) noexcept { + if (rhs.isSharedAndNonNull()) { + new (&shared_) SharedPtrWrapper(std::move(rhs.shared_)); + } else { + singletonRepr_.singleton_ = static_cast(rhs.rawRepr().first); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(rhs.singletonRepr_.unused_ == nullptr); + singletonRepr_.unused_ = nullptr; + } + } + + Repr& operator=(const Repr& rhs) { + if (&rhs == this) { + return *this; + } + if (rhs.isSharedAndNonNull()) { + if (isSharedAndNonNull()) { + shared_ = rhs.shared_; + } else { + new (&shared_) SharedPtrWrapper(rhs.shared_); + } + } else { + if (isSharedAndNonNull()) { + destroy(); + } + singletonRepr_.singleton_ = static_cast(rhs.rawRepr().first); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(rhs.rawRepr().nullIfSingleton_ == nullptr); + singletonRepr_.unused_ = nullptr; + } + return *this; + } + + Repr& operator=(Repr&& rhs) noexcept { + if (&rhs == this) { + return *this; + } + if (rhs.isSharedAndNonNull()) { + if (isSharedAndNonNull()) { + shared_ = std::move(rhs.shared_); + } else { + new (&shared_) SharedPtrWrapper(std::move(rhs.shared_)); + } + } else { + if (isSharedAndNonNull()) { + destroy(); + } + singletonRepr_.singleton_ = static_cast(rhs.rawRepr().first); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(rhs.rawRepr().nullIfSingleton_ == nullptr); + singletonRepr_.unused_ = nullptr; + } + return *this; + } + + SharedPtrWrapper shared_; + + struct SingletonRepr { + explicit SingletonRepr(T* s) : singleton_(s) {} + T* singleton_; + void* unused_ = nullptr; + } singletonRepr_; + struct RawRepr { + void* first; + void* nullIfSingleton_; + }; + + // It is UB to read the singleton part of Repr if it was + // constructed as a shared_ptr and vice versa, but memcpying out + // the representation is always OK, so here's an accessor to obey + // the letter of the law. + RawRepr rawRepr() const { + RawRepr repr{}; + memcpy(&repr, reinterpret_cast(this), sizeof(RawRepr)); + return repr; + } + + bool isNonNull() const { + auto repr = rawRepr(); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(repr.nullIfSingleton_ == nullptr || repr.first != nullptr); + return repr.first != nullptr; + } + + bool isSharedAndNonNull() const { + return rawRepr().nullIfSingleton_ != nullptr; + } + + private: + void destroy() { + if (isSharedAndNonNull()) { + // Without SharedPtrWrapper, this line would read + // `shared_.~shared_ptr()` and nvcc would complain with + // "error: expected primary-expression before '>' token" + // referring to the "t" in "shared_ptr". SharedPtrWrapper + // exists to work around this compiler bug. + shared_.~SharedPtrWrapper(); + } + } + } repr_; + }; + + using TypePtr = SingletonOrSharedTypePtr; + using Ptr = TypePtr; + using ElementType = Type; + + // subtyping relation. By default, we return true for the case + // when the type is exactly equal or if this <: T where rhs = Optional[T] + + // if this returns false and the why_not stream is non-null, it contains + // additional details that describe why this is not a subtype of 'rhs'. + // This additional information should only contain details that are not + // obvious from the annotation_str() that describes the type. For instance it + // is clear that `int <: str` is false but not clear why `Foo <: InterfaceBar` + // might be false. + virtual bool isSubtypeOfExt(const Type& rhs, std::ostream* why_not) const; + virtual bool is_module() const; + bool isSubtypeOf(const Type& rhs) const { + return isSubtypeOfExt(rhs, nullptr); + } + // Compatibility shims to accommodate existing code that passes shared_ptrs + // around. Ideally, we would just delete this, but it should be harmless. + template + std::enable_if_t, bool> + isSubtypeOf(const std::shared_ptr& rhs) const { + return isSubtypeOf(*rhs); + } + + template + std::enable_if_t, bool> + isSubtypeOf(const SingletonOrSharedTypePtr& rhs) const { + return isSubtypeOf(*rhs); + } + + template + std::enable_if_t, bool> + isSubtypeOf(SingletonTypePtr rhs) const { + return isSubtypeOf(*rhs); + } + + template + std::enable_if_t, bool> + isSubtypeOfExt(const SingletonOrSharedTypePtr& rhs, std::ostream* why_not) const { + return isSubtypeOfExt(*rhs, why_not); + } + + template + std::enable_if_t, bool> + isSubtypeOfExt(const std::shared_ptr& rhs, std::ostream* why_not) const { + return isSubtypeOfExt(*rhs, why_not); + } + + template + std::enable_if_t, bool> + isSubtypeOfExt(SingletonTypePtr rhs, std::ostream* why_not) const { + return isSubtypeOfExt(*rhs, why_not); + } + + // How this type will appear in FunctionSchema declarations + virtual std::string str() const = 0; + + // How this type will appear as if it were a type annotation in Python + // which is sometimes different than how it appears in declarations (e.g. + // int[] vs List[int]) + // + // Takes a custom printer that users can pass in to customize the output of + // this method. + std::string annotation_str(const TypePrinter& printer) const { + if (printer) { + // the printer can return std::nullopt to fall through to the default impl + if (auto renamed = printer(*this)) { + return *renamed; + } + } + return annotation_str_impl(printer); + } + std::string annotation_str() const { + // Overload instead of define a default value for `printer` to help + // debuggers out. + return annotation_str(nullptr); + } + + // Returns a human readable string that includes additional information like + // "type is inferred rather than explicitly defined" to help construct more + // user-friendly messages. + virtual std::string repr_str() const { + return annotation_str(); + } + + TypeKind kind() const { + return kind_; + } + + virtual bool isUnionType() const { + return false; + } + + virtual bool requires_grad() const { + for (const auto& ct : containedTypes()) { + if (ct->requires_grad()) { + return true; + } + } + return false; + } + + // Dynamically cast this object to the subclass indicated by the + // template variable, returning nullptr if the cast is invalid. + template ::value, bool> = true> + typename detail::CastReturnType::type cast() { + if (T::Kind == kind()) { + return std::static_pointer_cast(static_cast(this)->shared_from_this()); + } + return nullptr; + } + template ::value, bool> = true> + typename detail::CastReturnType::type cast() { + if (T::Kind == kind()) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(this == T::get().get()); + return typename detail::CastReturnType::type(static_cast(this)); + } + return nullptr; + } + template ::value, bool> = true> + typename detail::CastConstReturnType::type cast() const { + if (T::Kind == kind()) { + return std::static_pointer_cast(static_cast(this)->shared_from_this()); + } + return nullptr; + } + template ::value, bool> = true> + typename detail::CastConstReturnType::type cast() const { + if (T::Kind == kind()) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(this == T::get().get()); + return typename detail::CastConstReturnType::type(static_cast(this)); + } + return nullptr; + } + template + T* castRaw() { + if (T::Kind == kind()) { + return static_cast(this); + } + return nullptr; + } + template + const T* castRaw() const { + if (T::Kind == kind()) { + return static_cast(this); + } + return nullptr; + } + template + auto expect() { + auto r = cast(); + AT_ASSERT(r); + return r; + } + template + auto expect() const { + auto r = cast(); + AT_ASSERT(r); + return r; + } + template + T& expectRef() { + auto* r = castRaw(); + AT_ASSERT(r); + return *r; + } + template + const T& expectRef() const { + auto* r = castRaw(); + AT_ASSERT(r); + return *r; + } + virtual ~Type() = default; + virtual bool hasFreeVariables() const { + return false; + } + // list of types this type contains, e.g. for a List then element type of a + // list for a tuple, the types of the tuple elements + virtual at::ArrayRef containedTypes() const { + return {}; + } + virtual TypePtr containedType(size_t i) const { + return containedTypes().at(i); + } + virtual size_t containedTypeSize() const { + return containedTypes().size(); + } + // create a new version of this type, replacing its contained types with + // contained_types + TypePtr withContained(std::vector contained_types); + // per-type constructor, you only need to override this if the + // containedTypes() is not empty + virtual TypePtr createWithContained( + // NOLINTNEXTLINE(performance-unnecessary-value-param) + std::vector /*contained_types*/) const { + TORCH_CHECK(false, + "type with contained types did not overload createWithContained: ", + str()); + } + +}; + +template +using SingletonOrSharedTypePtr = Type::SingletonOrSharedTypePtr; + + +template +bool operator==(const SingletonOrSharedTypePtr& x, const SingletonOrSharedTypePtr& y) { + return (void*)x.get() == (void*)y.get(); +} + +template +bool operator==(const SingletonOrSharedTypePtr& x, const std::shared_ptr& y) { + return (void*)x.get() == (void*)y.get(); +} + +template +bool operator==(const std::shared_ptr& x, const SingletonOrSharedTypePtr& y) { + return (void*)x.get() == (void*)y.get(); +} + +template +bool operator==(const SingletonOrSharedTypePtr& x, const SingletonTypePtr& y) { + return (void*)x.get() == (void*)y.get(); +} + +template +bool operator==(const SingletonTypePtr& x, const SingletonOrSharedTypePtr& y) { + return (void*)x.get() == (void*)y.get(); +} + +template +bool operator!=(const SingletonOrSharedTypePtr& x, const SingletonOrSharedTypePtr& y) { + return !(x == y); +} + +template +bool operator!=(const SingletonOrSharedTypePtr& x, const std::shared_ptr& y) { + return !(x == y); +} + +template +bool operator!=(const std::shared_ptr& x, const SingletonOrSharedTypePtr& y) { + return !(x == y); +} + +template +bool operator!=(const SingletonOrSharedTypePtr& x, const SingletonTypePtr& y) { + return !(x == y); +} + +template +bool operator!=(const SingletonTypePtr& x, const SingletonOrSharedTypePtr& y) { + return !(x == y); +} + +using TypePtr = SingletonOrSharedTypePtr; +using ConstTypePtr = SingletonOrSharedTypePtr; + +// Explicitly enable MaybeOwned>, rather than allowing +// MaybeOwned to be used for any type right away. +template +struct MaybeOwnedTraits> + : public MaybeOwnedTraitsGenericImpl> {}; + +// Base class for Types that are guaranteed to be owned by std::shared_ptr. +struct TORCH_API SharedType : public Type, public std::enable_shared_from_this { + using Type::Type; +}; + +inline TypePtr Type::withContained(std::vector contained_types) { + auto current_contained = containedTypes(); + // Types with no contained_types don't need this call. Check before calling! + // + // (We can't support this efficiently because types without + // contained types may be singletons, in which case + // shared_from_this will crash; we would have to provide a virtual + // typeptr_from_this or isSingleton.) + TORCH_INTERNAL_ASSERT(!current_contained.empty() && current_contained.size() == contained_types.size()); + if (current_contained.equals(contained_types)) { + return std::static_pointer_cast(static_cast(this)->shared_from_this()); + } + return createWithContained(std::move(contained_types)); +} + + +TORCH_API inline bool operator==(const Type& lhs, const Type& rhs) { + if (C10_UNLIKELY(!rhs.symmetric())) { + return rhs.equals(lhs); + } + return lhs.equals(rhs); +} + +struct NamedType; +using NamedTypePtr = std::shared_ptr; +using ConstNamedTypePtr = std::shared_ptr; + +struct TORCH_API NamedType : public SharedType { + NamedType(TypeKind tk, std::optional name) + : SharedType(tk), name_(std::move(name)) { + TORCH_INTERNAL_ASSERT( + tk == TypeKind::TupleType || tk == TypeKind::FunctionType || + tk == TypeKind::ClassType || tk == TypeKind::InterfaceType || + tk == TypeKind::EnumType, + "If you add a new kind of NamedType, ", + "please update the cast specialization and this assert"); + } + + // Fully qualified name of type + // Looks like: "foo.bar.Baz". + const std::optional& name() const { + return name_; + } + + private: + std::optional name_; +}; + +} // namespace c10 + +namespace std { +template +struct hash> { + size_t operator()(const c10::SingletonOrSharedTypePtr& x) const { + return std::hash()(x.get()); + } +}; +} // namespace std diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/adaption.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/adaption.h new file mode 100644 index 0000000000000000000000000000000000000000..89ed8a419a03e771a6f35ac7dbbc47e29c99b852 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/adaption.h @@ -0,0 +1,81 @@ +#pragma once + +#include +#include +#include +#include + +/* + * [Note: hacky wrapper removal for optional tensor] + * + * The kernel implementation takes an optional tensor marked in the schema as + * Tensor? but the C++ function takes Tensor instead of the std::optional + * expected by the dispatcher. + * + * To remove the hacky wrapper, the C++ function is changed to take + * std::optional and unwrap the Tensor value at the beginning of + * the function, e.g.: + * > c10::MaybeOwned weight_maybe_owned = + * > at::borrow_from_optional_tensor(weight_opt); + * > const Tensor& weight = *weight_maybe_owned; + * + * We may want to make the kernel handle optional directly without + * going through the creation of a default-constructed Tensor in + * at::borrow_from_optional_tensor. + */ + +/* + * [Note: hacky wrapper removal for TensorOptions] + * + * The kernel implementation takes a TensorOptions argument but the dispatcher + * expects separate arguments for dtype, layout, device, pin_memory. + * + * To remove the hacky wrapper, the kernel implementation is changed to take + * the 4 arguments (dtype, layout, device, pin_memory), and assemble the + * TensorOptions value at the beginning of the function, e.g.: + * > TensorOptions options = TensorOptions().dtype(dtype).layout(layout) + * > .device(device).pinned_memory(pin_memory); + * + * We may want make the kernel handle these parameters directly without going + * through the creation of a TensorOptions value. + */ + +namespace c10::impl { + +TORCH_API void common_device_check_failure(Device common_device, const at::Tensor& tensor, at::CheckedFrom methodName, at::CheckedFrom argName); + +inline void check_and_update_common_device(std::optional& common_device, const at::Tensor& tensor, at::CheckedFrom methodName, at::CheckedFrom argName) { + // TODO: Remove this once the following issue is addressed: + // https://github.com/pytorch/pytorch/issues/57380 + if (!tensor.defined()) { + return; + } + + if (!common_device.has_value()) { + common_device = tensor.device(); + return; + } + + if (C10_UNLIKELY(common_device != tensor.device())) { + common_device_check_failure(*common_device, tensor, methodName, argName); + } +} + +inline void check_and_update_common_device(std::optional& common_device, const std::optional& tensor, at::CheckedFrom methodName, at::CheckedFrom argName) { + if (tensor.has_value()) { + check_and_update_common_device(common_device, tensor.value(), methodName, argName); + } +} + +inline void check_and_update_common_device(std::optional& common_device, at::ITensorListRef tensors, at::CheckedFrom methodName, at::CheckedFrom argName) { + for (const auto& tensor : tensors) { + check_and_update_common_device(common_device, tensor, methodName, argName); + } +} + +inline void check_and_update_common_device(std::optional& common_device, const List>& tensors, at::CheckedFrom methodName, at::CheckedFrom argName) { + for (const auto& tensor : tensors) { + check_and_update_common_device(common_device, tensor, methodName, argName); + } +} +} // namespace c10::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/infer_schema.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/infer_schema.h new file mode 100644 index 0000000000000000000000000000000000000000..a393e0290458c7bcf2bce653d19ebe1ccf8a38c6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/infer_schema.h @@ -0,0 +1,157 @@ +#pragma once + +/** + * This file contains functionality to take a C++ function and infer its + * c10::FunctionSchema. + */ + +#include +#include + +namespace c10 { +namespace detail::infer_schema { + +/// The templated inference code creates `ArgumentDef` instead of `Argument`, +/// because that can be constructed at compile time and has a much smaller +/// binary size than having calls to `Argument` constructors in the template. +/// Creating `Argument` objects from `ArgumentDef` can then be done at +/// runtime in a non-templated way. +struct ArgumentDef final { + using GetTypeFn = TypePtr(); + GetTypeFn* getTypeFn; + GetTypeFn* getFakeTypeFn; + constexpr ArgumentDef(): getTypeFn(nullptr), getFakeTypeFn(nullptr) {} + explicit constexpr ArgumentDef(GetTypeFn *getTypeFn, GetTypeFn *getFakeTypeFn): getTypeFn(getTypeFn), getFakeTypeFn(getFakeTypeFn) {} +}; + +template +struct bool_t {}; +template<> struct bool_t : std::true_type {}; +template<> struct bool_t : std::false_type {}; + +/// Checks the static C++ types `Types` for correctness to catch common error cases. +template +constexpr int checkStaticTypes() { + // Give nice error messages for some of the common error cases. + // Use a LOUD ERROR MESSAGE SO USERS SEE THE STATIC_ASSERT + static_assert(std::conjunction_v< + bool_t || std::is_same_v || std::is_same_v || std::is_same_v>... + >, "INVALID TYPE: Only int8_t, int64_t and bool are supported as an integral argument type"); + static_assert(std::conjunction_v< + bool_t>... + >, "INVALID TYPE: float is not supported as an argument type, use double instead"); + return 0; +} + +template +constexpr std::array createArgumentVectorFromTypes(std::index_sequence) { + return ( + // Check types for common errors + checkStaticTypes(), + + // Create the return value + std::array{ + ArgumentDef(&getTypePtrCopy>, &getFakeTypePtrCopy>)...} + ); +} + +/// Creates a vector of `ArgumentDef` from a list of C++ types that are specified +/// as template arguments. +template struct createArguments final {}; +template +struct createArguments> final { + static constexpr std::array call() { + return createArgumentVectorFromTypes( + std::make_index_sequence() + ); + } +}; + +/// Creates a vector of `ArgumentDef` from a list of C++ types that are specified +/// as a tuple (i.e. in the way c10 kernels return values). +/// It can be a tuple if there's three output arguments with types A, B, C. +/// It can be an empty tuple<>, or void for kernels that don't return anything. +/// It can be a single type A (i.e. no tuple) for the case where a kernel just +/// returns one value. +template struct createReturns final {}; + +template +struct createReturns, void> final { + static constexpr std::array call() { + return createArgumentVectorFromTypes( + std::make_index_sequence() + ); + } +}; + +template +struct createReturns && !guts::is_instantiation_of::value>> final { + static constexpr std::array call() { + return createReturns>::call(); + } +}; + +template<> +struct createReturns final { + static constexpr std::array call() { + return createReturns>::call(); + } +}; + +template +struct createSingleReturn { + static constexpr std::array call() { + return createArgumentVectorFromTypes(std::make_index_sequence<1>()); + } +}; + +TORCH_API FunctionSchema make_function_schema(std::string&& name, std::string&& overload_name, c10::ArrayRef arguments, c10::ArrayRef returns); +TORCH_API FunctionSchema make_function_schema(c10::ArrayRef arguments, c10::ArrayRef returns); + +/// Creates a `FunctionSchema` object from a `FunctionTraits` type for a +/// function. Flattens std::tuple returns into multiple return types +template +FunctionSchema createFunctionSchemaFromTraitsFlattenedReturns() { + using ReturnType = typename FunctionTraits::return_type; + using ParameterTypes = typename FunctionTraits::parameter_types; + + // arguments and returns are computed into a std::array at compile time and embedded into the binary. + // The only code executed at runtime here is the one that creates a std::vector + // of the arguments/returns from the std::array. + constexpr auto arguments = createArguments::call(); + constexpr auto returns = createReturns::call(); + + return make_function_schema(arguments, returns); +} + +/// Creates a `FunctionSchema` object from a `FunctionTraits` type for a +/// function. Preserves std::tuple returns as a Tuple return type +template +FunctionSchema createFunctionSchemaFromTraitsSingleReturn(std::string&& name, std::string&& overload_name) { + using ReturnType = typename FunctionTraits::return_type; + using ParameterTypes = typename FunctionTraits::parameter_types; + + // arguments and returns are computed into a std::array at compile time and embedded into the binary. + // The only code executed at runtime here is the one that creates a std::vector + // of the arguments/returns from the std::array. + constexpr auto arguments = createArguments::call(); + constexpr auto returns = createSingleReturn::call(); + + return make_function_schema(std::move(name), std::move(overload_name), arguments, returns); +} + +} + +template +FunctionSchema inferFunctionSchemaFlattenedReturns() { + return detail::infer_schema::createFunctionSchemaFromTraitsFlattenedReturns>(); +} + +template +FunctionSchema inferFunctionSchemaSingleReturn(std::string&& name, std::string&& overload_name) { + return detail::infer_schema::createFunctionSchemaFromTraitsSingleReturn>(std::move(name), std::move(overload_name)); +} + +TORCH_API std::optional findSchemaDifferences(const FunctionSchema& inferred, const FunctionSchema& specified); + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/op_allowlist.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/op_allowlist.h new file mode 100644 index 0000000000000000000000000000000000000000..3e8e03f9fa4c2581dd11cac83a81766cb936cb49 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/op_allowlist.h @@ -0,0 +1,181 @@ +#pragma once + +// TODO: unify to C10_MOBILE. In theory this header could be used in OSS. +#ifdef TEMPLATE_SELECTIVE_BUILD +#include +#endif + +/** + * This header implements functionality to build PyTorch with only a certain + * set of operators (+ dependencies) included. + * + * - Build with -DTORCH_OPERATOR_WHITELIST="aten::add;aten::sub" and only these + * two ops will be included in your build. The allowlist records operators + * only, no overloads; if you include aten::add, all overloads of aten::add + * will be included. + * + * Internally, this is done by removing the operator registration calls + * using compile time programming, and the linker will then prune all + * operator functions that weren't registered. + * See Note [Selective build] for more details + * + * WARNING: The allowlist mechanism doesn't work for all ways you could go about + * registering an operator. If the dispatch key / operator name is not + * sufficiently obvious at compile time, then the allowlisting mechanism + * will fail (and the operator will be included in the binary anyway). + */ + +#include +#include +#include + + +#if defined(ENABLE_RECORD_KERNEL_FUNCTION_DTYPE) +#include +#endif + +namespace c10::impl { + +constexpr bool allowlist_contains(std::string_view allowlist, std::string_view item); // Forward Declare + +/** + * In selective build mode returns true/false depending on whether a build + * feature is available or not. + * + * In instrumenting mode (tracing mode), always returns true, and doesn't + * trigger any side effects. + */ +constexpr bool is_build_feature_available(const char* name) { +#if !defined(ENABLE_RECORD_KERNEL_FUNCTION_DTYPE) + // Selective Build mode. +#if !defined(TORCH_BUILD_FEATURE_ALLOWLIST) + (void)name; + return true; +#else + return allowlist_contains( + C10_STRINGIZE(TORCH_BUILD_FEATURE_ALLOWLIST), + name); +#endif + +#else + // Instrumenting mode. + (void)name; + return true; +#endif +} + +[[noreturn]] void build_feature_required_feature_not_available(const char* feature); + +/** + * Use BUILD_FEATURE_REQUIRED macro in user-code. + * + * In selective build mode becomes a no-op if the build feature passed + * in is available. If not available, throws an exception (c10::Error). + * The compiler is able to perform dead code elimination for code + * following this method if the build feature is not available. + * + * In instrumenting mode (tracing mode), registers (as a side effect) + * the presence of this specific build feature being triggered. + */ +#if !defined(ENABLE_RECORD_KERNEL_FUNCTION_DTYPE) // selective build mode + +#if defined(TORCH_BUILD_FEATURE_ALLOWLIST) +#define BUILD_FEATURE_REQUIRED(NAME) \ + if (!c10::impl::is_build_feature_available(NAME)) { \ + ::c10::impl::build_feature_required_feature_not_available(NAME); \ + } +#else // Everything trivially selected +#define BUILD_FEATURE_REQUIRED(NAME) + +#endif + +#else // trace mode +#define BUILD_FEATURE_REQUIRED(NAME) \ + RECORD_FUNCTION_WITH_SCOPE( \ + at::RecordScope::BUILD_FEATURE, \ + std::string(NAME), \ + {}); +#endif + +// Use this macro, and not is_build_feature_available +#define BUILD_FEATURE_AVAILABLE(NAME) ::c10::impl::is_build_feature_available(NAME) + +// returns true iff allowlist contains item +// allowlist_contains("a;bc;d", "bc") == true +constexpr bool allowlist_contains(std::string_view allowlist, std::string_view item) { + //Choose a really big value for next so that if something goes wrong + //this code will blow up in a hopefully detectable way. + size_t next = std::numeric_limits::max(); + for (size_t cur = 0; cur <= allowlist.size(); cur = next) { + next = allowlist.find(';', cur); + if (next != std::string_view::npos) { + if (allowlist.substr(cur, next - cur) == item) { + return true; + } + next++; + } else { + if (allowlist.substr(cur).compare(item) == 0) { + return true; + } + break; + } + } + return false; +} + +// Returns true iff the given op name is on the allowlist +// and should be registered +constexpr bool op_allowlist_check(std::string_view op_name [[maybe_unused]]) { + assert(op_name.find("::") != std::string_view::npos); + // Use assert() instead of throw() due to a gcc bug. See: + // https://stackoverflow.com/questions/34280729/throw-in-constexpr-function + // https://github.com/fmtlib/fmt/issues/682 + assert(op_name.find('(') == std::string_view::npos); +#if !defined(TORCH_OPERATOR_WHITELIST) + // If the TORCH_OPERATOR_WHITELIST parameter is not defined, + // all ops are to be registered + return true; +#else + return allowlist_contains( + C10_STRINGIZE(TORCH_OPERATOR_WHITELIST), + // This function is majorly used for mobile selective build with + // root operators, where the overload is included in the allowlist. + op_name); + // // Strip overload name (as allowlist doesn't contain overloads) + // // Another function based on this may be added when there's usage + // // on op names without overload. + // OperatorNameView::parse(op_name).name); +#endif +} + +// Returns true iff the given schema string is on the allowlist +// and should be registered +constexpr bool schema_allowlist_check(std::string_view schema) { +#if defined(TORCH_FORCE_SCHEMA_REGISTRATION) + return true; +#else + return op_allowlist_check(schema.substr(0, schema.find('('))); +#endif +} + +// Returns true iff the given custom class name is on the allowlist +// and should be registered +constexpr bool custom_class_allowlist_check(std::string_view custom_class_name [[maybe_unused]]) { +#if !defined(TORCH_CUSTOM_CLASS_ALLOWLIST) + // If the TORCH_CUSTOM_CLASS_ALLOWLIST parameter is not defined, + // all custom classes are to be registered + return true; +#else + return allowlist_contains( + C10_STRINGIZE(TORCH_CUSTOM_CLASS_ALLOWLIST), + custom_class_name); +#endif +} + +// schema_allowlist_check() implicitly depends on a macro, TORCH_OPERATOR_WHITELIST. +// Add this API to pass arbitrary allowlist. +constexpr bool op_allowlist_contains_name_in_schema(std::string_view allowlist, std::string_view schema) { + return allowlist_contains(allowlist, schema.substr(0, schema.find('('))); +} + +} // namespace c10::impl diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/op_registration.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/op_registration.h new file mode 100644 index 0000000000000000000000000000000000000000..7a44cfa49b0781af282f818ef4b5b16bc690b99f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/op_registration/op_registration.h @@ -0,0 +1,596 @@ +#pragma once + +/** + * Include this file if you want to register operators. It includes all + * functionality needed to do so for you. + */ + +#include +#include +#include +#include +#include +#include +#include +#if defined(EXPOSE_C2_OPS) || !defined(CAFFE2_IS_XPLAT_BUILD) +#include +#endif +#include + +namespace c10 { + +namespace detail { +// The first argument of the schema might be of type DispatchKeySet, in which case we remove it. +// We do this because every argument in a function schema is expected to be convertable +// to an ivalue, but DispatchKeySet is not a type we want the jit to be aware of. +// See Note [Plumbing Keys Through The Dispatcher] +template +std::unique_ptr inferFunctionSchemaFromFunctor() { + using func_type = typename c10::remove_DispatchKeySet_arg_from_func::func_type; + return std::make_unique(inferFunctionSchemaFlattenedReturns()); +} +} + +/** + * An instance of this class handles the registration for one or more operators. + * Make sure you keep the RegisterOperators instance around since it will + * deregister the operator it's responsible for in its destructor. + * + * Example: + * + * > namespace { + * > class my_kernel_cpu final : public c10::OperatorKernel { + * > public: + * > Tensor operator()(Tensor a, Tensor b) {...} + * > }; + * > } + * > + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .kernel(DispatchKey::CPU)); + */ +class TORCH_API RegisterOperators final { +public: + RegisterOperators() = default; + ~RegisterOperators() = default; + + RegisterOperators(const RegisterOperators&) = delete; + RegisterOperators& operator=(const RegisterOperators&) = delete; + RegisterOperators(RegisterOperators&&) noexcept = default; + RegisterOperators& operator=(RegisterOperators&&) noexcept = default; + + class TORCH_API Options final { + public: + Options(const Options&) = delete; + Options(Options&&) noexcept = delete; + Options& operator=(const Options&) = delete; + Options& operator=(Options&&) noexcept = delete; + + // internal-only for registering stack based kernels + template + Options&& kernel(DispatchKey dispatch_key) && { + return std::move(*this).kernel(dispatch_key, KernelFunction::makeFromBoxedFunction(), std::nullopt, nullptr); + } + + // internal-only for registering stack based catch-all kernels + template + Options&& catchAllKernel() && { + return std::move(*this).kernel(std::nullopt, KernelFunction::makeFromBoxedFunction(), std::nullopt, nullptr); + } + + // internal only for registering caffe2 ops + Options&& schema(FunctionSchema&& schema) { + TORCH_CHECK(!schemaOrName_.has_value(), "You can only specify the schema once per operator registration."); + schemaOrName_ = FunctionSchema(std::move(schema)); + return std::move(*this); + } + + /** + * Use this to specify the schema for an operator. You can also specify + * the operator name only to have the function signature part of the + * schema be inferred from the kernel function. + * + * Example: + * + * > // Infer function signature from my_kernel_cpu + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .kernel(DispatchKey::CPU)); + * > + * > + * > // Explicitly specify full schema + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op(Tensor a) -> Tensor") + * > .kernel(DispatchKey::CPU)); + */ + Options&& schema(const std::string& schemaOrName) { + TORCH_CHECK(!schemaOrName_.has_value(), "Tried to register operator ", schemaOrName," but specified schema multiple times. You can only specify the schema once per operator registration."); + + #if !defined(EXPOSE_C2_OPS) && defined(CAFFE2_IS_XPLAT_BUILD) + throw std::logic_error("Tried to register operator " + schemaOrName + ". We don't support registering c10 ops on mobile yet because the function schema parser isn't present in the mobile build."); + #else + schemaOrName_ = torch::jit::parseSchemaOrName(schemaOrName); + #endif + + return std::move(*this); + } + + /** + * Use this to register an operator whose kernel is implemented as a functor. + * The kernel is only called for inputs matching the given dispatch key. + * You can register multiple kernels for different dispatch keys. + * + * Example: + * + * > namespace { + * > class my_kernel_cpu final : public c10::OperatorKernel { + * > public: + * > Tensor operator()(Tensor a, Tensor b) {...} + * > }; + * > } + * > + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .kernel(DispatchKey::CPU)); + * + * The functor constructor can take arguments to configure the kernel. + * The arguments are defined in the kernel registration. + * Example: + * + * > namespace { + * > class my_kernel_cpu final : public c10::OperatorKernel { + * > public: + * > explicit my_kernel_cpu(std::string some_configuration, int a, bool b) + * > : ... {...} + * > + * > Tensor operator()(Tensor a, Tensor b) {...} + * > }; + * > } + * > + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .kernel(DispatchKey::CPU, "some_configuration", 3, true)); + */ + template + // enable_if: only enable it if KernelFunctor is actually a functor + std::enable_if_t::value, Options&&> kernel(DispatchKey dispatch_key, ConstructorParameters&&... constructorParameters) && { + static_assert(std::is_base_of_v, "Tried to register a kernel functor using the kernel() API, but it doesn't inherit from c10::OperatorKernel. Please have the functor inherit from it."); + static_assert(std::is_constructible_v, "Wrong argument list for constructor of kernel functor. The arguments to kernel(arguments...) must match one of the constructors of Functor."); + + return std::move(*this).kernel( + dispatch_key, + KernelFunction::makeFromUnboxedFunctor(std::make_unique(std::forward(constructorParameters)...)), + impl::CppSignature::make(), + detail::inferFunctionSchemaFromFunctor() + ); + } + + /** + * Use this to register an operator whose kernel is implemented as a functor. + * The kernel is a catch-all kernel, meaning it's called independent from + * the input. Dispatch is disabled for this operator. + * + * Example: + * + * > namespace { + * > class my_kernel_cpu final : public c10::OperatorKernel { + * > public: + * > Tensor operator()(Tensor a, Tensor b) {...} + * > }; + * > } + * > + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .catchAllKernel()); + * + * The functor constructor can take arguments to configure the kernel. + * The arguments are defined in the kernel registration. + * Example: + * + * > namespace { + * > class my_kernel_cpu final : public c10::OperatorKernel { + * > public: + * > explicit my_kernel_cpu(std::string some_configuration, int a, bool b) + * > : ... {...} + * > + * > Tensor operator()(Tensor a, Tensor b) {...} + * > }; + * > } + * > + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .catchAllKernel("some_configuration", 3, true)); + */ + template + // enable_if: only enable it if KernelFunctor is actually a functor + std::enable_if_t::value, Options&&> catchAllKernel(ConstructorParameters&&... constructorParameters) && { + static_assert(std::is_base_of_v, "Tried to register a kernel functor using the kernel() API, but it doesn't inherit from c10::OperatorKernel. Please have the functor inherit from it."); + static_assert(std::is_constructible_v, "Wrong argument list for constructor of kernel functor. The arguments to kernel(arguments...) must match one of the constructors of Functor."); + + return std::move(*this).kernel( + std::nullopt, + KernelFunction::makeFromUnboxedFunctor(std::make_unique(std::forward(constructorParameters)...)), + impl::CppSignature::make(), + detail::inferFunctionSchemaFromFunctor() + ); + } + + /** + * Use this to register an operator whose kernel is implemented by a function. + * The kernel is only called for inputs matching the given dispatch key. + * You can register multiple kernels for different dispatch keys. + * + * Example: + * + * > namespace { Tensor my_kernel_cpu(Tensor a, Tensor b) {...} } + * > + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .kernel(DispatchKey::CPU)); + */ + template + // enable_if: only enable it if FuncType is actually a function + std::enable_if_t::value, Options&&> kernel(DispatchKey dispatch_key) && { + static_assert(!std::is_same_v, "Tried to register a stackbased (i.e. internal) kernel function using the public kernel<...>() API. Please either use the internal kernel(...) API or also implement the kernel function as defined by the public API."); + static_assert(kernel_func != nullptr, "Kernel function cannot be nullptr"); + + return std::move(*this).kernel( + dispatch_key, + KernelFunction::makeFromUnboxedFunction(TORCH_FN(kernel_func)), + impl::CppSignature::make(), + // TODO Do schema inference without relying on WrapFunctionIntoFunctor + detail::inferFunctionSchemaFromFunctor>::type>() + ); + } + + /** + * Use this to register an operator whose kernel is implemented by a function. + * The kernel is a catch-all kernel, meaning it's called independent from + * the input. Dispatch is disabled for this operator. + * + * Example: + * + * > namespace { Tensor my_kernel_cpu(Tensor a, Tensor b) {...} } + * > + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .catchAllKernel()); + */ + template + // enable_if: only enable it if FuncType is actually a function + std::enable_if_t::value, Options&&> catchAllKernel() && { + static_assert(!std::is_same_v, "Tried to register a stackbased (i.e. internal) kernel function using the public kernel<...>() API. Please either use the internal kernel(...) API or also implement the kernel function as defined by the public API."); + static_assert(kernel_func != nullptr, "Kernel function cannot be nullptr"); + + return std::move(*this).kernel( + std::nullopt, + KernelFunction::makeFromUnboxedFunction(TORCH_FN(kernel_func)), + impl::CppSignature::make(), + // TODO Do schema inference without relying on WrapFunctionIntoFunctor + detail::inferFunctionSchemaFromFunctor>::type>() + ); + } + + template + // enable_if: only enable it if FuncType is actually a function + std::enable_if_t::value, Options&&> kernel(DispatchKey dispatch_key, FuncType* kernel_func) && { + static_assert(!std::is_same_v, "Tried to register a stackbased (i.e. internal) kernel function using the public kernel<...>() API. Please either use the internal kernel(...) API or also implement the kernel function as defined by the public API."); + TORCH_INTERNAL_ASSERT(kernel_func != nullptr, "Kernel function cannot be nullptr"); + + return std::move(*this).kernel( + dispatch_key, + KernelFunction::makeFromUnboxedRuntimeFunction(kernel_func), + impl::CppSignature::make(), + // TODO Do schema inference without relying on WrapFunctionIntoFunctor + detail::inferFunctionSchemaFromFunctor>>() + ); + } + + template + // enable_if: only enable it if FuncType is actually a function + std::enable_if_t::value, Options&&> catchAllKernel(FuncType* kernel_func) && { + static_assert(!std::is_same_v, "Tried to register a stackbased (i.e. internal) kernel function using the public kernel<...>() API. Please either use the internal kernel(...) API or also implement the kernel function as defined by the public API."); + TORCH_INTERNAL_ASSERT(kernel_func != nullptr, "Kernel function cannot be nullptr"); + + return std::move(*this).kernel( + std::nullopt, + KernelFunction::makeFromUnboxedRuntimeFunction(kernel_func), + impl::CppSignature::make(), + // TODO Do schema inference without relying on WrapFunctionIntoFunctor + detail::inferFunctionSchemaFromFunctor>>() + ); + } + + /** + * Use this to register an operator whose kernel is implemented as a lambda. + * The kernel is only called for inputs matching the given dispatch key. + * You can register multiple kernels for different dispatch keys. + * + * The lambda must be stateless, i.e. not have a capture. If your kernel + * needs to store some configuration parameters, write the kernel as a + * functor instead. + * + * Example: + * + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .kernel(DispatchKey::CPU, [] (Tensor a) -> Tensor {...})); + */ + template + // enable_if: only enable it if Lambda is a functor (note: lambdas are functors) + std::enable_if_t< + guts::is_functor>::value + && !std::is_same_v>::func_type, KernelFunction::BoxedKernelFunction>, + Options&&> kernel(DispatchKey dispatch_key, Lambda&& functor) && { + static_assert(!std::is_base_of_v>, "The kernel(x) API for registering a kernel is only meant to be used with lambdas. Your kernel is a functor. Please use the kernel() API instead."); + + // We don't support stateful lambdas (i.e. lambdas with a capture), because their + // behavior would be nonobvious. A functor kernel with cache gets a new instance of + // its cache each time the kernel is looked up from the dispatch table. + // A lambda with a capture would be global and share its capture between all kernel lookups. + // So, instead of making users having to think about it (including the thread-safety + // issues this causes), let's just forbid stateful lambdas altogether. + static_assert(guts::is_stateless_lambda>::value, "The kernel(x) API for registering a kernel only works for stateless lambdas (i.e. lambdas without captures). If you need a cache, please use the functor based API kernel() instead."); + + return std::move(*this).kernel( + dispatch_key, + KernelFunction::makeFromUnboxedLambda(std::forward(functor)), + impl::CppSignature::make(), + // TODO Do schema inference without relying on WrapFunctionIntoRuntimeFunctor + detail::inferFunctionSchemaFromFunctor>>() + ); + } + + /** + * Use this to register an operator whose kernel is implemented as a lambda. + * The kernel is a catch-all kernel, meaning it's called independent from + * the input. Dispatch is disabled for this operator. + * + * The lambda must be stateless, i.e. not have a capture. If your kernel + * needs to store some configuration parameters, write the kernel as a + * functor instead. + * + * Example: + * + * > static auto registry = c10::RegisterOperators() + * > .op(c10::RegisterOperators::options() + * > .schema("my_op") + * > .catchAllKernel([] (Tensor a) -> Tensor {...})); + */ + template + // enable_if: only enable it if Lambda is a functor (note: lambdas are functors) + std::enable_if_t< + guts::is_functor>::value + && !std::is_same_v>::func_type, KernelFunction::BoxedKernelFunction>, + Options&&> catchAllKernel(Lambda&& lambda) && { + static_assert(!std::is_base_of_v>, "The kernel(x) API for registering a kernel is only meant to be used with lambdas. Your kernel is a functor. Please use the kernel() API instead."); + + // We don't support stateful lambdas (i.e. lambdas with a capture), because their + // behavior would be nonobvious. + // A lambda with a capture would be global and share its capture between all kernel lookups. + // This would be a likely source for unexpected race conditions, so we forbid it. + // If a kernel really needs global state, they can just have regular global state + // in their .cpp file next to the kernel lambda. + static_assert(guts::is_stateless_lambda>::value, "The kernel(x) API for registering a kernel only works for stateless lambdas (i.e. lambdas without captures). If you need a cache, please use the functor based API kernel() instead."); + + return std::move(*this).kernel( + std::nullopt, + KernelFunction::makeFromUnboxedLambda(std::forward(lambda)), + impl::CppSignature::make(), + // TODO Do schema inference without relying on WrapFunctionIntoRuntimeFunctor + detail::inferFunctionSchemaFromFunctor>>() + ); + } + + Options&& aliasAnalysis(AliasAnalysisKind aliasAnalysisKind) && { + TORCH_CHECK(!aliasAnalysisKind_.has_value(), "You can only call aliasAnalysis() once per operator registration."); + aliasAnalysisKind_ = aliasAnalysisKind; + return std::move(*this); + } + + private: + Options&& kernel(std::optional dispatch_key, KernelFunction&& func, std::optional cpp_signature, std::unique_ptr&& inferred_function_schema) && { + KernelRegistrationConfig config; + config.dispatch_key = dispatch_key; + config.func = std::move(func); + config.cpp_signature = cpp_signature; + config.inferred_function_schema = std::move(inferred_function_schema); + kernels.push_back(std::move(config)); + return std::move(*this); + } + + Options() + : schemaOrName_(std::nullopt) + , kernels() + , aliasAnalysisKind_(std::nullopt) + {} + + // KernelRegistrationConfig accumulates all information from the config + // parameters passed to a RegisterOperators::op() call into one object. + struct KernelRegistrationConfig final { + KernelRegistrationConfig() + : dispatch_key(std::nullopt) + , func() + , cpp_signature(std::nullopt) + , inferred_function_schema(nullptr) + {} + + std::optional dispatch_key; + KernelFunction func; + std::optional cpp_signature; + std::unique_ptr inferred_function_schema; + }; + + std::optional> schemaOrName_; + + std::vector kernels; + std::optional aliasAnalysisKind_; + friend class RegisterOperators; + friend class Library; + }; + + /** + * Call this to get an instance of registration options, which + * can be passed to a call to RegisterOperators::op() to specify + * these options for the operator registration. + * See class doc comment for examples. + */ + static Options options() { + return {}; + } + + /** + * Call this to register an operator. See class doc comment for examples. + */ + RegisterOperators&& op(Options&& options) && { + checkSchemaAndRegisterOp_(std::move(options)); + return std::move(*this); + } + + // Regular mutator version of the && version above + RegisterOperators& op(Options&& options) & { + checkSchemaAndRegisterOp_(std::move(options)); + return *this; + } + + /** + * This is a shorthand for RegisterOperators::op(Options) where you can + * specify the operator schema outside of the options parameter. + * See class doc comment for examples. + */ + RegisterOperators&& op(const std::string& schemaOrName, Options&& options = RegisterOperators::options()) && { + return std::move(*this).op(std::move(options).schema(schemaOrName)); + } + + // internal only for registering caffe2 ops + RegisterOperators&& op(FunctionSchema schema, Options&& options) && { + return std::move(*this).op(std::move(options).schema(std::move(schema))); + } + + template + explicit RegisterOperators(const std::string& schemaOrName, FuncType&& func, Options&& options = RegisterOperators::options()) + : RegisterOperators() { + std::move(*this).op(schemaOrName, std::forward(func), std::move(options)); + } + + /** + * This API registers an operator based on a kernel function pointer. + * + * Given a kernel + * + * > namespace { Tensor my_kernel_cpu(Tensor a, Tensor b) {...} } + * + * This API looks like: + * + * > static auto registry = c10::RegisterOperators() + * > .op("my_op", &my_kernel_cpu); + * + * If your kernel is small and the overhead of calling it matters, + * then this API might be the wrong choice since the following API + * has a slightly lower overhead for calling into the kernel: + * + * > static auto registry = c10::RegisterOperators() + * > .op("my_op", c10::RegisterOperators::options() + * > .kernel()); + * + * Or, alternatively, write your kernel as a functor: + * + * > namespace { + * > class my_kernel_cpu final : public c10::OperatorKernel { + * > public: + * > Tensor operator()(Tensor a, Tensor b) {...} + * > }; + * > } + * > + * > static auto registry = c10::RegisterOperators() + * > .op("my_op", c10::RegisterOperators::options() + * > .kernel()); + */ + template + // enable_if: only enable it if FuncType is actually a function, but not a stack based BoxedKernelFunction. + std::enable_if_t::value && !std::is_same_v, RegisterOperators&&> + op(const std::string& schemaOrName, FuncType* func, Options&& options = RegisterOperators::options()) && { + constexpr bool AllowLegacyTypes = true; + return std::move(*this).op(std::move(options).schema(schemaOrName).kernel( + std::nullopt, + KernelFunction::makeFromUnboxedRuntimeFunction(func), + impl::CppSignature::make(), + // TODO Do schema inference without relying on WrapFunctionIntoRuntimeFunctor + detail::inferFunctionSchemaFromFunctor>>() + )); + } + + /** + * This API registers an operator based on a kernel lambda. + * + * This API looks like: + * + * > static auto registry = c10::RegisterOperators() + * > .op("my_op", [] (Tensor a, Tensor b) {...}); + * + * This is equivalent to: + * + * > static auto registry = c10::RegisterOperators() + * > .op("my_op", c10::RegisterOperators::options() + * > .catchAllKernel([] (Tensor a, Tensor b) {...})); + * + */ + template + // enable_if: only enable it if Lambda is actually a stateless lambda + std::enable_if_t::value && guts::is_stateless_lambda>::value, RegisterOperators&&> + op(const std::string& schemaOrName, Lambda&& lambda, Options&& options = RegisterOperators::options()) && { + static_assert(!std::is_base_of_v, "c10::OperatorKernel is part of the new kernel registration API and shouldn't be used together with the deprecated registration API. Please use the new RegisterOperators::options().kernel() based API instead."); + + constexpr bool AllowLegacyTypes = true; + return std::move(*this).op(std::move(options).schema(schemaOrName).kernel( + std::nullopt, + KernelFunction::makeFromUnboxedLambda(std::forward(lambda)), + impl::CppSignature::make(), + // TODO Do schema inference without relying on WrapFunctionIntoRuntimeFunctor + detail::inferFunctionSchemaFromFunctor>>() + )); + } + + template + C10_DEPRECATED_MESSAGE("Registering operator kernels with stateful lambdas (i.e. lambdas with a capture) has non-obvious behavior. This is deprecated. Please use a lambda without a capture or a functor class instead.") + // enable_if: only enable it if Lambda is actually a functor but not a stateless lambda + std::enable_if_t::value && !guts::is_stateless_lambda>::value, RegisterOperators&&> + op(const std::string& schemaOrName, Lambda&& lambda, Options&& options = RegisterOperators::options()) && { + static_assert(!std::is_base_of_v, "c10::OperatorKernel is part of the new kernel registration API and shouldn't be used together with the deprecated registration API. Please use the new RegisterOperators::options().kernel() based API instead."); + + constexpr bool AllowLegacyTypes = true; + return std::move(*this).op(std::move(options).schema(schemaOrName).kernel( + std::nullopt, + KernelFunction::makeFromUnboxedLambda(std::forward(lambda)), + impl::CppSignature::make(), + // TODO Do schema inference without relying on WrapFunctionIntoRuntimeFunctor + detail::inferFunctionSchemaFromFunctor>>() + )); + } + +private: + void checkSchemaAndRegisterOp_(Options&& config); + + static c10::FunctionSchema inferSchemaFromKernels_(const OperatorName& opNameStr, const Options& options); + void checkNoDuplicateKernels_(const Options& options); + void registerOp_(Options&& options); + + std::vector registrars_; +}; + +} // namespace c10 + +namespace torch { + // Old-style API + using RegisterOperators = c10::RegisterOperators; +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/operator_name.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/operator_name.h new file mode 100644 index 0000000000000000000000000000000000000000..22e1f427b632659aa6a523b9bcb2723a104414aa --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/operator_name.h @@ -0,0 +1,98 @@ +#pragma once + +#include +#include + +#include +#include +#include +#include +#include +#include + +namespace c10 { + +// TODO: consider storing namespace separately too +struct OperatorName final { + std::string name; + std::string overload_name; + OperatorName(std::string name, std::string overload_name) + : name(std::move(name)), overload_name(std::move(overload_name)) {} + + // TODO: These two functions below are slow! Fix internal data structures so + // I don't have to manually reconstruct the namespaces! + + // Return the namespace of this OperatorName, if it exists. The + // returned string_view is only live as long as the OperatorName + // exists and name is not mutated + std::optional getNamespace() const { + auto pos = name.find("::"); + if (pos == std::string::npos) { + return std::nullopt; + } else { + return std::string_view(name.data(), pos); + } + } + + // Returns true if we successfully set the namespace + bool setNamespaceIfNotSet(const char* ns) { + if (!getNamespace().has_value()) { + const auto ns_len = strlen(ns); + const auto old_name_size = name.size(); + name.resize(ns_len + 2 + old_name_size); + // Shift current value of name to the end of the new space. + name.replace( + name.size() - old_name_size, old_name_size, name, 0, old_name_size); + name.replace(0, ns_len, ns, ns_len); + name[ns_len] = ':'; + name[ns_len + 1] = ':'; + return true; + } else { + return false; + } + } +}; + +// Non-owning view of an OperatorName. Unlike OperatorName, most of +// its functions are constexpr, so it can be used for compile time +// computations +struct OperatorNameView final { + std::string_view name; + std::string_view overload_name; + constexpr OperatorNameView( + std::string_view name, + std::string_view overload_name) + : name(name), overload_name(overload_name) {} + // Parses strings like "foo.overload" and also "foo" + constexpr static OperatorNameView parse(std::string_view full_name) { + auto i = full_name.find('.'); + if (i == std::string_view::npos) { + return OperatorNameView(full_name, std::string_view()); + } else { + return OperatorNameView(full_name.substr(0, i), full_name.substr(i + 1)); + } + } +}; + +inline bool operator==(const OperatorName& lhs, const OperatorName& rhs) { + return lhs.name == rhs.name && lhs.overload_name == rhs.overload_name; +} + +inline bool operator!=(const OperatorName& lhs, const OperatorName& rhs) { + return !operator==(lhs, rhs); +} + +TORCH_API std::string toString(const OperatorName& opName); +TORCH_API std::ostream& operator<<(std::ostream&, const OperatorName&); + +} // namespace c10 + +namespace std { +template <> +struct hash<::c10::OperatorName> { + size_t operator()(const ::c10::OperatorName& x) const { + return std::hash()(x.name) ^ + (~std::hash()(x.overload_name)); + } +}; +} // namespace std diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/qualified_name.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/qualified_name.h new file mode 100644 index 0000000000000000000000000000000000000000..22fd8b8b857d7c1b60fbd4c5033a7765e281cab6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/qualified_name.h @@ -0,0 +1,161 @@ +#pragma once + +#include +#include +#include +#include +#include + +namespace c10 { + +// Represents a name of the form "foo.bar.baz" +struct QualifiedName { + QualifiedName() = default; + + // `name` can be a dotted string, like "foo.bar.baz", or just a bare name. + /* implicit */ QualifiedName(const std::string& name) { + TORCH_CHECK(!name.empty()); + // split the string into its atoms. + size_t startSearchFrom = 0; + size_t pos = name.find(delimiter_, startSearchFrom); + + while (pos != std::string::npos) { + auto atom = name.substr(startSearchFrom, pos - startSearchFrom); + TORCH_INTERNAL_ASSERT( + !atom.empty(), "Invalid name for qualified name: '", name, "'"); + atoms_.push_back(std::move(atom)); + startSearchFrom = pos + 1; + pos = name.find(delimiter_, startSearchFrom); + } + + auto finalAtom = name.substr(startSearchFrom); + TORCH_INTERNAL_ASSERT( + !finalAtom.empty(), "Invalid name for qualified name: '", name, "'"); + atoms_.emplace_back(std::move(finalAtom)); + + cacheAccessors(); + } + + explicit QualifiedName(std::vector atoms) : atoms_(std::move(atoms)) { + for (const auto& atom : atoms_) { + TORCH_CHECK(!atom.empty(), "Atom cannot be empty"); + TORCH_CHECK( + atom.find(delimiter_) == std::string::npos, + "Delimiter not allowed in atom"); + } + + cacheAccessors(); + } + // Unnecessary copy. Ideally we'd use something like std::string_view. + /* implicit */ QualifiedName(const char* name) + : QualifiedName(std::string(name)) {} + + // `name` must be a bare name (no dots!) + explicit QualifiedName(const QualifiedName& prefix, std::string name) { + TORCH_INTERNAL_ASSERT(!name.empty()); + TORCH_INTERNAL_ASSERT(name.find(delimiter_) == std::string::npos); + atoms_.insert(atoms_.begin(), prefix.atoms_.begin(), prefix.atoms_.end()); + atoms_.push_back(std::move(name)); + + cacheAccessors(); + } + + // Is `this` a prefix of `other`? + // For example, "foo.bar" is a prefix of "foo.bar.baz" + bool isPrefixOf(const QualifiedName& other) const { + const auto& thisAtoms = atoms_; + const auto& otherAtoms = other.atoms_; + + if (thisAtoms.size() > otherAtoms.size()) { + // Can't be a prefix if it's bigger + return false; + } + for (const auto i : c10::irange(thisAtoms.size())) { + if (thisAtoms[i] != otherAtoms[i]) { + return false; + } + } + return true; + } + + // The fully qualified name, like "foo.bar.baz" + const std::string& qualifiedName() const { + return qualifiedName_; + } + + // The leading qualifier, like "foo.bar" + const std::string& prefix() const { + return prefix_; + } + + // The base name, like "baz" + const std::string& name() const { + return name_; + } + + const std::vector& atoms() const { + return atoms_; + } + + bool operator==(const QualifiedName& other) const { + return this->qualifiedName_ == other.qualifiedName_; + } + + bool operator!=(const QualifiedName& other) const { + return !(*this == other); + } + + private: + static constexpr char delimiter_ = '.'; + + // Helper for cacheAccessors() below. + template + std::string join(char delimiter, const T& v) { + std::string out; + size_t reserve = 0; + for (const auto& e : v) { + reserve += e.size() + 1; + } + out.reserve(reserve); + for (const auto i : c10::irange(v.size())) { + if (i != 0) { + out.push_back(delimiter); + } + out.append(v[i]); + } + return out; + } + + void cacheAccessors() { + qualifiedName_ = join(delimiter_, atoms_); + if (atoms_.size() > 1) { + ArrayRef view(atoms_); + const auto prefixView = view.slice(0, view.size() - 1); + prefix_ = join(delimiter_, prefixView); + } + + if (!atoms_.empty()) { + name_ = atoms_.back(); + } + } + + // The actual list of names, like "{foo, bar, baz}" + std::vector atoms_; + + /* + * Cached accessors, derived from `atoms_`. + */ + std::string qualifiedName_; + std::string prefix_; + std::string name_; +}; +} // namespace c10 + +namespace std { +template <> +struct hash { + size_t operator()(const c10::QualifiedName& n) const noexcept { + return std::hash()(n.qualifiedName()); + } +}; +} // namespace std diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/rref_interface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/rref_interface.h new file mode 100644 index 0000000000000000000000000000000000000000..70273f168d936136556f7556cbdf398d6d792f58 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/rref_interface.h @@ -0,0 +1,41 @@ +#pragma once + +#include +#include + +namespace c10 { + +struct Type; +using worker_id_t = int16_t; + +// This abstract class contains only user-facing APIs, and will be shared +// between jit and distributed to implement TorchScript support. +class C10_EXPORT RRefInterface : public c10::intrusive_ptr_target { + public: + RRefInterface() = default; + // RRef is made NOT copyable NOT movable to prevent messing up reference + // counting. + RRefInterface(const RRefInterface& other) = delete; + RRefInterface(RRefInterface&& other) = delete; + RRefInterface& operator=(const RRefInterface& other) = delete; + RRefInterface& operator=(RRefInterface&& other) = delete; + + ~RRefInterface() override = default; + + // returns the worker id of the owner + virtual worker_id_t owner() const = 0; + + // returns the worker name of the owner + virtual std::string ownerName() const = 0; + + // Returns true if this is the ``OwnerRRef`` + virtual bool isOwner() const = 0; + + // Returns true if this is an ``OwnerRRef`` or if this ``UserRRef`` has been + // confirmed by its owner. + virtual bool confirmedByOwner() const = 0; + + virtual const TypePtr type() const = 0; +}; + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/stack.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/stack.h new file mode 100644 index 0000000000000000000000000000000000000000..ca2925f3cac20786353c28ad1fb2d7bbdb0101d1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/stack.h @@ -0,0 +1,204 @@ +#pragma once + +#include + +#include +#include +#include + +// TODO move this to c10 namespace + + +namespace torch::jit { + +using c10::IValue; +using Stack = std::vector; + +class Operation { + template + using accepts = std::is_constructible, F&&>; + + public: + template ::value, int> = 0> + C10_DEPRECATED_MESSAGE("Please use void(Stack&) to register operator instead.") + Operation(F&& raw): op_([raw = std::forward(raw)](Stack& stack) { + raw(&stack); + }) {} + + template ::value && + !std::is_same_v, Operation>, int> = 0> + Operation(F&& op): op_(std::forward(op)) {} + + Operation(std::nullptr_t) noexcept {} + + explicit operator bool() const noexcept { + return op_ ? true : false; + } + + void operator()(Stack& stack) { + op_(stack); + } + + template + T* target() noexcept { + return op_.target(); + } + + private: + std::function op_; +}; + +// An operation with N inputs and M outputs pops the last N inputs off +// the stack and pushes its M inputs onto the stack +// before: I0, I1, ... IN <- stack.back() +// after: O0, O1, ... OM +// operations are defined this way so that ownership of inputs can be +// transferred to the operation and it can incrementally drop ownership of +// tensors when they become unneeded. For large operations, like 'run an entire +// subgraph', this functionality is very important for minimizing gpu memory +// usage return value is the relative 'offset' to jump to for the next +// operation: +// pc += 1 + offset +// so a return value of 0 goes to the next instruction + +// treat the last N elements of the stack as a list, looking up +// element i +inline IValue& peek(Stack& stack, size_t i, size_t N) { + // NOLINTNEXTLINE(*-narrowing-conversions) + return *(stack.end() - N + i); +} +inline IValue& peek(Stack* stack, size_t i, size_t N) { + return peek(*stack, i, N); +} +inline const IValue& peek(const Stack& stack, size_t i, size_t N) { + // NOLINTNEXTLINE(*-narrowing-conversions) + return *(stack.end() - N + i); +} +inline const IValue& peek(const Stack* stack, size_t i, size_t N) { + return peek(*stack, i, N); +} +// treat the last N elements of the stack as a list, looking up the +// slice starting at index i and having length len +inline at::ArrayRef peekSlice( + const Stack& stack, + size_t i, + size_t len, + size_t N) { + return at::ArrayRef(stack).slice(stack.size() - N + i, len); +} +inline at::ArrayRef last(const Stack& stack, size_t N) { + return peekSlice(stack, 0, N, N); +} +inline at::ArrayRef last(const Stack* stack, size_t N) { + return last(*stack, N); +} +inline void drop(Stack& stack, size_t n) { + // NOLINTNEXTLINE(*-narrowing-conversions) + stack.erase(stack.end() - n, stack.end()); +} +inline void drop(Stack* stack, size_t n) { + drop(*stack, n); +} +inline IValue pop(Stack& stack) { + TORCH_CHECK(!stack.empty(), "pop() called on empty stack"); + auto r = std::move(stack.back()); + stack.pop_back(); + return r; +} +inline IValue pop(Stack* stack) { + return pop(*stack); +} +inline std::vector pop(Stack& stack, size_t n) { + std::vector result; + result.reserve(n); + for (const auto i : c10::irange(n)) { + result.push_back(std::move(peek(stack, i, n))); + } + drop(stack, n); + return result; +} + +// variadic pop: +// int64_t a; at::Tensor b; +// pop(stack, a, b); +// equivalent to: +// b = pop(stack).toTensor(); +// a = pop(stack).toInt(); +template +inline void pop(Stack& stack, Types&... args) { + size_t i = 0; + constexpr size_t N = sizeof...(args); + (void)std::initializer_list{ + (args = std::move(peek(stack, i++, N)).template to(), 0)...}; + drop(stack, N); +} +template +inline void pop(Stack* stack, Types&... args) { + pop(*stack, args...); +} +template +inline void push_one(Stack& stack, Type&& arg) { + stack.emplace_back(std::forward(arg)); +} + +inline void push_one(Stack& stack, c10::TensorOptions options) { + stack.emplace_back(c10::typeMetaToScalarType(options.dtype())); + stack.emplace_back(options.layout()); + stack.emplace_back(options.device()); + stack.emplace_back(options.pinned_memory()); +} + +template +inline void push(Stack& stack, Types&&... args) { + (void)std::initializer_list{(push_one(stack, std::forward(args)), 0)...}; +} +template +inline void push(Stack* stack, Types&&... args) { + return push(*stack, std::forward(args)...); +} +template +inline void push_list_elements(Stack& stack, const c10::List& elements) { + for (T elem : elements) { + stack.push_back(std::move(elem)); + } +} + +// The packer here is carefully written not to make any unnecessary +// copies. + +// pack takes the return values of aten functions pushes them onto the stack +template +inline void pack(Stack& stack, T&& v) { + stack.emplace_back(std::forward(v)); +} +template +inline void pack(Stack* stack, T&& v) { + pack(*stack, std::forward(v)); +} + +template +struct TuplePacker { + // NB: *Not* a universal reference. + static void execute(Stack& stack, std::tuple&& t) { + // NB: The move here does not "destroy" the entire tuple, that is + // not what std::move does; only the particular tuple index + // processed here gets stolen. + pack(stack, std::get(std::move(t))); + TuplePacker::execute(stack, std::move(t)); + } +}; + +template +struct TuplePacker<0, Args...> { + // NOLINTNEXTLINE(cppcoreguidelines-rvalue-reference-param-not-moved) + static void execute(Stack& /*stack*/, std::tuple&& /*t*/){} +}; + +template +inline void pack(Stack& stack, std::tuple&& t) { + TuplePacker::execute(stack, std::move(t)); +} + +} // namespace torch::jit diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/symbol.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/symbol.h new file mode 100644 index 0000000000000000000000000000000000000000..f94cbf6d620ce062e64604bd8bcff366868e358b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/symbol.h @@ -0,0 +1,147 @@ +#pragma once +#include +#include +#include // For std::hash +#include + + +namespace c10 { + +// 'prim' symbols are synthetic operators that occur only in the IR +// and don't have corresponding implementations in ATen. + +// 'onnx' symbols correspond to ONNX operators. Their semantics +// are defined in https://github.com/onnx/onnx/blob/master/docs/Operators.md +// The particular version we are targeting is specified by '_onnx_opset_version' +// in torch.onnx.symbolic_helper +// +// In general, most ONNX operators won't get an entry here, because they +// are handled from the Python end. However, you may occasionally need +// to intern an ONNX symbol here so that you can conveniently write an +// optimization on ONNX operations. + +// 'attr' symbols are attribute keys. They are shared between both ONNX and ATen +// operators (you disambiguate their meaning by looking at the operator itself). +// In general, you only need to define attribute keys that are used by +// onnx or prim; ATen attributes are automatically generated in FORALL_ATTR_BASE_SYMBOLS. + +// Note [Symbol allocation] +// ~~~~~~~~~~~~~~~~~~~~~~~~ +// +// 1. Symbol namespace is split up into namespaces. +// +// 2. The intended access pattern for built-in symbols is onnx::MatMul +// in the c10 namespace (this is a Symbol). +// + +// Built-in constant definition strategy: +// - Enum is the most convenient way to generate a contiguous sequence +// of numbers for an identifier. +// - However, an enum gives you a fresh type. We want onnx::MatMul to +// be type Symbol, not some random enum type! +// - Therefore, after using enums to generate the sequence of integers, +// we then declare constexpr Symbols to get everything the actual Symbol +// type we want. Symbols must be constexpr to be valid to be "case"ed on. + +using unique_t = uint32_t; + +const std::string& domain_prefix(); + +// A Symbol is like an interned string, but with a little extra +// structure; it is namespaced via SymbolNamespace and the resulting +// intern pointers support efficient namespace testing. +struct TORCH_API Symbol { + explicit constexpr Symbol() : value(0) {} + explicit constexpr Symbol(unique_t uniq) + : value(uniq) {} + + // Get a Symbol for a qualified string like "attr::bar" + static Symbol fromQualString(const std::string & s); + + // Get a Symbol from a domain and an unqualified string like "org.pytorch.attr" and "bar" + static Symbol fromDomainAndUnqualString(const std::string & d, const std::string & s); + + // Constructors for our various namespaced strings. This will construct + // the appropriate namespaced string, e.g., "attr::foo" for the + // argument "foo", and then attempt to intern it. DO NOT USE THIS + // with a string literal; attr::foo should be available in that case + // (and if it's not, you should add it to the built-ins list above.) + static Symbol attr(const std::string & s); + static Symbol aten(const std::string & s); + static Symbol cuda(const std::string & s); + static Symbol onnx(const std::string & s); + static Symbol prim(const std::string & s); + static Symbol user(const std::string & s); + static Symbol caffe2(const std::string & s); + static Symbol dimname(const std::string & s); + // TODO: eliminate me + static Symbol scope(const std::string & s); + + bool is_attr() const; + bool is_aten() const; + bool is_cuda() const; + bool is_prim() const; + bool is_prims() const; + bool is_nvprims() const; + bool is_onnx() const; + bool is_user() const; + bool is_caffe2() const; + bool is_dimname() const; + + // So we can switch on this + constexpr operator unique_t() const { + return value; + } + + Symbol ns() const; + + // Give a string corresponding to the unqualified version of this name, e.g., + // "mm". Use this in a context where the intended namespace of the string is + // obvious; this is a *lossy* conversion. + const char * toUnqualString() const; + + // Give a string corresponding to the qualified version of this name, + // e.g., "aten::mm". This string format is made available to Python bindings + // (so we know how to parse it.) + const char * toQualString() const; + + // This describes a symbol in a case where humans read it. At the moment it's + // the same as toQualString. This has to be a const char* returned because + // a lot of printf style macros use it. + const char * toDisplayString() const; + + // Give a string corresponding to the domain name for the symbol, + // e.g., "org.pytorch.aten". + std::string domainString() const; + +private: + + explicit Symbol(Symbol ns, const std::string & s); + unique_t value; +}; + +static inline bool operator==(Symbol lhs, Symbol rhs) { + return static_cast(lhs) == static_cast(rhs); +} + +inline Symbol Symbol::attr(const std::string & s) { return Symbol::fromQualString("attr::" + s); } +inline Symbol Symbol::aten(const std::string & s) { return Symbol::fromQualString("aten::" + s); } +inline Symbol Symbol::cuda(const std::string & s) { return Symbol::fromQualString("cuda::" + s); } +inline Symbol Symbol::onnx(const std::string & s) { return Symbol::fromQualString("onnx::" + s); } +inline Symbol Symbol::prim(const std::string & s) { return Symbol::fromQualString("prim::" + s); } +inline Symbol Symbol::scope(const std::string & s) { return Symbol::fromQualString("scope::" + s); } +inline Symbol Symbol::user(const std::string & s) { return Symbol::fromQualString("user::" + s); } +inline Symbol Symbol::caffe2(const std::string & s) { return Symbol::fromQualString("_caffe2::" + s); } +inline Symbol Symbol::dimname(const std::string & s) { return Symbol::fromQualString("dimname::" + s); } + +} // namespace c10 + +// make symbol behave like an integer in hash tables +namespace std { +template <> +struct hash { + size_t operator()(c10::Symbol s) const { + return std::hash()(static_cast(s)); + } +}; +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/type_factory.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/type_factory.h new file mode 100644 index 0000000000000000000000000000000000000000..5b573b5c41e90bb5c2c5b16fc54135b05561f3c1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/type_factory.h @@ -0,0 +1,108 @@ +#pragma once + +#include +#include + +#include +#include +#include + +namespace c10 { + +template +struct TORCH_API TypeFactoryBase {}; + +template <> +struct TORCH_API TypeFactoryBase { + template + static c10::DynamicTypePtr create(TypePtr ty, Args&&... args) { + return std::make_shared( + c10::DynamicTypeTrait::tagValue(), + c10::DynamicType::Arguments(c10::ArrayRef( + {std::move(ty), std::forward(args)...}))); + } + template + static c10::DynamicTypePtr create(const std::vector& types) { + return std::make_shared( + c10::DynamicTypeTrait::tagValue(), + c10::DynamicType::Arguments(types)); + } + static c10::DynamicTypePtr createNamedTuple( + const std::string& name, + const std::vector& fields, + const std::vector& types) { + return std::make_shared( + c10::DynamicType::Tag::Tuple, + name, + c10::DynamicType::Arguments(fields, types)); + } + template + C10_ERASE static c10::DynamicTypePtr createNamed(const std::string& name) { + return std::make_shared( + c10::DynamicTypeTrait::tagValue(), + name, + c10::DynamicType::Arguments{}); + } + template + C10_ERASE static c10::DynamicTypePtr get() { + return DynamicTypeTrait::getBaseType(); + } + static const std::unordered_map& basePythonTypes(); +}; + +using DynamicTypeFactory = TypeFactoryBase; + +// Helper functions for constructing DynamicTypes inline. +template < + typename T, + std::enable_if_t::isBaseType, int> = 0> +C10_ERASE DynamicTypePtr dynT() { + return DynamicTypeFactory::get(); +} + +template < + typename T, + typename... Args, + std::enable_if_t::isBaseType, int> = 0> +C10_ERASE DynamicTypePtr dynT(Args&&... args) { + return DynamicTypeFactory::create(std::forward(args)...); +} + +template <> +struct TORCH_API TypeFactoryBase { + template + static c10::TypePtr create(TypePtr ty, Args&&... args) { + return T::create(std::move(ty), std::forward(args)...); + } + template + static c10::TypePtr create(std::vector types) { + return T::create(std::move(types)); + } + static c10::TypePtr createNamedTuple( + const std::string& name, + const std::vector& fields, + const std::vector& types); + template + C10_ERASE static c10::TypePtr createNamed(const std::string& name) { + return T::create(name); + } + static const std::unordered_map& basePythonTypes(); + template + C10_ERASE static c10::TypePtr get() { + return T::get(); + } +}; + +using DefaultTypeFactory = TypeFactoryBase; + +using PlatformType = +#ifdef C10_MOBILE + c10::DynamicType +#else + c10::Type +#endif + ; + +using TypeFactory = TypeFactoryBase; + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/type_ptr.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/type_ptr.h new file mode 100644 index 0000000000000000000000000000000000000000..0859e04c7d2d834155af005b1f574a5182eb51fe --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/type_ptr.h @@ -0,0 +1,54 @@ +#pragma once + +#include +#include + +#include +#include + +namespace c10 { + +// Compatibility wrapper around a raw pointer so that existing code +// written to deal with a shared_ptr can keep working. +template +class SingletonTypePtr { + public: + /* implicit */ SingletonTypePtr(T* p) : repr_(p) {} + + // We need this to satisfy Pybind11, but it shouldn't be hit. + explicit SingletonTypePtr(std::shared_ptr) { TORCH_CHECK(false); } + + using element_type = typename std::shared_ptr::element_type; + + template , void>, bool> = true> + T& operator*() const { + return *repr_; + } + + T* get() const { + return repr_; + } + + T* operator->() const { + return repr_; + } + + operator bool() const { + return repr_ != nullptr; + } + + private: + T* repr_{nullptr}; +}; + +template +bool operator==(SingletonTypePtr lhs, SingletonTypePtr rhs) { + return (void*)lhs.get() == (void*)rhs.get(); +} + +template +bool operator!=(SingletonTypePtr lhs, SingletonTypePtr rhs) { + return !(lhs == rhs); +} + +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/typeid.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/typeid.h new file mode 100644 index 0000000000000000000000000000000000000000..5967c0a1659aadd9225d3f16f13275879c8bdbc9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/core/typeid.h @@ -0,0 +1 @@ +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/FlushDenormal.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/FlushDenormal.h new file mode 100644 index 0000000000000000000000000000000000000000..9bb1bfccc42a1971568346fbb6bce859d0f3018a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/FlushDenormal.h @@ -0,0 +1,14 @@ +/// Flush-To-Zero and Denormals-Are-Zero mode +/// +/// Flush-To-Zero (FTZ) and Denormals-Are-Zero (DAZ) are modes that bypass +/// IEEE 754 methods of dealing with denormal floating-point numbers on x86-64 +/// and some x86 CPUs. They result in reduced precision for values near zero, +/// but increased performance. +/// +/// See https://software.intel.com/en-us/articles/x87-and-sse-floating-point-assists-in-ia-32-flush-to-zero-ftz-and-denormals-are-zero-daz + +namespace at::cpu { + +bool set_flush_denormal(bool on); + +} // namespace at::cpu diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/Utils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/Utils.h new file mode 100644 index 0000000000000000000000000000000000000000..b339cb328b9bbbdbf77e773a7cc27dcedbb5518f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/Utils.h @@ -0,0 +1,33 @@ +#pragma once + +#include + +#include + +namespace at::cpu { + +TORCH_API bool is_avx2_supported(); +TORCH_API bool is_avx512_supported(); + +// Detect if CPU support Vector Neural Network Instruction. +TORCH_API bool is_avx512_vnni_supported(); + +// Detect if CPU supports AVX512_BF16 ISA +TORCH_API bool is_avx512_bf16_supported(); + +// Detect if CPU support Advanced Matrix Extension. +TORCH_API bool is_amx_tile_supported(); + +// Detect if CPU support Advanced Matrix Extension for fp16. +TORCH_API bool is_amx_fp16_supported(); + +// Enable the system to use AMX instructions. +TORCH_API bool init_amx(); + +// Get the L1 cache size per core in Byte +TORCH_API uint32_t L1d_cache_size(); + +// Get the L2 cache size per core in Byte +TORCH_API uint32_t L2_cache_size(); + +} // namespace at::cpu diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/functional.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/functional.h new file mode 100644 index 0000000000000000000000000000000000000000..388b3170d5b55a8c4bdd3af4ff982397fb323cb6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/functional.h @@ -0,0 +1,4 @@ +#pragma once + +#include +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/functional_base.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/functional_base.h new file mode 100644 index 0000000000000000000000000000000000000000..4d1d05ea8d32685172316c925883569f4d784334 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/functional_base.h @@ -0,0 +1,377 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include + +namespace at::vec { + +// slow path +template +inline scalar_t vec_reduce_all( + const Op& vec_fun, + vec::Vectorized acc_vec, + int64_t size) { + using Vec = vec::Vectorized; + scalar_t acc_arr[Vec::size()]; + acc_vec.store(acc_arr); + for (const auto i : c10::irange(1, size)) { + std::array acc_arr_next = {0}; + acc_arr_next[0] = acc_arr[i]; + Vec acc_vec_next = Vec::loadu(acc_arr_next.data()); + acc_vec = vec_fun(acc_vec, acc_vec_next); + } + acc_vec.store(acc_arr); + return acc_arr[0]; +} + +template +struct VecReduceAllSIMD { + static inline scalar_t apply(const Op& vec_fun, const Vectorized& acc_vec) { + return vec_reduce_all(vec_fun, acc_vec, Vectorized::size()); + } +}; + +#if defined(__GNUC__) && (__GNUC__ > 5) && !defined(_MSC_VER) && !defined(C10_MOBILE) +#if defined(CPU_CAPABILITY_AVX2) +template +struct VecReduceAllSIMD { + static inline float apply(const Op& vec_fun, const Vectorized& acc_vec) { + using Vec = Vectorized; + Vec v = acc_vec; + // 128-bit shuffle + Vec v1 = _mm256_permute2f128_ps(v, v, 0x1); + v = vec_fun(v, v1); + // 64-bit shuffle + v1 = _mm256_shuffle_ps(v, v, 0x4E); + v = vec_fun(v, v1); + // 32-bit shuffle + v1 = _mm256_shuffle_ps(v, v, 0xB1); + v = vec_fun(v, v1); + return _mm256_cvtss_f32(v); + } +}; +#endif // defined(CPU_CAPABILITY_AVX2) +#if defined(CPU_CAPABILITY_AVX512) +template +struct VecReduceAllSIMD { + static inline float apply(const Op& vec_fun, const Vectorized& acc_vec) { + using Vec = Vectorized; + Vec v = acc_vec; + // 256-bit shuffle + Vec v1 = _mm512_shuffle_f32x4(v, v, 0x4E); + v = vec_fun(v, v1); + // 128-bit shuffle + v1 = _mm512_shuffle_f32x4(v, v, 0xB1); + v = vec_fun(v, v1); + // 64-bit shuffle + v1 = _mm512_shuffle_ps(v, v, 0x4E); + v = vec_fun(v, v1); + // 32-bit shuffle + v1 = _mm512_shuffle_ps(v, v, 0xB1); + v = vec_fun(v, v1); + return _mm512_cvtss_f32(v); + } +}; +#endif // defined(CPU_CAPABILITY_AVX512) +#endif // defined(__GNUC__) && (__GNUC__ > 5) && !defined(_MSC_VER) && !defined(C10_MOBILE) + +#if defined(__aarch64__) && !defined(C10_MOBILE) && !defined(__CUDACC__) && !defined(CPU_CAPABILITY_SVE) +template +struct VecReduceAllSIMD { + static inline float apply(const Op& vec_fun, const Vectorized& acc_vec) { + using Vec = Vectorized; + Vec v = acc_vec; + + // 64-bit shuffle: [a1+a5, a2+a6, a3+a7, a4+a8, -, -, -, -] -> [a3+a7, a4+a8, a1+a5, a2+a6, -, -, -, -] + float32x4_t v1_1 = vextq_f32(v, v, 2); + Vec v1 = v1_1; + // [a1+a3+a5+a7, a2+a4+a6+a8, a1+a3+a5+a7, a2+a4+a6+a8, -, -, -, -] + v = vec_fun(v, v1); + + // 32-bit shuffle: [a1+a3+a5+a7, a2+a4+a6+a8, a1+a3+a5+a7, a2+a4+a6+a8, -, -, -, -] -> [a2+a4+a6+a8, a1+a3+a5+a7, a2+a4+a6+a8, a1+a3+a5+a7, -, -, -, -] + v1_1 = vrev64q_f32(v); + v1 = v1_1; + // [a1+a2+a3+a4+a5+a6+a7+a8, a1+a2+a3+a4+a5+a6+a7+a8, a1+a2+a3+a4+a5+a6+a7+a8, a1+a2+a3+a4+a5+a6+a7+a8, -, -, -, -] + v = vec_fun(v, v1); + + return v[0]; + } +}; +#endif // defined(__aarch64__) + +#if defined(__aarch64__) && !defined(C10_MOBILE) && !defined(__CUDACC__) && defined(CPU_CAPABILITY_SVE256) +template +struct VecReduceAllSIMD { + static inline float apply(const Op& vec_fun, const Vectorized& acc_vec) { + using Vec = Vectorized; + Vec v = acc_vec; + // 128-bit shuffle + svuint32_t ind = svdupq_n_u32(4, 5, 6, 7); + Vec v1 = svtbl_f32(v, ind); + v = vec_fun(v, v1); + // 64-bit shuffle + ind = svdupq_n_u32(2, 3, 0, 1); + v1 = svtbl_f32(v, ind); + v = vec_fun(v, v1); + // 32-bit shuffle + ind = svdupq_n_u32(1, 0, 2, 3); + v1 = svtbl_f32(v, ind); + v = vec_fun(v, v1); + return svlasta(svpfalse(), v); + } +}; +#endif // defined(__aarch64__) + + +template +inline scalar_t vec_reduce_all(const Op& vec_fun, const Vectorized& acc_vec) { + return VecReduceAllSIMD::apply(vec_fun, acc_vec); +} + +template , int> = 0> +inline scalar_t reduce_all(const Op& vec_fun, const scalar_t* data, int64_t size) { + using Vec = vec::Vectorized; + if (size < Vec::size()) + return vec_reduce_all(vec_fun, Vec::loadu(data, size), size); + int64_t d = Vec::size(); + Vec acc_vec = Vec::loadu(data); + for (; d < size - (size % Vec::size()); d += Vec::size()) { + Vec data_vec = Vec::loadu(data + d); + acc_vec = vec_fun(acc_vec, data_vec); + } + if (size - d > 0) { + Vec data_vec = Vec::loadu(data + d, size - d); + acc_vec = Vec::set(acc_vec, vec_fun(acc_vec, data_vec), size - d); + } + return vec_reduce_all(vec_fun, acc_vec); +} + +// similar to reduce_all, but reduces into two outputs +template , int> = 0> +inline std::pair reduce2_all(const Op1& vec_fun1, const Op2& vec_fun2, + const scalar_t* data, int64_t size) { + using Vec = vec::Vectorized; + if (size < Vec::size()) { + auto loaded_data = Vec::loadu(data, size); + return std::pair( + vec_reduce_all(vec_fun1, loaded_data, size), + vec_reduce_all(vec_fun2, loaded_data, size)); + } + int64_t d = Vec::size(); + Vec acc_vec1 = Vec::loadu(data); + Vec acc_vec2 = Vec::loadu(data); + for (; d < size - (size % Vec::size()); d += Vec::size()) { + Vec data_vec = Vec::loadu(data + d); + acc_vec1 = vec_fun1(acc_vec1, data_vec); + acc_vec2 = vec_fun2(acc_vec2, data_vec); + } + if (size - d > 0) { + Vec data_vec = Vec::loadu(data + d, size - d); + acc_vec1 = Vec::set(acc_vec1, vec_fun1(acc_vec1, data_vec), size - d); + acc_vec2 = Vec::set(acc_vec2, vec_fun2(acc_vec2, data_vec), size - d); + } + return std::pair( + vec_reduce_all(vec_fun1, acc_vec1), + vec_reduce_all(vec_fun2, acc_vec2)); +} + +template , int> = 0> +inline scalar_t map_reduce_all( + const MapOp& map_fun, + const ReduceOp& red_fun, + const scalar_t* data, + int64_t size) { + using Vec = vec::Vectorized; + if (size < Vec::size()) + return vec_reduce_all(red_fun, map_fun(Vec::loadu(data, size)), size); + int64_t d = Vec::size(); + Vec acc_vec = map_fun(Vec::loadu(data)); + for (; d < size - (size % Vec::size()); d += Vec::size()) { + Vec data_vec = Vec::loadu(data + d); + data_vec = map_fun(data_vec); + acc_vec = red_fun(acc_vec, data_vec); + } + if (size - d > 0) { + Vec data_vec = Vec::loadu(data + d, size - d); + data_vec = map_fun(data_vec); + acc_vec = Vec::set(acc_vec, red_fun(acc_vec, data_vec), size - d); + } + return vec_reduce_all(red_fun, acc_vec); +} + +template , int> = 0> +inline scalar_t map2_reduce_all( + const MapOp& map_fun, + const ReduceOp& red_fun, + const scalar_t* data, + const scalar_t* data2, + int64_t size) { + using Vec = vec::Vectorized; + if (size < Vec::size()) { + Vec data_vec = Vec::loadu(data, size); + Vec data2_vec = Vec::loadu(data2, size); + data_vec = map_fun(data_vec, data2_vec); + return vec_reduce_all(red_fun, data_vec, size); + } + int64_t d = Vec::size(); + Vec acc_vec = map_fun(Vec::loadu(data), Vec::loadu(data2)); + for (; d < size - (size % Vec::size()); d += Vec::size()) { + Vec data_vec = Vec::loadu(data + d); + Vec data2_vec = Vec::loadu(data2 + d); + data_vec = map_fun(data_vec, data2_vec); + acc_vec = red_fun(acc_vec, data_vec); + } + if (size - d > 0) { + Vec data_vec = Vec::loadu(data + d, size - d); + Vec data2_vec = Vec::loadu(data2 + d, size - d); + data_vec = map_fun(data_vec, data2_vec); + acc_vec = Vec::set(acc_vec, red_fun(acc_vec, data_vec), size - d); + } + return vec_reduce_all(red_fun, acc_vec); +} + +template , int> = 0> +inline scalar_t map3_reduce_all( + const MapOp& map_fun, + const ReduceOp& red_fun, + const scalar_t* data, + const scalar_t* data2, + const scalar_t* data3, + int64_t size) { + using Vec = vec::Vectorized; + if (size < Vec::size()) { + Vec data_vec = Vec::loadu(data, size); + Vec data2_vec = Vec::loadu(data2, size); + Vec data3_vec = Vec::loadu(data3, size); + data_vec = map_fun(data_vec, data2_vec, data3_vec); + return vec_reduce_all(red_fun, data_vec, size); + } + + int64_t d = Vec::size(); + Vec acc_vec = map_fun(Vec::loadu(data), Vec::loadu(data2), Vec::loadu(data3)); + for (; d < size - (size % Vec::size()); d += Vec::size()) { + Vec data_vec = Vec::loadu(data + d); + Vec data2_vec = Vec::loadu(data2 + d); + Vec data3_vec = Vec::loadu(data3 + d); + data_vec = map_fun(data_vec, data2_vec, data3_vec); + acc_vec = red_fun(acc_vec, data_vec); + } + if (size - d > 0) { + Vec data_vec = Vec::loadu(data + d, size - d); + Vec data2_vec = Vec::loadu(data2 + d, size - d); + Vec data3_vec = Vec::loadu(data3 + d, size - d); + data_vec = map_fun(data_vec, data2_vec, data3_vec); + acc_vec = Vec::set(acc_vec, red_fun(acc_vec, data_vec), size - d); + } + return vec_reduce_all(red_fun, acc_vec); +} + +template , int> = 0> +inline void map( + const Op& vec_fun, + scalar_t* output_data, + const scalar_t* input_data, + int64_t size) { + using Vec = vec::Vectorized; + int64_t d = 0; + for (; d < size - (size % Vec::size()); d += Vec::size()) { + Vec output_vec = vec_fun(Vec::loadu(input_data + d)); + output_vec.store(output_data + d); + } + if (size - d > 0) { + Vec output_vec = vec_fun(Vec::loadu(input_data + d, size - d)); + output_vec.store(output_data + d, size - d); + } +} + +template , int> = 0> +inline void map2( + const Op& vec_fun, + scalar_t* output_data, + const scalar_t* input_data, + const scalar_t* input_data2, + int64_t size) { + using Vec = vec::Vectorized; + int64_t d = 0; + for (; d < size - (size % Vec::size()); d += Vec::size()) { + Vec data_vec = Vec::loadu(input_data + d); + Vec data_vec2 = Vec::loadu(input_data2 + d); + Vec output_vec = vec_fun(data_vec, data_vec2); + output_vec.store(output_data + d); + } + if (size - d > 0) { + Vec data_vec = Vec::loadu(input_data + d, size - d); + Vec data_vec2 = Vec::loadu(input_data2 + d, size - d); + Vec output_vec = vec_fun(data_vec, data_vec2); + output_vec.store(output_data + d, size - d); + } +} + +template , int> = 0> +inline void map3( + const Op& vec_fun, + scalar_t* output_data, + const scalar_t* input_data1, + const scalar_t* input_data2, + const scalar_t* input_data3, + int64_t size) { + using Vec = vec::Vectorized; + int64_t d = 0; + for (; d < size - (size % Vec::size()); d += Vec::size()) { + Vec data_vec1 = Vec::loadu(input_data1 + d); + Vec data_vec2 = Vec::loadu(input_data2 + d); + Vec data_vec3 = Vec::loadu(input_data3 + d); + Vec output_vec = vec_fun(data_vec1, data_vec2, data_vec3); + output_vec.store(output_data + d); + } + if (size - d > 0) { + Vec data_vec1 = Vec::loadu(input_data1 + d, size - d); + Vec data_vec2 = Vec::loadu(input_data2 + d, size - d); + Vec data_vec3 = Vec::loadu(input_data3 + d, size - d); + Vec output_vec = vec_fun(data_vec1, data_vec2, data_vec3); + output_vec.store(output_data + d, size - d); + } +} + +template , int> = 0> +inline void map4( + const Op& vec_fun, + scalar_t* output_data, + const scalar_t* input_data1, + const scalar_t* input_data2, + const scalar_t* input_data3, + const scalar_t* input_data4, + int64_t size) { + using Vec = vec::Vectorized; + int64_t d = 0; + for (; d < size - (size % Vec::size()); d += Vec::size()) { + Vec data_vec1 = Vec::loadu(input_data1 + d); + Vec data_vec2 = Vec::loadu(input_data2 + d); + Vec data_vec3 = Vec::loadu(input_data3 + d); + Vec data_vec4 = Vec::loadu(input_data4 + d); + Vec output_vec = vec_fun(data_vec1, data_vec2, data_vec3, data_vec4); + output_vec.store(output_data + d); + } + if (size - d > 0) { + Vec data_vec1 = Vec::loadu(input_data1 + d, size - d); + Vec data_vec2 = Vec::loadu(input_data2 + d, size - d); + Vec data_vec3 = Vec::loadu(input_data3 + d, size - d); + Vec data_vec4 = Vec::loadu(input_data4 + d, size - d); + Vec output_vec = vec_fun(data_vec1, data_vec2, data_vec3, data_vec4); + output_vec.store(output_data + d, size - d); + } +} + +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/functional_bfloat16.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/functional_bfloat16.h new file mode 100644 index 0000000000000000000000000000000000000000..3bd22b3820f0b13d6d518329dd7df687ced37948 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/functional_bfloat16.h @@ -0,0 +1,549 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include + +namespace at::vec { + +// BFloat16 specification +template struct VecScalarType { using type = scalar_t; }; +template <> struct VecScalarType { using type = float; }; +template <> struct VecScalarType { using type = float; }; + +// This is different from at::acc_type since we only need to specialize BFloat16 +template +using vec_scalar_t = typename VecScalarType::type; + +// Vector conversion between float and bfloat16/half +template , int> = 0> +inline std::tuple, Vectorized> convert_to_float(const Vectorized&); + +template <> +inline std::tuple, Vectorized> convert_to_float (const Vectorized& a) { + return convert_bfloat16_float(a); +} + +template <> +inline std::tuple, Vectorized> convert_to_float (const Vectorized& a) { + return convert_half_float(a); +} + +template , int> = 0> +inline Vectorized convert_from_float(const Vectorized&, const Vectorized&); + +template <> +inline Vectorized convert_from_float(const Vectorized& a, const Vectorized& b) { + return convert_float_bfloat16(a, b); +} + +template <> +inline Vectorized convert_from_float(const Vectorized& a, const Vectorized& b) { + return convert_float_half(a, b); +} + +template , int> = 0> +inline void load_to_float(const scalar_t *data, Vectorized &out1, Vectorized &out2); + +template <> +inline void load_to_float (const BFloat16 *data, Vectorized &out1, Vectorized &out2) { + load_fp32_from_bf16(data, out1, out2); +} + +template <> +inline void load_to_float (const Half *data, Vectorized &out1, Vectorized &out2) { + load_fp32_from_fp16(data, out1, out2); +} + +template , int> = 0> +inline void load_to_float(const scalar_t *data, Vectorized &out); + +template <> +inline void load_to_float (const BFloat16 *data, Vectorized &out) { + load_fp32_from_bf16(data, out); +} + +template <> +inline void load_to_float (const Half *data, Vectorized &out) { + load_fp32_from_fp16(data, out); +} + +// Note that we already have specialized member of Vectorized for BFloat16 +// so the following functions would run smoothly: +// using Vec = Vectorized; +// Vec one = Vec(BFloat16(1)); +// vec::map([](Vec x) { return one / (one + x.exp()); }, y_ptr, x_ptr, N); +// +// Then why we still need to specialize "functional"? +// If we do specialization at Vectorized<> level, the above example would need 3 pairs of +// conversion of bf16->fp32/fp32->bf16, each for ".exp()", "+" and "/". +// If we do specialization at vec::map<>() level, we have only 1 pair of conversion +// of bf16->fp32/fp32->bf16, for the input and output BFloat16 vector only. +// +// The following BFloat16 functionality will only do data type conversion for input +// and output vector (reduce functionality will only convert the final scalar back to bf16). +// Compared to Vectorized<> specialization, +// 1. better performance since we have less data type conversion; +// 2. less rounding error since immediate results are kept in fp32; +// 3. accumulation done on data type of fp32. +// +// If you plan to extend this file, please ensure adding unit tests at +// aten/src/ATen/test/vec_test_all_types.cpp +// +template , int> = 0> +inline float reduce_all(const Op& vec_fun, const scalar_t* data, int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + if (size < bVec::size()) { + bVec data_bvec = bVec::loadu(data, size); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + if (size > fVec::size()) { + data_fvec0 = fVec::set(data_fvec0, vec_fun(data_fvec0, data_fvec1), size - fVec::size()); + return vec_reduce_all(vec_fun, data_fvec0, fVec::size()); + } else { + return vec_reduce_all(vec_fun, data_fvec0, size); + } + } + int64_t d = bVec::size(); + bVec acc_bvec = bVec::loadu(data); + auto [acc_fvec0, acc_fvec1] = convert_to_float(acc_bvec); + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec data_bvec = bVec::loadu(data + d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + acc_fvec0 = vec_fun(acc_fvec0, data_fvec0); + acc_fvec1 = vec_fun(acc_fvec1, data_fvec1); + } + if (size - d > 0) { + bVec data_bvec = bVec::loadu(data + d, size - d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + if (size - d > fVec::size()) { + acc_fvec0 = vec_fun(acc_fvec0, data_fvec0); + acc_fvec1 = fVec::set(acc_fvec1, vec_fun(acc_fvec1, data_fvec1), size - d - fVec::size()); + } else { + acc_fvec0 = fVec::set(acc_fvec0, vec_fun(acc_fvec0, data_fvec0), size - d); + } + } + acc_fvec0 = vec_fun(acc_fvec0, acc_fvec1); + return vec_reduce_all(vec_fun, acc_fvec0); +} + +template , int> = 0> +inline std::pair reduce2_all(const Op1& vec_fun1, const Op2& vec_fun2, + const scalar_t* data, int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + if (size < bVec::size()) { + bVec data_bvec = bVec::loadu(data, size); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + if (size > fVec::size()) { + fVec acc1_fvec = fVec::set(data_fvec0, vec_fun1(data_fvec0, data_fvec1), size - fVec::size()); + fVec acc2_fvec = fVec::set(data_fvec0, vec_fun2(data_fvec0, data_fvec1), size - fVec::size()); + return std::pair( + vec_reduce_all(vec_fun1, acc1_fvec, fVec::size()), + vec_reduce_all(vec_fun2, acc2_fvec, fVec::size())); + } else { + return std::pair( + vec_reduce_all(vec_fun1, data_fvec0, size), + vec_reduce_all(vec_fun2, data_fvec0, size)); + } + } + int64_t d = bVec::size(); + bVec acc_bvec = bVec::loadu(data); + auto [acc1_fvec0, acc1_fvec1] = convert_to_float(acc_bvec); + auto [acc2_fvec0, acc2_fvec1] = convert_to_float(acc_bvec); + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec data_bvec = bVec::loadu(data + d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + acc1_fvec0 = vec_fun1(acc1_fvec0, data_fvec0); + acc1_fvec1 = vec_fun1(acc1_fvec1, data_fvec1); + acc2_fvec0 = vec_fun2(acc2_fvec0, data_fvec0); + acc2_fvec1 = vec_fun2(acc2_fvec1, data_fvec1); + } + if (size - d > 0) { + bVec data_bvec = bVec::loadu(data + d, size - d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + if (size - d > fVec::size()) { + acc1_fvec0 = vec_fun1(acc1_fvec0, data_fvec0); + acc1_fvec1 = fVec::set(acc1_fvec1, vec_fun1(acc1_fvec1, data_fvec1), size - d - fVec::size()); + acc2_fvec0 = vec_fun2(acc2_fvec0, data_fvec0); + acc2_fvec1 = fVec::set(acc2_fvec1, vec_fun2(acc2_fvec1, data_fvec1), size - d - fVec::size()); + } else { + acc1_fvec0 = fVec::set(acc1_fvec0, vec_fun1(acc1_fvec0, data_fvec0), size - d); + acc2_fvec0 = fVec::set(acc2_fvec0, vec_fun2(acc2_fvec0, data_fvec0), size - d); + } + } + acc1_fvec0 = vec_fun1(acc1_fvec0, acc1_fvec1); + acc2_fvec0 = vec_fun2(acc2_fvec0, acc2_fvec1); + return std::pair( + vec_reduce_all(vec_fun1, acc1_fvec0), + vec_reduce_all(vec_fun2, acc2_fvec0)); +} + +template , int> = 0> +inline float map_reduce_all( + const MapOp& map_fun, + const ReduceOp& red_fun, + const scalar_t* data, + int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + if (size < bVec::size()) { + bVec data_bvec = bVec::loadu(data, size); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + if (size > fVec::size()) { + data_fvec0 = map_fun(data_fvec0); + data_fvec1 = map_fun(data_fvec1); + data_fvec0 = fVec::set(data_fvec0, red_fun(data_fvec0, data_fvec1), size - fVec::size()); + return vec_reduce_all(red_fun, data_fvec0, fVec::size()); + } else { + data_fvec0 = map_fun(data_fvec0); + return vec_reduce_all(red_fun, data_fvec0, size); + } + } + int64_t d = bVec::size(); + bVec acc_bvec = bVec::loadu(data); + auto [acc_fvec0, acc_fvec1] = convert_to_float(acc_bvec); + acc_fvec0 = map_fun(acc_fvec0); + acc_fvec1 = map_fun(acc_fvec1); + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec data_bvec = bVec::loadu(data + d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + data_fvec0 = map_fun(data_fvec0); + data_fvec1 = map_fun(data_fvec1); + acc_fvec0 = red_fun(acc_fvec0, data_fvec0); + acc_fvec1 = red_fun(acc_fvec1, data_fvec1); + } + if (size - d > 0) { + bVec data_bvec = bVec::loadu(data + d, size - d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + if (size - d > fVec::size()) { + data_fvec0 = map_fun(data_fvec0); + data_fvec1 = map_fun(data_fvec1); + acc_fvec0 = red_fun(acc_fvec0, data_fvec0); + acc_fvec1 = fVec::set(acc_fvec1, red_fun(acc_fvec1, data_fvec1), size - d - fVec::size()); + } else { + data_fvec0 = map_fun(data_fvec0); + acc_fvec0 = fVec::set(acc_fvec0, red_fun(acc_fvec0, data_fvec0), size - d); + } + } + acc_fvec0 = red_fun(acc_fvec0, acc_fvec1); + return vec_reduce_all(red_fun, acc_fvec0); +} + +template , int> = 0> +inline float map2_reduce_all( + const MapOp& map_fun, + const ReduceOp& red_fun, + const scalar_t* data, + const scalar_t* data2, + int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + if (size < bVec::size()) { + bVec data_bvec = bVec::loadu(data, size); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + bVec data2_bvec = bVec::loadu(data2, size); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + if (size > fVec::size()) { + data_fvec0 = map_fun(data_fvec0, data2_fvec0); + data_fvec1 = map_fun(data_fvec1, data2_fvec1); + data_fvec0 = fVec::set(data_fvec0, red_fun(data_fvec0, data_fvec1), size - fVec::size()); + return vec_reduce_all(red_fun, data_fvec0, fVec::size()); + } else { + data_fvec0 = map_fun(data_fvec0, data2_fvec0); + return vec_reduce_all(red_fun, data_fvec0, size); + } + } + int64_t d = bVec::size(); + bVec acc_bvec = bVec::loadu(data); + auto [acc_fvec0, acc_fvec1] = convert_to_float(acc_bvec); + bVec acc2_bvec = bVec::loadu(data2); + auto [acc2_fvec0, acc2_fvec1] = convert_to_float(acc2_bvec); + acc_fvec0 = map_fun(acc_fvec0, acc2_fvec0); + acc_fvec1 = map_fun(acc_fvec1, acc2_fvec1); + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec data_bvec = bVec::loadu(data + d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + bVec data2_bvec = bVec::loadu(data2 + d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + data_fvec0 = map_fun(data_fvec0, data2_fvec0); + data_fvec1 = map_fun(data_fvec1, data2_fvec1); + acc_fvec0 = red_fun(acc_fvec0, data_fvec0); + acc_fvec1 = red_fun(acc_fvec1, data_fvec1); + } + if (size - d > 0) { + bVec data_bvec = bVec::loadu(data + d, size - d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + bVec data2_bvec = bVec::loadu(data2 + d, size - d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + if (size - d > fVec::size()) { + data_fvec0 = map_fun(data_fvec0, data2_fvec0); + data_fvec1 = map_fun(data_fvec1, data2_fvec1); + acc_fvec0 = red_fun(acc_fvec0, data_fvec0); + acc_fvec1 = fVec::set(acc_fvec1, red_fun(acc_fvec1, data_fvec1), size - d - fVec::size()); + } else { + data_fvec0 = map_fun(data_fvec0, data2_fvec0); + acc_fvec0 = fVec::set(acc_fvec0, red_fun(acc_fvec0, data_fvec0), size - d); + } + } + acc_fvec0 = red_fun(acc_fvec0, acc_fvec1); + return vec_reduce_all(red_fun, acc_fvec0); +} + +template , int> = 0> +inline float map3_reduce_all( + const MapOp& map_fun, + const ReduceOp& red_fun, + const scalar_t* data, + const scalar_t* data2, + const scalar_t* data3, + int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + if (size < bVec::size()) { + bVec data_bvec = bVec::loadu(data, size); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + bVec data2_bvec = bVec::loadu(data2, size); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + bVec data3_bvec = bVec::loadu(data3, size); + auto [data3_fvec0, data3_fvec1] = convert_to_float(data3_bvec); + if (size > fVec::size()) { + data_fvec0 = map_fun(data_fvec0, data2_fvec0, data3_fvec0); + data_fvec1 = map_fun(data_fvec1, data2_fvec1, data3_fvec1); + data_fvec0 = fVec::set(data_fvec0, red_fun(data_fvec0, data_fvec1), size - fVec::size()); + return vec_reduce_all(red_fun, data_fvec0, fVec::size()); + } else { + data_fvec0 = map_fun(data_fvec0, data2_fvec0, data3_fvec0); + return vec_reduce_all(red_fun, data_fvec0, size); + } + } + int64_t d = bVec::size(); + bVec acc_bvec = bVec::loadu(data); + auto [acc_fvec0, acc_fvec1] = convert_to_float(acc_bvec); + bVec acc2_bvec = bVec::loadu(data2); + auto [acc2_fvec0, acc2_fvec1] = convert_to_float(acc2_bvec); + bVec acc3_bvec = bVec::loadu(data3); + auto [acc3_fvec0, acc3_fvec1] = convert_to_float(acc3_bvec); + acc_fvec0 = map_fun(acc_fvec0, acc2_fvec0, acc3_fvec0); + acc_fvec1 = map_fun(acc_fvec1, acc2_fvec1, acc3_fvec1); + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec data_bvec = bVec::loadu(data + d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + bVec data2_bvec = bVec::loadu(data2 + d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + bVec data3_bvec = bVec::loadu(data3 + d); + auto [data3_fvec0, data3_fvec1] = convert_to_float(data3_bvec); + data_fvec0 = map_fun(data_fvec0, data2_fvec0, data3_fvec0); + data_fvec1 = map_fun(data_fvec1, data2_fvec1, data3_fvec1); + acc_fvec0 = red_fun(acc_fvec0, data_fvec0); + acc_fvec1 = red_fun(acc_fvec1, data_fvec1); + } + if (size - d > 0) { + bVec data_bvec = bVec::loadu(data + d, size - d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + bVec data2_bvec = bVec::loadu(data2 + d, size - d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + bVec data3_bvec = bVec::loadu(data3 + d, size - d); + auto [data3_fvec0, data3_fvec1] = convert_to_float(data3_bvec); + if (size - d > fVec::size()) { + data_fvec0 = map_fun(data_fvec0, data2_fvec0, data3_fvec0); + data_fvec1 = map_fun(data_fvec1, data2_fvec1, data3_fvec1); + acc_fvec0 = red_fun(acc_fvec0, data_fvec0); + acc_fvec1 = fVec::set(acc_fvec1, red_fun(acc_fvec1, data_fvec1), size - d - fVec::size()); + } else { + data_fvec0 = map_fun(data_fvec0, data2_fvec0, data3_fvec0); + acc_fvec0 = fVec::set(acc_fvec0, red_fun(acc_fvec0, data_fvec0), size - d); + } + } + acc_fvec0 = red_fun(acc_fvec0, acc_fvec1); + return vec_reduce_all(red_fun, acc_fvec0); +} + +template , int> = 0> +inline void map( + const Op& vec_fun, + scalar_t* output_data, + const scalar_t* input_data, + int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + int64_t d = 0; + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec data_bvec = bVec::loadu(input_data + d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + fVec output_fvec0 = vec_fun(data_fvec0); + fVec output_fvec1 = vec_fun(data_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d); + } + if (size - d > 0) { + bVec data_bvec = bVec::loadu(input_data + d, size - d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + fVec output_fvec0 = vec_fun(data_fvec0); + fVec output_fvec1 = vec_fun(data_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d, size - d); + } +} + +template , int> = 0> +inline void map( + const Op& vec_fun, + scalar_t* output_data, + const float* input_data, + int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + int64_t d = 0; + for (; d < size - (size % bVec::size()); d += bVec::size()) { + fVec data_fvec0 = fVec::loadu(input_data + d); + fVec data_fvec1 = fVec::loadu(input_data + d + fVec::size()); + fVec output_fvec0 = vec_fun(data_fvec0); + fVec output_fvec1 = vec_fun(data_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d); + } + if (size - d > 0) { + fVec data_fvec0, data_fvec1; + if (size - d > fVec::size()) { + data_fvec0 = fVec::loadu(input_data + d); + data_fvec1 = fVec::loadu(input_data + d + fVec::size(), size - d - fVec::size()); + } else { + // choose to align with behaviour of bVec::loadu(ptr, size), + // which leaves data_fvec1 uninitialized + data_fvec0 = fVec::loadu(input_data + d, size - d); + } + fVec output_fvec0 = vec_fun(data_fvec0); + fVec output_fvec1 = vec_fun(data_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d, size - d); + } +} + +template , int> = 0> +inline void map2( + const Op& vec_fun, + scalar_t* output_data, + const scalar_t* input_data, + const scalar_t* input_data2, + int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + int64_t d = 0; + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec data_bvec = bVec::loadu(input_data + d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + bVec data2_bvec = bVec::loadu(input_data2 + d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + fVec output_fvec0 = vec_fun(data_fvec0, data2_fvec0); + fVec output_fvec1 = vec_fun(data_fvec1, data2_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d); + } + if (size - d > 0) { + bVec data_bvec = bVec::loadu(input_data + d, size - d); + auto [data_fvec0, data_fvec1] = convert_to_float(data_bvec); + bVec data2_bvec = bVec::loadu(input_data2 + d, size - d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + fVec output_fvec0 = vec_fun(data_fvec0, data2_fvec0); + fVec output_fvec1 = vec_fun(data_fvec1, data2_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d, size - d); + } +} + +template , int> = 0> +inline void map3( + const Op& vec_fun, + scalar_t* output_data, + const scalar_t* input_data1, + const scalar_t* input_data2, + const scalar_t* input_data3, + int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + int64_t d = 0; + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec data1_bvec = bVec::loadu(input_data1 + d); + auto [data1_fvec0, data1_fvec1] = convert_to_float(data1_bvec); + bVec data2_bvec = bVec::loadu(input_data2 + d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + bVec data3_bvec = bVec::loadu(input_data3 + d); + auto [data3_fvec0, data3_fvec1] = convert_to_float(data3_bvec); + fVec output_fvec0 = vec_fun(data1_fvec0, data2_fvec0, data3_fvec0); + fVec output_fvec1 = vec_fun(data1_fvec1, data2_fvec1, data3_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d); + } + if (size - d > 0) { + bVec data1_bvec = bVec::loadu(input_data1 + d, size - d); + auto [data1_fvec0, data1_fvec1] = convert_to_float(data1_bvec); + bVec data2_bvec = bVec::loadu(input_data2 + d, size - d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + bVec data3_bvec = bVec::loadu(input_data3 + d, size - d); + auto [data3_fvec0, data3_fvec1] = convert_to_float(data3_bvec); + fVec output_fvec0 = vec_fun(data1_fvec0, data2_fvec0, data3_fvec0); + fVec output_fvec1 = vec_fun(data1_fvec1, data2_fvec1, data3_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d, size - d); + } +} + +template , int> = 0> +inline void map4( + const Op& vec_fun, + scalar_t* output_data, + const scalar_t* input_data1, + const scalar_t* input_data2, + const scalar_t* input_data3, + const scalar_t* input_data4, + int64_t size) { + using bVec = vec::Vectorized; + using fVec = vec::Vectorized; + int64_t d = 0; + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec data1_bvec = bVec::loadu(input_data1 + d); + auto [data1_fvec0, data1_fvec1] = convert_to_float(data1_bvec); + bVec data2_bvec = bVec::loadu(input_data2 + d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + bVec data3_bvec = bVec::loadu(input_data3 + d); + auto [data3_fvec0, data3_fvec1] = convert_to_float(data3_bvec); + bVec data4_bvec = bVec::loadu(input_data4 + d); + auto [data4_fvec0, data4_fvec1] = convert_to_float(data4_bvec); + fVec output_fvec0 = vec_fun(data1_fvec0, data2_fvec0, data3_fvec0, data4_fvec0); + fVec output_fvec1 = vec_fun(data1_fvec1, data2_fvec1, data3_fvec1, data4_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d); + } + if (size - d > 0) { + bVec data1_bvec = bVec::loadu(input_data1 + d, size - d); + auto [data1_fvec0, data1_fvec1] = convert_to_float(data1_bvec); + bVec data2_bvec = bVec::loadu(input_data2 + d, size - d); + auto [data2_fvec0, data2_fvec1] = convert_to_float(data2_bvec); + bVec data3_bvec = bVec::loadu(input_data3 + d, size - d); + auto [data3_fvec0, data3_fvec1] = convert_to_float(data3_bvec); + bVec data4_bvec = bVec::loadu(input_data4 + d, size - d); + auto [data4_fvec0, data4_fvec1] = convert_to_float(data4_bvec); + fVec output_fvec0 = vec_fun(data1_fvec0, data2_fvec0, data3_fvec0, data4_fvec0); + fVec output_fvec1 = vec_fun(data1_fvec1, data2_fvec1, data3_fvec1, data4_fvec1); + bVec output_bvec = convert_from_float(output_fvec0, output_fvec1); + output_bvec.store(output_data + d, size - d); + } +} + +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/intrinsics.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/intrinsics.h new file mode 100644 index 0000000000000000000000000000000000000000..48b18793b079e75c8b63aa8d1f8319d1ba31e21f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/intrinsics.h @@ -0,0 +1,51 @@ +#pragma once +#if defined(__GNUC__) && (defined(__x86_64__) || defined(__i386__)) +/* GCC or clang-compatible compiler, targeting x86/x86-64 */ +#include +#elif defined(__clang__) && (defined(__ARM_NEON__) || defined(__aarch64__)) +/* Clang-compatible compiler, targeting arm neon */ +#include +#if defined(__ARM_FEATURE_SVE) +/* CLANG-compatible compiler, targeting ARM with SVE */ +#include +#endif +#elif defined(_MSC_VER) +/* Microsoft C/C++-compatible compiler */ +#include +#if _MSC_VER <= 1900 +#define _mm256_extract_epi64(X, Y) (_mm_extract_epi64(_mm256_extractf128_si256(X, Y >> 1), Y % 2)) +#define _mm256_extract_epi32(X, Y) (_mm_extract_epi32(_mm256_extractf128_si256(X, Y >> 2), Y % 4)) +#define _mm256_extract_epi16(X, Y) (_mm_extract_epi16(_mm256_extractf128_si256(X, Y >> 3), Y % 8)) +#define _mm256_extract_epi8(X, Y) (_mm_extract_epi8(_mm256_extractf128_si256(X, Y >> 4), Y % 16)) +#endif +#elif defined(__GNUC__) && (defined(__ARM_NEON__) || defined(__aarch64__)) +/* GCC-compatible compiler, targeting ARM with NEON */ +#include +#if defined(__ARM_FEATURE_SVE) +/* GCC-compatible compiler, targeting ARM with SVE */ +#include +#endif +#if defined (MISSING_ARM_VLD1) +#include +#elif defined (MISSING_ARM_VST1) +#include +#endif +#elif defined(__GNUC__) && defined(__IWMMXT__) +/* GCC-compatible compiler, targeting ARM with WMMX */ +#include +#elif defined(__s390x__) +// targets Z/architecture +// we will include vecintrin later +#elif (defined(__GNUC__) || defined(__xlC__)) && \ + (defined(__VEC__) || defined(__ALTIVEC__)) +/* XLC or GCC-compatible compiler, targeting PowerPC with VMX/VSX */ +#include +/* We need to undef those tokens defined by to avoid conflicts + with the C++ types. => Can still use __bool/__vector */ +#undef bool +#undef vector +#undef pixel +#elif defined(__GNUC__) && defined(__SPE__) +/* GCC-compatible compiler, targeting PowerPC with SPE */ +#include +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/sve_helper.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/sve_helper.h new file mode 100644 index 0000000000000000000000000000000000000000..e511ebb52b2e905776f43343c4b0f2ac1f48daaf --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/sve_helper.h @@ -0,0 +1,63 @@ +#pragma once + +#include + +#include + +#if defined(CPU_CAPABILITY_SVE) + +// Define the data type of VLS(vector-length specific). +typedef svbool_t vls_pred_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svint8_t vls_int8_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svint16_t vls_int16_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svint32_t vls_int32_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svint64_t vls_int64_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svuint8_t vls_uint8_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svuint16_t vls_uint16_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svuint32_t vls_uint32_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svuint64_t vls_uint64_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svfloat16_t vls_float16_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svfloat32_t vls_float32_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); +typedef svfloat64_t vls_float64_t __attribute__((arm_sve_vector_bits(VECTOR_WIDTH * 8))); + +#define ptrue svptrue_b8() +#define ZERO_S8 svdup_n_s8(0) +#define ZERO_S16 svdup_n_s16(0) +#define ZERO_S32 svdup_n_s32(0) +#define ZERO_S64 svdup_n_s64(0) +#define ZERO_U8 svdup_n_u8(0) +#define ZERO_U16 svdup_n_u16(0) +#define ZERO_U32 svdup_n_u32(0) +#define ZERO_U64 svdup_n_u64(0) +#define ZERO_F16 svdup_n_f16(0.f) +#define ZERO_F32 svdup_n_f32(0.f) +#define ZERO_F64 svdup_n_f64(0.0) +#define ONE_S8 svdup_n_s8(1) +#define ONE_S16 svdup_n_s16(1) +#define ONE_S32 svdup_n_s32(1) +#define ONE_S64 svdup_n_s64(1) +#define ONE_U8 svdup_n_u8(1) +#define ONE_U16 svdup_n_u16(1) +#define ONE_U32 svdup_n_u32(1) +#define ONE_U64 svdup_n_u64(1) +#define ONE_F16 svdup_n_f16(1.f) +#define ONE_F32 svdup_n_f32(1.f) +#define ONE_F64 svdup_n_f64(1.0) +#define ALL_S8_TRUE_MASK svdup_n_s8(0xff) +#define ALL_S8_FALSE_MASK svdup_n_s8(0x0) +#define ALL_S16_TRUE_MASK svdup_n_s16(0xffff) +#define ALL_S16_FALSE_MASK svdup_n_s16(0x0) +#define ALL_S32_TRUE_MASK svdup_n_s32(0xffffffff) +#define ALL_S32_FALSE_MASK svdup_n_s32(0x0) +#define ALL_S64_TRUE_MASK svdup_n_s64(0xffffffffffffffff) +#define ALL_S64_FALSE_MASK svdup_n_s64(0x0) +#define ALL_U8_TRUE_MASK svdup_n_u8(0x01) +#define ALL_U8_FALSE_MASK svdup_n_u8(0x00) +#define ALL_F16_TRUE_MASK svreinterpret_f16_s16(ALL_S16_TRUE_MASK) +#define ALL_F16_FALSE_MASK svreinterpret_f16_s16(ALL_S16_FALSE_MASK) +#define ALL_F32_TRUE_MASK svreinterpret_f32_s32(ALL_S32_TRUE_MASK) +#define ALL_F32_FALSE_MASK svreinterpret_f32_s32(ALL_S32_FALSE_MASK) +#define ALL_F64_TRUE_MASK svreinterpret_f64_s64(ALL_S64_TRUE_MASK) +#define ALL_F64_FALSE_MASK svreinterpret_f64_s64(ALL_S64_FALSE_MASK) + +#endif // defined(CPU_CAPABILITY_SVE) diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_common_sve.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_common_sve.h new file mode 100644 index 0000000000000000000000000000000000000000..c7968e271f91a2c42290e6a6df642b948920b423 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_common_sve.h @@ -0,0 +1,176 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with SVE] + +#include + +#include +#include + +#if defined(CPU_CAPABILITY_SVE) +#include +#include +#include +#include +#endif + + +namespace at::vec { +// Note [CPU_CAPABILITY namespace] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// This header, and all of its subheaders, will be compiled with +// different architecture flags for each supported set of vector +// intrinsics. So we need to make sure they aren't inadvertently +// linked together. We do this by declaring objects in an `inline +// namespace` which changes the name mangling, but can still be +// accessed as `at::vec`. +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_SVE) + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ CAST ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template<> +inline Vectorized cast(const Vectorized& src) { + return svreinterpret_f32_f64(src); +} + +template<> +inline Vectorized cast(const Vectorized& src) { + return svreinterpret_f64_f32(src); +} + +#define DEFINE_FLOAT_INT_CAST(int_t, int_bit, float_t, float_bit) \ +template<> \ +inline Vectorized cast(const Vectorized& src) { \ + return svreinterpret_s##int_bit##_f##float_bit(src); \ +} \ +template<> \ +inline Vectorized cast(const Vectorized& src) { \ + return svreinterpret_f##float_bit##_s##int_bit(src); \ +} + +DEFINE_FLOAT_INT_CAST(int64_t, 64, double, 64) +DEFINE_FLOAT_INT_CAST(int32_t, 32, double, 64) +DEFINE_FLOAT_INT_CAST(int16_t, 16, double, 64) +DEFINE_FLOAT_INT_CAST(int64_t, 64, float, 32) +DEFINE_FLOAT_INT_CAST(int32_t, 32, float, 32) +DEFINE_FLOAT_INT_CAST(int16_t, 16, float, 32) + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ GATHER ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template +std::enable_if_t> +inline gather(const double* base_addr, const Vectorized& vindex_) { + svint64_t vindex = svasrd_n_s64_x(ptrue, svmul_s64_x(ptrue, vindex_, svdup_n_s64(scale)), 3); + return svld1_gather_s64index_f64(ptrue, base_addr, vindex); +} + +template +std::enable_if_t> +inline gather(const float* base_addr, const Vectorized& vindex_) { + svint32_t vindex = svasrd_n_s32_x(ptrue, svmul_s32_x(ptrue, vindex_, svdup_n_s32(scale)), 2); + return svld1_gather_s32index_f32(ptrue, base_addr, vindex); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ MASK GATHER ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template +std::enable_if_t> +inline mask_gather(const Vectorized& src, const double* base_addr, + const Vectorized& vindex_, const Vectorized& mask_) { + svbool_t mask = svcmpeq_s64(ptrue, svreinterpret_s64_f64(mask_), + ALL_S64_TRUE_MASK); + svint64_t vindex = svasrd_n_s64_x(ptrue, svmul_s64_x(ptrue, vindex_, svdup_n_s64(scale)), 3); + return svsel_f64(mask, svld1_gather_s64index_f64(mask, base_addr, vindex), src); +} + +template +std::enable_if_t> +inline mask_gather(const Vectorized& src, const float* base_addr, + const Vectorized& vindex_, const Vectorized& mask_) { + svbool_t mask = svcmpeq_s32(ptrue, svreinterpret_s32_f32(mask_), + ALL_S32_TRUE_MASK); + svint32_t vindex = svasrd_n_s32_x(ptrue, svmul_s32_x(ptrue, vindex_, svdup_n_s32(scale)), 2); + return svsel_f32(mask, svld1_gather_s32index_f32(mask, base_addr, vindex), src); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ CONVERT ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +// Only works for inputs in the range: [-2^51, 2^51] +// From: https://stackoverflow.com/a/41148578 +template<> +Vectorized +inline convert_to_int_of_same_size(const Vectorized &src) { + svfloat64_t x = svadd_f64_x(ptrue, src, svdup_n_f64(0x0018000000000000)); + return svsub_s64_x(ptrue, + svreinterpret_s64_f64(x), + svreinterpret_s64_f64(svdup_n_f64(0x0018000000000000))); +} + +template<> +Vectorized +inline convert_to_int_of_same_size(const Vectorized &src) { + return svcvt_s32_f32_x(ptrue, src); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ INTERLEAVE ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template <> +std::pair, Vectorized> +inline interleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, a1, a3, a3} + // b = {b0, b1, b2, b3} + // group cols crossing lanes: + // return {a0, b0, a1, b1} + // {a2, b2, a3, b3} + return std::make_pair(Vectorized(svzip1_f64(a, b)), + Vectorized(svzip2_f64(a, b))); +} + +template <> +std::pair, Vectorized> +inline interleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, a1, a2, a3, a4, a5, a6, a7} + // b = {b0, b1, b2, b3, b4, b5, b6, b7} + // group cols crossing lanes: + // return {a0, b0, a1, b1, a2, b2, a3, b3} + // {a4, b4, a5, b5, a6, b6, a7, b7} + return std::make_pair(Vectorized(svzip1_f32(a, b)), + Vectorized(svzip2_f32(a, b))); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ DEINTERLEAVE ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template <> +std::pair, Vectorized> +inline deinterleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1} + // b = {a2, b2, a3, b3} + // swap lanes: + // return {a0, a1, a2, a3} + // {b0, b1, b2, b3} + return std::make_pair(Vectorized(svuzp1_f64(a, b)), + Vectorized(svuzp2_f64(a, b))); +} + +template <> +std::pair, Vectorized> +inline deinterleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1, a2, b2, a3, b3} + // b = {a4, b4, a5, b5, a6, b6, a7, b7} + // swap lanes: + // return {a0, a1, a2, a3, a4, a5, a6, a7} + // {b0, b1, b2, b3, b4, b5, b6, b7} + return std::make_pair(Vectorized(svuzp1_f32(a, b)), + Vectorized(svuzp2_f32(a, b))); +} + +#endif // defined(CPU_CAPABILITY_SVE) + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_double.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_double.h new file mode 100644 index 0000000000000000000000000000000000000000..23626e29ce1c7d3027bc6190433b25379dc6ff4a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_double.h @@ -0,0 +1,524 @@ +#pragma once + +#include +#include +#include +#include +#if defined(__aarch64__) && defined(AT_BUILD_ARM_VEC256_WITH_SLEEF) +#include +#define USE_SLEEF(sleef_code, non_sleef_code) sleef_code +#else +#define USE_SLEEF(sleef_code, non_sleef_code) non_sleef_code +#endif + +namespace at::vec { +// Note [CPU_CAPABILITY namespace] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// This header, and all of its subheaders, will be compiled with +// different architecture flags for each supported set of vector +// intrinsics. So we need to make sure they aren't inadvertently +// linked together. We do this by declaring objects in an `inline +// namespace` which changes the name mangling, but can still be +// accessed as `at::vec`. +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_SVE) + +template <> class Vectorized { +private: + vls_float64_t values; +public: + using value_type = double; + using size_type = int; + static constexpr size_type size() { + return VECTOR_WIDTH / sizeof(double); + } + Vectorized() {} + Vectorized(svfloat64_t v) : values(v) {} + Vectorized(double val) { + values = svdup_n_f64(val); + } + template> + Vectorized(Args... vals) { + __at_align__ double buffer[size()] = { vals... }; + values = svld1_f64(ptrue, buffer); + } + operator svfloat64_t() const { + return values; + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + // Build an array of flags: each element is 1 if the corresponding bit in 'mask' is set, 0 otherwise. + __at_align__ int64_t flag_arr[size()]; + for (int i = 0; i < size(); i++) { + flag_arr[i] = (mask & (1ULL << i)) ? 1 : 0; + } + // Load the flag array into an SVE int64 vector. + svint64_t int_mask = svld1_s64(svptrue_b64(), flag_arr); + // Compare each lane of int_mask to 0; returns an svbool_t predicate where true indicates a nonzero flag. + svbool_t blend_mask = svcmpne_n_s64(svptrue_b64(), int_mask, 0); + + // Use svsel to select elements from b where the predicate is true, else from a. + svfloat64_t result = svsel(blend_mask, b.values, a.values); + return Vectorized(result); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask_) { + svbool_t mask = svcmpeq_s64(ptrue, svreinterpret_s64_f64(mask_), + ALL_S64_TRUE_MASK); + return svsel_f64(mask, b, a); + } + template + static Vectorized arange(double base = 0., step_t step = static_cast(1)) { + __at_align__ double buffer[size()]; + for (int64_t i = 0; i < size(); i++) { + buffer[i] = base + i * step; + } + return svld1_f64(ptrue, buffer); + } + static Vectorized set(const Vectorized& a, const Vectorized& b, + int64_t count = size()) { + if (count == 0) { + return a; + } else if (count < size()) { + return svsel_f64(svwhilelt_b64(0ull, count), b, a); + } + return b; + } + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return svld1_f64(ptrue, reinterpret_cast(ptr)); + svbool_t pg = svwhilelt_b64(0ull, count); + return svld1_f64(pg, reinterpret_cast(ptr)); + } + void store(void* ptr, int64_t count = size()) const { + if (count == size()) { + svst1_f64(ptrue, reinterpret_cast(ptr), values); + } else { + svbool_t pg = svwhilelt_b64(0ull, count); + svst1_f64(pg, reinterpret_cast(ptr), values); + } + } + const double& operator[](int idx) const = delete; + double& operator[](int idx) = delete; + int64_t zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit and others are translated to 0-bit + int64_t mask = 0; + __at_align__ int64_t mask_array[size()]; + + svbool_t svbool_mask = svcmpeq_f64(ptrue, values, ZERO_F64); + svst1_s64(ptrue, mask_array, svsel_s64(svbool_mask, + ALL_S64_TRUE_MASK, + ALL_S64_FALSE_MASK)); + for (int64_t i = 0; i < size(); ++i) { + if (mask_array[i]) mask |= (1ull << i); + } + return mask; + } + Vectorized isnan() const { + // NaN check + svbool_t mask = svcmpuo_f64(ptrue, values, ZERO_F64); + return svsel_f64(mask, ALL_F64_TRUE_MASK, ALL_F64_FALSE_MASK); + } + bool has_inf_nan() const { + return svptest_any(ptrue, svcmpuo_f64(ptrue, svsub_f64_x(ptrue, values, values), ZERO_F64)); + } + Vectorized map(double (*f)(double)) const { + __at_align__ double tmp[size()]; + store(tmp); + for (int64_t i = 0; i < size(); ++i) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + Vectorized abs() const { + return svabs_f64_x(ptrue, values); + } + Vectorized angle() const { + const auto nan_vec = svdup_n_f64(NAN); + const auto nan_mask = svcmpuo_f64(ptrue, values, ZERO_F64); + const auto pi = svdup_n_f64(c10::pi); + + const auto neg_mask = svcmplt_f64(ptrue, values, ZERO_F64); + auto angle = svsel_f64(neg_mask, pi, ZERO_F64); + angle = svsel_f64(nan_mask, nan_vec, angle); + return angle; + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return Vectorized(0.0); + } + Vectorized conj() const { + return *this; + } + Vectorized acos() const { + return USE_SLEEF(Vectorized(Sleef_acosdx_u10sve(values)),map(std::acos)); + } + Vectorized acosh() const { + return USE_SLEEF( Vectorized(Sleef_acoshdx_u10sve(values)),map(std::acosh)); + } + Vectorized asin() const { + return USE_SLEEF(Vectorized(Sleef_asindx_u10sve(values)),map(std::asin)); + } + Vectorized asinh() const { + return USE_SLEEF(Vectorized(Sleef_asinhdx_u10sve(values)),map(std::asinh)); + } + Vectorized atan() const { + return USE_SLEEF(Vectorized(Sleef_atandx_u10sve(values)),map(std::atan)); + } + Vectorized atanh() const { + return USE_SLEEF(Vectorized(Sleef_atanhdx_u10sve(values)),map(std::atanh)); + } + Vectorized atan2(const Vectorized &b) const { + USE_SLEEF({return Vectorized(Sleef_atan2dx_u10sve(values, b));}, + { + __at_align__ double tmp[size()]; + __at_align__ double tmp_b[size()]; + store(tmp); + b.store(tmp_b); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = std::atan2(tmp[i], tmp_b[i]); + } + return loadu(tmp); + } + ) + } + Vectorized copysign(const Vectorized &sign) const { + USE_SLEEF( {return Vectorized(Sleef_copysigndx_sve(values, sign));}, + { + __at_align__ double tmp[size()]; + __at_align__ double tmp_sign[size()]; + store(tmp); + sign.store(tmp_sign); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = std::copysign(tmp[i], tmp_sign[i]); + } + return loadu(tmp); + } + ) + } + Vectorized erf() const { + return USE_SLEEF(Vectorized(Sleef_erfdx_u10sve(values)),map(std::erf)); + } + Vectorized erfc() const { + return USE_SLEEF(Vectorized(Sleef_erfcdx_u15sve(values)),map(std::erfc)); + } + Vectorized erfinv() const { + return map(calc_erfinv); + } + Vectorized exp() const { + return USE_SLEEF(Vectorized(Sleef_expdx_u10sve(values)),map(std::exp)); + } + Vectorized exp2() const { + return USE_SLEEF(Vectorized(Sleef_exp2dx_u10sve(values)),map(std::exp2)); + } + Vectorized expm1() const { + return USE_SLEEF(Vectorized(Sleef_expm1dx_u10sve(values)),map(std::expm1)); + } + Vectorized exp_u20() const { + return exp(); + } + Vectorized fmod(const Vectorized& q) const { + USE_SLEEF({return Vectorized(Sleef_fmoddx_sve(values, q));}, + { + __at_align__ double tmp[size()]; + __at_align__ double tmp_q[size()]; + store(tmp); + q.store(tmp_q); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = std::fmod(tmp[i], tmp_q[i]); + } + return loadu(tmp); + } + ) + } + Vectorized hypot(const Vectorized &b) const { + USE_SLEEF({return Vectorized(Sleef_hypotdx_u05sve(values, b));}, + { + __at_align__ double tmp[size()]; + __at_align__ double tmp_b[size()]; + store(tmp); + b.store(tmp_b); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = std::hypot(tmp[i], tmp_b[i]); + } + return loadu(tmp); + }) + } + Vectorized i0() const { + return map(calc_i0); + } + Vectorized i0e() const { + return map(calc_i0e); + } + Vectorized digamma() const { + return map(calc_digamma); + } + Vectorized igamma(const Vectorized &x) const { + __at_align__ double tmp[size()]; + __at_align__ double tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = calc_igamma(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized igammac(const Vectorized &x) const { + __at_align__ double tmp[size()]; + __at_align__ double tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = calc_igammac(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized nextafter(const Vectorized &b) const { + USE_SLEEF( + { + return Vectorized(Sleef_nextafterdx_sve(values, b)); + }, + { + __at_align__ double tmp[size()]; + __at_align__ double tmp_b[size()]; + store(tmp); + b.store(tmp_b); + for (int64_t i = 0; i < size(); ++i) { + tmp[i] = std::nextafter(tmp[i], tmp_b[i]); + } + return loadu(tmp); + } + ) + } + Vectorized log() const { + return USE_SLEEF(Vectorized(Sleef_logdx_u10sve(values)),map(std::log)); + } + Vectorized log2() const { + return USE_SLEEF(Vectorized(Sleef_log2dx_u10sve(values)),map(std::log2)); + } + Vectorized log10() const { + return USE_SLEEF(Vectorized(Sleef_log10dx_u10sve(values)),map(std::log10)); + } + Vectorized log1p() const { + return USE_SLEEF(Vectorized(Sleef_log1pdx_u10sve(values)),map(std::log1p)); + } + Vectorized frac() const; + Vectorized sin() const { + return USE_SLEEF( Vectorized(Sleef_sindx_u10sve(values)),map(std::sin)); + } + Vectorized sinh() const { + return USE_SLEEF(Vectorized(Sleef_sinhdx_u10sve(values)),map(std::sinh)); + } + Vectorized cos() const { + return USE_SLEEF(Vectorized(Sleef_cosdx_u10sve(values)),map(std::cos)); + } + Vectorized cosh() const { + return USE_SLEEF( Vectorized(Sleef_coshdx_u10sve(values)),map(std::cosh)); + } + Vectorized ceil() const { + return svrintp_f64_x(ptrue, values); + } + Vectorized floor() const { + return svrintm_f64_x(ptrue, values); + } + Vectorized neg() const { + return svneg_f64_x(ptrue, values); + } + Vectorized round() const { + return svrinti_f64_x(ptrue, values); + } + Vectorized tan() const { + return USE_SLEEF( Vectorized(Sleef_tandx_u10sve(values)),map(std::tan)); + } + Vectorized tanh() const { + return USE_SLEEF( Vectorized(Sleef_tanhdx_u10sve(values)),map(std::tanh)); + } + Vectorized trunc() const { + return svrintz_f64_x(ptrue, values); + } + Vectorized lgamma() const { + return USE_SLEEF( Vectorized(Sleef_lgammadx_u10sve(values)),map(std::lgamma)); + } + Vectorized sqrt() const { + return svsqrt_f64_x(ptrue, values); + } + Vectorized reciprocal() const { + return svdivr_f64_x(ptrue, values, ONE_F64); + } + Vectorized rsqrt() const { + return svdivr_f64_x(ptrue, svsqrt_f64_x(ptrue, values), ONE_F64); + } + Vectorized pow(const Vectorized &b) const { + USE_SLEEF( {return Vectorized(Sleef_powdx_u10sve(values, b));}, + { + __at_align__ double tmp[size()]; + __at_align__ double tmp_b[size()]; + store(tmp); + b.store(tmp_b); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = std::pow(tmp[i], tmp_b[i]); + } + return loadu(tmp); + } + ) + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized operator==(const Vectorized& other) const { + svbool_t mask = svcmpeq_f64(ptrue, values, other); + return svsel_f64(mask, ALL_F64_TRUE_MASK, ALL_F64_FALSE_MASK); + } + + Vectorized operator!=(const Vectorized& other) const { + svbool_t mask = svcmpne_f64(ptrue, values, other); + return svsel_f64(mask, ALL_F64_TRUE_MASK, ALL_F64_FALSE_MASK); + } + + Vectorized operator<(const Vectorized& other) const { + svbool_t mask = svcmplt_f64(ptrue, values, other); + return svsel_f64(mask, ALL_F64_TRUE_MASK, ALL_F64_FALSE_MASK); + } + + Vectorized operator<=(const Vectorized& other) const { + svbool_t mask = svcmple_f64(ptrue, values, other); + return svsel_f64(mask, ALL_F64_TRUE_MASK, ALL_F64_FALSE_MASK); + } + + Vectorized operator>(const Vectorized& other) const { + svbool_t mask = svcmpgt_f64(ptrue, values, other); + return svsel_f64(mask, ALL_F64_TRUE_MASK, ALL_F64_FALSE_MASK); + } + + Vectorized operator>=(const Vectorized& other) const { + svbool_t mask = svcmpge_f64(ptrue, values, other); + return svsel_f64(mask, ALL_F64_TRUE_MASK, ALL_F64_FALSE_MASK); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return svadd_f64_x(ptrue, a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return svsub_f64_x(ptrue, a, b); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return svmul_f64_x(ptrue, a, b); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return svdiv_f64_x(ptrue, a, b); +} + +// frac. Implement this here so we can use subtraction +Vectorized inline Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return svmax_f64_x(ptrue, a, b); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return svmin_f64_x(ptrue, a, b); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min, const Vectorized& max) { + return svmin_f64_x(ptrue, max, svmax_f64_x(ptrue, min, a)); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + return svmin_f64_x(ptrue, max, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + return svmax_f64_x(ptrue, min, a); +} + +template <> +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return svreinterpret_f64_s64(svand_s64_x(ptrue, svreinterpret_s64_f64(a), svreinterpret_s64_f64(b))); +} + +template <> +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return svreinterpret_f64_s64(svorr_s64_x(ptrue, svreinterpret_s64_f64(a), svreinterpret_s64_f64(b))); +} + +template <> +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return svreinterpret_f64_s64(sveor_s64_x(ptrue, svreinterpret_s64_f64(a), svreinterpret_s64_f64(b))); +} + +Vectorized inline Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0); +} + +Vectorized inline Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0); +} + +Vectorized inline Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0); +} + +Vectorized inline Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0); +} + +Vectorized inline Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0); +} + +Vectorized inline Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0); +} + +template <> +inline void convert(const double* src, double* dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svst1_f64(ptrue, dst + i, svldnt1_f64(ptrue, src + i)); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + svbool_t pg = svwhilelt_b64(i, n); + svst1_f64(pg, dst + i, svldnt1_f64(pg, src + i)); + } +} + +template <> +Vectorized inline fmadd(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return svmad_f64_x(ptrue, a, b, c); +} + +#endif // defined(CPU_CAPABILITY_SVE) + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_float.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_float.h new file mode 100644 index 0000000000000000000000000000000000000000..6a3dc2bc1c101eed1f907e9f41ec5d86c4aac0ea --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_float.h @@ -0,0 +1,588 @@ +#pragma once + +#include +#include +#include +#include +#if defined(__aarch64__) && defined(AT_BUILD_ARM_VEC256_WITH_SLEEF) +#include +#define USE_SLEEF(sleef_code, non_sleef_code) sleef_code +#else +#define USE_SLEEF(sleef_code, non_sleef_code) non_sleef_code +#endif + +namespace at::vec { +// Note [CPU_CAPABILITY namespace] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// This header, and all of its subheaders, will be compiled with +// different architecture flags for each supported set of vector +// intrinsics. So we need to make sure they aren't inadvertently +// linked together. We do this by declaring objects in an `inline +// namespace` which changes the name mangling, but can still be +// accessed as `at::vec`. +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_SVE) + +template <> class Vectorized { +private: + vls_float32_t values; +public: + using value_type = float; + using size_type = int; + static constexpr size_type size() { + return VECTOR_WIDTH / sizeof(float); + } + Vectorized() {} + Vectorized(svfloat32_t v) : values(v) {} + Vectorized(float val) { + values = svdup_n_f32(val); + } + template> + Vectorized(Args... vals) { + __at_align__ float buffer[size()] = { vals... }; + values = svld1_f32(ptrue, buffer); + } + operator svfloat32_t() const { + return values; + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + // Build an array of flags: each element is 1 if the corresponding bit in 'mask' is set, 0 otherwise. + __at_align__ int32_t flag_arr[size()]; + for (int i = 0; i < size(); i++) { + flag_arr[i] = (mask & (1ULL << i)) ? 1 : 0; + } + // Load the flag array into an SVE int32 vector. + svint32_t int_mask = svld1_s32(svptrue_b32(), flag_arr); + // Compare each lane of int_mask to 0; returns an svbool_t predicate where true indicates a nonzero flag. + svbool_t blend_mask = svcmpne_n_s32(svptrue_b32(), int_mask, 0); + // Use svsel to select elements from b where the predicate is true, else from a. + svfloat32_t result = svsel_f32(blend_mask, b.values, a.values); + return Vectorized(result); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask_) { + svbool_t mask = svcmpeq_s32(ptrue, svreinterpret_s32_f32(mask_), + ALL_S32_TRUE_MASK); + return svsel_f32(mask, b, a); + } + template + static Vectorized arange(float base = 0.f, step_t step = static_cast(1)) { + __at_align__ float buffer[size()]; + for (int64_t i = 0; i < size(); i++) { + buffer[i] = base + i * step; + } + return svld1_f32(ptrue, buffer); + } + static Vectorized set(const Vectorized& a, const Vectorized& b, + int64_t count = size()) { + if (count == 0) { + return a; + } else if (count < size()) { + return svsel_f32(svwhilelt_b32(0ull, count), b, a); + } + return b; + } + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return svld1_f32(ptrue, reinterpret_cast(ptr)); + svbool_t pg = svwhilelt_b32(0ull, count); + return svld1_f32(pg, reinterpret_cast(ptr)); + } + void store(void* ptr, int64_t count = size()) const { + if (count == size()) { + svst1_f32(ptrue, reinterpret_cast(ptr), values); + } else { + svbool_t pg = svwhilelt_b32(0ull, count); + svst1_f32(pg, reinterpret_cast(ptr), values); + } + } + const float& operator[](int idx) const = delete; + float& operator[](int idx) = delete; + int64_t zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit and others are translated to 0-bit + int64_t mask = 0; + __at_align__ int32_t mask_array[size()]; + + svbool_t svbool_mask = svcmpeq_f32(ptrue, values, ZERO_F32); + svst1_s32(ptrue, mask_array, svsel_s32(svbool_mask, + ALL_S32_TRUE_MASK, + ALL_S32_FALSE_MASK)); + for (int64_t i = 0; i < size(); ++i) { + if (mask_array[i]) mask |= (1ull << i); + } + return mask; + } + Vectorized isnan() const { + // NaN check + svbool_t mask = svcmpuo_f32(ptrue, values, ZERO_F32); + return svsel_f32(mask, ALL_F32_TRUE_MASK, ALL_F32_FALSE_MASK); + } + bool has_inf_nan() const { + return svptest_any(ptrue, svcmpuo_f32(ptrue, svsub_f32_x(ptrue, values, values), ZERO_F32)); + } + Vectorized map(float (*f)(float)) const { + __at_align__ float tmp[size()]; + store(tmp); + for (int64_t i = 0; i < size(); ++i) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + Vectorized abs() const { + return svabs_f32_x(ptrue, values); + } + Vectorized angle() const { + const auto nan_vec = svdup_n_f32(NAN); + const auto nan_mask = svcmpuo_f32(ptrue, values, ZERO_F32); + const auto pi = svdup_n_f32(c10::pi); + + const auto neg_mask = svcmplt_f32(ptrue, values, ZERO_F32); + auto angle = svsel_f32(neg_mask, pi, ZERO_F32); + angle = svsel_f32(nan_mask, nan_vec, angle); + return angle; + } + Vectorized real() const { + return values; + } + Vectorized imag() const { + return Vectorized(0.f); + } + Vectorized conj() const { + return values; + } + Vectorized acos() const { + return USE_SLEEF(Vectorized(Sleef_acosfx_u10sve(values)),map(std::acos)); + } + Vectorized acosh() const { + return USE_SLEEF(Vectorized(Sleef_acoshfx_u10sve(values)),map(std::acosh)); + } + Vectorized asin() const { + return USE_SLEEF(Vectorized(Sleef_asinfx_u10sve(values)),map(std::asin)); + } + Vectorized asinh() const { + return USE_SLEEF(Vectorized(Sleef_asinhfx_u10sve(values)),map(std::asinh)); + } + Vectorized atan() const { + return USE_SLEEF(Vectorized(Sleef_atanfx_u10sve(values)),map(std::atan)); + } + Vectorized atanh() const { + return USE_SLEEF(Vectorized(Sleef_atanhfx_u10sve(values)),map(std::atanh)); + } + Vectorized atan2(const Vectorized &b) const { + USE_SLEEF({return Vectorized(Sleef_atan2fx_u10sve(values, b));}, + { + __at_align__ float tmp[size()]; + __at_align__ float tmp_b[size()]; + store(tmp); + b.store(tmp_b); + for (int64_t i = 0; i < size(); i++){ + tmp[i] = std::atan2(tmp[i], tmp_b[i]); + } + return loadu(tmp); + } + ) + } + Vectorized copysign(const Vectorized &sign) const { + + USE_SLEEF({return Vectorized(Sleef_copysignfx_sve(values, sign));}, + { + __at_align__ float tmp[size()]; + __at_align__ float tmp_sign[size()]; + store(tmp); + sign.store(tmp_sign); + for (int64_t i = 0; i < size(); ++i) { + tmp[i] = std::copysign(tmp[i], tmp_sign[i]); + } + return loadu(tmp); + }) + } + Vectorized erf() const { + return USE_SLEEF(Vectorized(Sleef_erffx_u10sve(values)),map(std::erf)); + } + Vectorized erfc() const { + return USE_SLEEF(Vectorized(Sleef_erfcfx_u15sve(values)),map(std::erfc)); + } + Vectorized erfinv() const { + return map(calc_erfinv); + } + Vectorized exp() const { + return USE_SLEEF(Vectorized(Sleef_expfx_u10sve(values)),map(std::exp)); + } + Vectorized exp2() const { + return USE_SLEEF(Vectorized(Sleef_exp2fx_u10sve(values)),map(std::exp2)); + } + Vectorized expm1() const { + return USE_SLEEF(Vectorized(Sleef_expm1fx_u10sve(values)),map(std::expm1)); + } + Vectorized exp_u20() const { + return exp(); + } + Vectorized fmod(const Vectorized& q) const { + USE_SLEEF({return Vectorized(Sleef_fmodfx_sve(values, q));}, + { + __at_align__ float tmp[size()]; + __at_align__ float tmp_q[size()]; + store(tmp); + q.store(tmp_q); + for (int64_t i = 0; i < size(); ++i) { + tmp[i] = std::fmod(tmp[i], tmp_q[i]); + } + return loadu(tmp); + }) + } + Vectorized hypot(const Vectorized &b) const { + USE_SLEEF( {return Vectorized(Sleef_hypotfx_u05sve(values, b));}, + { + __at_align__ float tmp[size()]; + __at_align__ float tmp_b[size()]; + store(tmp); + b.store(tmp_b); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = std::hypot(tmp[i], tmp_b[i]); + } + return loadu(tmp); + } + ) + } + Vectorized i0() const { + return map(calc_i0); + } + Vectorized i0e() const { + return map(calc_i0e); + } + Vectorized digamma() const { + return map(calc_digamma); + } + Vectorized igamma(const Vectorized &x) const { + __at_align__ float tmp[size()]; + __at_align__ float tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = calc_igamma(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized igammac(const Vectorized &x) const { + __at_align__ float tmp[size()]; + __at_align__ float tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = calc_igammac(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized nextafter(const Vectorized &b) const { + USE_SLEEF( + { + return Vectorized(Sleef_nextafterfx_sve(values, b)); + }, + { + __at_align__ float tmp[size()]; + __at_align__ float tmp_b[size()]; + store(tmp); + b.store(tmp_b); + for (int64_t i = 0; i < size(); ++i) { + tmp[i] = std::nextafter(tmp[i], tmp_b[i]); + } + return loadu(tmp); + } + ) + } + Vectorized log() const { + return USE_SLEEF(Vectorized(Sleef_logfx_u10sve(values)),map(std::log)); + } + Vectorized log2() const { + return USE_SLEEF(Vectorized(Sleef_log2fx_u10sve(values)),map(std::log2)); + } + Vectorized log10() const { + return USE_SLEEF(Vectorized(Sleef_log10fx_u10sve(values)),map(std::log10)); + } + Vectorized log1p() const { + return USE_SLEEF(Vectorized(Sleef_log1pfx_u10sve(values)),map(std::log1p)); + } + Vectorized frac() const; + Vectorized sin() const { + return USE_SLEEF(Vectorized(Sleef_sinfx_u10sve(values)),map(std::sin)); + } + Vectorized sinh() const { + return USE_SLEEF(Vectorized(Sleef_sinhfx_u10sve(values)),map(std::sinh)); + } + Vectorized cos() const { + return USE_SLEEF(Vectorized(Sleef_cosfx_u10sve(values)),map(std::cos)); + } + Vectorized cosh() const { + return USE_SLEEF(Vectorized(Sleef_coshfx_u10sve(values)),map(std::cosh)); + } + Vectorized ceil() const { + return svrintp_f32_x(ptrue, values); + } + Vectorized floor() const { + return svrintm_f32_x(ptrue, values); + } + Vectorized neg() const { + return svneg_f32_x(ptrue, values); + } + Vectorized round() const { + return svrinti_f32_x(ptrue, values); + } + Vectorized tan() const { + return USE_SLEEF(Vectorized(Sleef_tanfx_u10sve(values)),map(std::tan)); + } + Vectorized tanh() const { + return USE_SLEEF(Vectorized(Sleef_tanhfx_u10sve(values)),map(std::tanh)); + } + Vectorized trunc() const { + return svrintz_f32_x(ptrue, values); + } + Vectorized lgamma() const { + return USE_SLEEF(Vectorized(Sleef_lgammafx_u10sve(values)),map(std::lgamma)); + } + Vectorized sqrt() const { + return svsqrt_f32_x(ptrue, values); + } + Vectorized reciprocal() const { + return svdivr_f32_x(ptrue, values, ONE_F32); + } + Vectorized rsqrt() const { + return svdivr_f32_x(ptrue, svsqrt_f32_x(ptrue, values), ONE_F32); + } + Vectorized pow(const Vectorized &b) const { + USE_SLEEF( {return Vectorized(Sleef_powfx_u10sve(values, b));}, + { + __at_align__ float tmp[size()]; + __at_align__ float tmp_b[size()]; + store(tmp); + b.store(tmp_b); + for (int64_t i = 0; i < size(); i++) { + tmp[i] = std::pow(tmp[i], tmp_b[i]); + } + return loadu(tmp); + } + ) + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized operator==(const Vectorized& other) const { + svbool_t mask = svcmpeq_f32(ptrue, values, other); + return svsel_f32(mask, ALL_F32_TRUE_MASK, ALL_F32_FALSE_MASK); + } + + Vectorized operator!=(const Vectorized& other) const { + svbool_t mask = svcmpne_f32(ptrue, values, other); + return svsel_f32(mask, ALL_F32_TRUE_MASK, ALL_F32_FALSE_MASK); + } + + Vectorized operator<(const Vectorized& other) const { + svbool_t mask = svcmplt_f32(ptrue, values, other); + return svsel_f32(mask, ALL_F32_TRUE_MASK, ALL_F32_FALSE_MASK); + } + + Vectorized operator<=(const Vectorized& other) const { + svbool_t mask = svcmple_f32(ptrue, values, other); + return svsel_f32(mask, ALL_F32_TRUE_MASK, ALL_F32_FALSE_MASK); + } + + Vectorized operator>(const Vectorized& other) const { + svbool_t mask = svcmpgt_f32(ptrue, values, other); + return svsel_f32(mask, ALL_F32_TRUE_MASK, ALL_F32_FALSE_MASK); + } + + Vectorized operator>=(const Vectorized& other) const { + svbool_t mask = svcmpge_f32(ptrue, values, other); + return svsel_f32(mask, ALL_F32_TRUE_MASK, ALL_F32_FALSE_MASK); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return svadd_f32_x(ptrue, a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return svsub_f32_x(ptrue, a, b); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return svmul_f32_x(ptrue, a, b); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return svdiv_f32_x(ptrue, a, b); +} + +// frac. Implement this here so we can use subtraction +Vectorized inline Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return svmax_f32_x(ptrue, a, b); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return svmin_f32_x(ptrue, a, b); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min, const Vectorized& max) { + return svmin_f32_x(ptrue, max, svmax_f32_x(ptrue, min, a)); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + return svmin_f32_x(ptrue, max, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + return svmax_f32_x(ptrue, min, a); +} + +template <> +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return svreinterpret_f32_s32(svand_s32_x(ptrue, svreinterpret_s32_f32(a), svreinterpret_s32_f32(b))); +} + +template <> +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return svreinterpret_f32_s32(svorr_s32_x(ptrue, svreinterpret_s32_f32(a), svreinterpret_s32_f32(b))); +} + +template <> +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return svreinterpret_f32_s32(sveor_s32_x(ptrue, svreinterpret_s32_f32(a), svreinterpret_s32_f32(b))); +} + +Vectorized inline Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0f); +} + +Vectorized inline Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0f); +} + +Vectorized inline Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0f); +} + +Vectorized inline Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0f); +} + +Vectorized inline Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0f); +} + +Vectorized inline Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0f); +} + +template <> +inline void convert(const float* src, float* dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svst1_f32(ptrue, dst + i, svldnt1_f32(ptrue, src + i)); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + svbool_t pg = svwhilelt_b32(i, n); + svst1_f32(pg, dst + i, svldnt1_f32(pg, src + i)); + } +} + +template <> +inline void convert(const float *src, at::Half *dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); + svbool_t pg_16 = svwhilelt_b16(0ull, Vectorized::size()); + svbool_t pg_32 = svwhilelt_b32(0ull, Vectorized::size()); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svfloat16_t src_vec = svuzp1_f16(svcvt_f16_f32_x(ptrue, svldnt1_f32(pg_32, src + i)), + ZERO_F16); + svst1_f16(pg_16, reinterpret_cast(dst) + i, src_vec); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + pg_16 = svwhilelt_b16(i, n); + pg_32 = svwhilelt_b32(i, n); + svfloat16_t src_vec = svuzp1_f16(svcvt_f16_f32_x(ptrue, svldnt1_f32(pg_32, src + i)), + ZERO_F16); + svst1_f16(pg_16, reinterpret_cast(dst) + i, src_vec); + } +} + +template <> +inline void convert(const at::Half *src, float *dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); + svbool_t pg_16 = svwhilelt_b16(0ull, Vectorized::size()); + svbool_t pg_32 = svwhilelt_b32(0ull, Vectorized::size()); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svfloat16_t src_vec = svzip1_f16(svldnt1_f16(pg_16, reinterpret_cast(src) + i), + ZERO_F16); + svst1_f32(pg_32, dst + i, svcvt_f32_f16_x(ptrue, src_vec)); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + pg_16 = svwhilelt_b16(i, n); + pg_32 = svwhilelt_b32(i, n); + svfloat16_t src_vec = svzip1_f16(svldnt1_f16(pg_16, reinterpret_cast(src) + i), + ZERO_F16); + svst1_f32(pg_32, dst + i, svcvt_f32_f16_x(ptrue, src_vec)); + } +} + +template <> +inline void convert(const bool *src, float *dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); + svbool_t pg_8 = svwhilelt_b8(0ull, Vectorized::size()); + svbool_t pg_32 = svwhilelt_b32(0ull, Vectorized::size()); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svuint8_t src_vec_u8 = svldnt1_u8(pg_8, reinterpret_cast(src) + i); + svuint32_t src_vec_u32 = svunpklo_u32(svunpklo_u16(src_vec_u8)); + svbool_t mask = svcmpne_u32(pg_32, src_vec_u32, ZERO_U32); + svst1_f32(pg_32, dst + i, svsel_f32(mask, ONE_F32, ZERO_F32)); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + pg_8 = svwhilelt_b8(i, n); + pg_32 = svwhilelt_b32(i, n); + svuint8_t src_vec_u8 = svldnt1_u8(pg_8, reinterpret_cast(src) + i); + svuint32_t src_vec_u32 = svunpklo_u32(svunpklo_u16(src_vec_u8)); + svbool_t mask = svcmpne_u32(pg_32, src_vec_u32, ZERO_U32); + svst1_f32(pg_32, dst + i, svsel_f32(mask, ONE_F32, ZERO_F32)); + } +} + +template <> +Vectorized inline fmadd(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return svmad_f32_x(ptrue, a, b, c); +} + +#endif // defined(CPU_CAPABILITY_SVE) + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_int.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_int.h new file mode 100644 index 0000000000000000000000000000000000000000..1e8c76ab0572ac37510cb183a00310b4049bf6d0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_int.h @@ -0,0 +1,419 @@ +#pragma once + +#include +#include +#include + + +namespace at::vec { +// Note [CPU_CAPABILITY namespace] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// This header, and all of its subheaders, will be compiled with +// different architecture flags for each supported set of vector +// intrinsics. So we need to make sure they aren't inadvertently +// linked together. We do this by declaring objects in an `inline +// namespace` which changes the name mangling, but can still be +// accessed as `at::vec`. +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_SVE) + +#define VEC_INT_SVE_TEMPLATE(vl, bit) \ +template <> class Vectorized { \ +private: \ + vls_int##bit##_t values; \ +public: \ + using value_type = int##bit##_t; \ + using size_type = int; \ + static constexpr size_type size() { \ + return vl; \ + } \ + Vectorized() {} \ + Vectorized(svint##bit##_t v) : values(v) {} \ + Vectorized(int##bit##_t val) { \ + values = svdup_n_s##bit(val); \ + } \ + template> \ + Vectorized(Args... vals) { \ + __at_align__ int##bit##_t buffer[size()] = { vals... }; \ + values = svld1_s##bit(ptrue, buffer); \ + } \ + operator svint##bit##_t() const { \ + return values; \ + } \ + template \ + static Vectorized blend(const Vectorized& a, const Vectorized& b) { \ + __at_align__ int##bit##_t flag_arr[size()]; \ + for (int i = 0; i < size(); ++i) { \ + flag_arr[i] = (i < 64 && (mask & (1ULL << i))) ? 1 : 0; \ + } \ + svbool_t blend_mask = svcmpne_n_s##bit(svptrue_b##bit(), svld1_s##bit(svptrue_b##bit(), flag_arr), 0); \ + return Vectorized(svsel_s##bit(blend_mask, b.values, a.values)); \ + } \ + static Vectorized blendv(const Vectorized& a, \ + const Vectorized& b, \ + const Vectorized& mask_) { \ + svbool_t mask = svcmpeq_s##bit(ptrue, mask_, ALL_S##bit##_TRUE_MASK); \ + return svsel_s##bit(mask, b, a); \ + } \ + /* step sometimes requires a higher precision type (e.g., T=int, step_t=double) */ \ + template \ + static Vectorized arange(int##bit##_t base = 0, step_t step = static_cast(1)) { \ + __at_align__ int##bit##_t buffer[size()]; \ + for (int64_t i = 0; i < size(); i++) { \ + buffer[i] = base + i * step; \ + } \ + return svld1_s##bit(ptrue, buffer); \ + } \ + static Vectorized set(const Vectorized& a, \ + const Vectorized& b, \ + int##bit##_t count = size()) { \ + if (count == 0) { \ + return a; \ + } else if (count < size()) { \ + return svsel_s##bit(svwhilelt_b##bit(0ull, count), b, a); \ + } \ + return b; \ + } \ + static Vectorized loadu(const void* ptr, int64_t count = size()) { \ + if (count == size()) \ + return svld1_s##bit(ptrue, reinterpret_cast(ptr)); \ + svbool_t pg = svwhilelt_b##bit(0ull, count); \ + return svld1_s##bit(pg, reinterpret_cast(ptr)); \ + } \ + void store(void* ptr, int64_t count = size()) const { \ + if (count == size()) { \ + svst1_s##bit(ptrue, reinterpret_cast(ptr), values); \ + } else { \ + svbool_t pg = svwhilelt_b##bit(0ull, count); \ + svst1_s##bit(pg, reinterpret_cast(ptr), values); \ + } \ + } \ + const int##bit##_t& operator[](int idx) const = delete; \ + int##bit##_t& operator[](int idx) = delete; \ + Vectorized abs() const { \ + return svabs_s##bit##_x(ptrue, values); \ + } \ + Vectorized real() const { \ + return values; \ + } \ + Vectorized imag() const { \ + return svdup_n_s##bit(0); \ + } \ + Vectorized conj() const { \ + return values; \ + } \ + Vectorized frac() const; \ + Vectorized neg() const { \ + return svneg_s##bit##_x(ptrue, values); \ + } \ + Vectorized operator==(const Vectorized& other) const { \ + svbool_t mask = svcmpeq_s##bit(ptrue, values, other); \ + return svsel_s##bit(mask, ALL_S##bit##_TRUE_MASK, ALL_S##bit##_FALSE_MASK); \ + } \ + Vectorized operator!=(const Vectorized& other) const { \ + svbool_t mask = svcmpne_s##bit(ptrue, values, other); \ + return svsel_s##bit(mask, ALL_S##bit##_TRUE_MASK, ALL_S##bit##_FALSE_MASK); \ + } \ + Vectorized operator<(const Vectorized& other) const { \ + svbool_t mask = svcmplt_s##bit(ptrue, values, other); \ + return svsel_s##bit(mask, ALL_S##bit##_TRUE_MASK, ALL_S##bit##_FALSE_MASK); \ + } \ + Vectorized operator<=(const Vectorized& other) const { \ + svbool_t mask = svcmple_s##bit(ptrue, values, other); \ + return svsel_s##bit(mask, ALL_S##bit##_TRUE_MASK, ALL_S##bit##_FALSE_MASK); \ + } \ + Vectorized operator>(const Vectorized& other) const { \ + svbool_t mask = svcmpgt_s##bit(ptrue, values, other); \ + return svsel_s##bit(mask, ALL_S##bit##_TRUE_MASK, ALL_S##bit##_FALSE_MASK); \ + } \ + Vectorized operator>=(const Vectorized& other) const { \ + svbool_t mask = svcmpge_s##bit(ptrue, values, other); \ + return svsel_s##bit(mask, ALL_S##bit##_TRUE_MASK, ALL_S##bit##_FALSE_MASK); \ + } \ + Vectorized eq(const Vectorized& other) const; \ + Vectorized ne(const Vectorized& other) const; \ + Vectorized gt(const Vectorized& other) const; \ + Vectorized ge(const Vectorized& other) const; \ + Vectorized lt(const Vectorized& other) const; \ + Vectorized le(const Vectorized& other) const; \ +}; \ +template <> \ +Vectorized inline operator+(const Vectorized& a, \ + const Vectorized& b) { \ + return svadd_s##bit##_x(ptrue, a, b); \ +} \ +template <> \ +Vectorized inline operator-(const Vectorized& a, \ + const Vectorized& b) { \ + return svsub_s##bit##_x(ptrue, a, b); \ +} \ +template <> \ +Vectorized inline operator*(const Vectorized& a, \ + const Vectorized& b) { \ + return svmul_s##bit##_x(ptrue, a, b); \ +} \ +template <> \ +Vectorized inline maximum(const Vectorized& a, \ + const Vectorized& b) { \ + return svmax_s##bit##_x(ptrue, a, b); \ +} \ +template <> \ +Vectorized inline minimum(const Vectorized& a, \ + const Vectorized& b) { \ + return svmin_s##bit##_x(ptrue, a, b); \ +} \ +template <> \ +Vectorized inline clamp(const Vectorized& a, \ + const Vectorized& min, \ + const Vectorized& max) { \ + return svmin_s##bit##_x(ptrue, max, svmax_s##bit##_x(ptrue, min, a)); \ +} \ +template <> \ +Vectorized inline clamp_max(const Vectorized& a, \ + const Vectorized& max) { \ + return svmin_s##bit##_x(ptrue, max, a); \ +} \ +template <> \ +Vectorized inline clamp_min(const Vectorized& a, \ + const Vectorized& min) { \ + return svmax_s##bit##_x(ptrue, min, a); \ +} \ +template <> \ +Vectorized inline operator&(const Vectorized& a, \ + const Vectorized& b) { \ + return svand_s##bit##_x(ptrue, a, b); \ +} \ +template <> \ +Vectorized inline operator|(const Vectorized& a, \ + const Vectorized& b) { \ + return svorr_s##bit##_x(ptrue, a, b); \ +} \ +template <> \ +Vectorized inline operator^(const Vectorized& a, \ + const Vectorized& b) { \ + return sveor_s##bit##_x(ptrue, a, b); \ +} \ +template <> \ +inline Vectorized operator~(const Vectorized& a) { \ + return sveor_s##bit##_x(ptrue, a, svdup_n_s##bit(-1)); \ +} \ +Vectorized inline Vectorized::eq(const Vectorized& other) const { \ + return (*this == other) & Vectorized(1); \ +} \ +Vectorized inline Vectorized::ne(const Vectorized& other) const { \ + return (*this != other) & Vectorized(1); \ +} \ +Vectorized inline Vectorized::gt(const Vectorized& other) const { \ + return (*this > other) & Vectorized(1); \ +} \ +Vectorized inline Vectorized::ge(const Vectorized& other) const { \ + return (*this >= other) & Vectorized(1); \ +} \ +Vectorized inline Vectorized::lt(const Vectorized& other) const { \ + return (*this < other) & Vectorized(1); \ +} \ +Vectorized inline Vectorized::le(const Vectorized& other) const { \ + return (*this <= other) & Vectorized(1); \ +} + +VEC_INT_SVE_TEMPLATE(VECTOR_WIDTH / sizeof(int64_t), 64) +VEC_INT_SVE_TEMPLATE(VECTOR_WIDTH / sizeof(int32_t), 32) +VEC_INT_SVE_TEMPLATE(VECTOR_WIDTH / sizeof(int16_t), 16) +VEC_INT_SVE_TEMPLATE(VECTOR_WIDTH / sizeof(int8_t), 8) + +template +Vectorized inline intdiv_nosve(const Vectorized& a, const Vectorized& b) { + T values_a[Vectorized::size()]; + T values_b[Vectorized::size()]; + a.store(values_a); + b.store(values_b); + for (int i = 0; i != Vectorized::size(); i++) { + values_a[i] /= values_b[i]; + } + return Vectorized::loadu(values_a); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return svdiv_s64_x(ptrue, a, b); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return svdiv_s32_x(ptrue, a, b); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return intdiv_nosve(a, b); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return intdiv_nosve(a, b); +} + +template <> +inline void convert(const int32_t *src, int64_t *dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); + svbool_t pg_32 = svwhilelt_b32(0ull, Vectorized::size()); + svbool_t pg_64 = svwhilelt_b64(0ull, Vectorized::size()); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) + svst1_s64(pg_64, dst + i, svunpklo_s64(svldnt1_s32(pg_32, src + i))); +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + pg_32 = svwhilelt_b32(i, n); + pg_64 = svwhilelt_b64(i, n); + svst1_s64(pg_64, dst + i, svunpklo_s64(svldnt1_s32(pg_32, src + i))); + } +} + +template <> +inline void convert(const int64_t *src, float *dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); + svbool_t pg_32 = svwhilelt_b32(0ull, Vectorized::size()); + svbool_t pg_64 = svwhilelt_b64(0ull, Vectorized::size()); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svint64_t src_vec_s64 = svldnt1_s64(pg_64, src + i); + svfloat32_t src_vec_f32 = svuzp1_f32(svcvt_f32_s64_x(pg_64, src_vec_s64), ZERO_F32); + svst1_f32(pg_32, dst + i, src_vec_f32); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + pg_32 = svwhilelt_b32(i, n); + pg_64 = svwhilelt_b64(i, n); + svint64_t src_vec_s64 = svldnt1_s64(pg_64, src + i); + svfloat32_t src_vec_f32 = svuzp1_f32(svcvt_f32_s64_x(pg_64, src_vec_s64), ZERO_F32); + svst1_f32(pg_32, dst + i, src_vec_f32); + } +} + +template <> +inline void convert(const int32_t *src, float *dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); + svbool_t pg = svwhilelt_b32(0ull, Vectorized::size()); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svint32_t src_vec = svldnt1_s32(pg, src + i); + svst1_f32(pg, dst + i, svcvt_f32_s32_x(pg, src_vec)); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + pg = svwhilelt_b32(i, n); + svint32_t src_vec = svldnt1_s32(pg, src + i); + svst1_f32(pg, dst + i, svcvt_f32_s32_x(pg, src_vec)); + } +} + +template <> +inline void convert(const bool *src, int64_t *dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); + svbool_t pg_8 = svwhilelt_b8(0ull, Vectorized::size()); + svbool_t pg_64 = svwhilelt_b64(0ull, Vectorized::size()); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svuint8_t src_vec_u8 = svldnt1_u8(pg_8, reinterpret_cast(src) + i); + svuint64_t src_vec_u64 = svunpklo_u64(svunpklo_u32(svunpklo_u16(src_vec_u8))); + svbool_t mask = svcmpne_u64(pg_64, src_vec_u64, ZERO_U64); + svst1_s64(pg_64, dst + i, svsel_s64(mask, ONE_S64, ZERO_S64)); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + pg_8 = svwhilelt_b8(i, n); + pg_64 = svwhilelt_b64(i, n); + svuint8_t src_vec_u8 = svldnt1_u8(pg_8, reinterpret_cast(src) + i); + svuint64_t src_vec_u64 = svunpklo_u64(svunpklo_u32(svunpklo_u16(src_vec_u8))); + svbool_t mask = svcmpne_u64(pg_64, src_vec_u64, ZERO_U64); + svst1_s64(pg_64, dst + i, svsel_s64(mask, ONE_S64, ZERO_S64)); + } +} + +template <> +inline void convert(const bool *src, int32_t *dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); + svbool_t pg_8 = svwhilelt_b8(0ull, Vectorized::size()); + svbool_t pg_32 = svwhilelt_b32(0ull, Vectorized::size()); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svuint8_t src_vec_u8 = svldnt1_u8(pg_8, reinterpret_cast(src) + i); + svuint32_t src_vec_u32 = svunpklo_u32(svunpklo_u16(src_vec_u8)); + svbool_t mask = svcmpne_u32(pg_32, src_vec_u32, ZERO_U32); + svst1_s32(pg_32, dst + i, svsel_s32(mask, ONE_S32, ZERO_S32)); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + pg_8 = svwhilelt_b8(i, n); + pg_32 = svwhilelt_b32(i, n); + svuint8_t src_vec_u8 = svldnt1_u8(pg_8, reinterpret_cast(src) + i); + svuint32_t src_vec_u32 = svunpklo_u32(svunpklo_u16(src_vec_u8)); + svbool_t mask = svcmpne_u32(pg_32, src_vec_u32, ZERO_U32); + svst1_s32(pg_32, dst + i, svsel_s32(mask, ONE_S32, ZERO_S32)); + } +} + +template <> +inline void convert(const uint8_t *src, bool *dst, int64_t n) { + const int64_t fraction = n % Vectorized::size(); + svbool_t pg = svwhilelt_b8(0ull, Vectorized::size()); +#pragma unroll + for (int64_t i = 0; i < n - fraction; i += Vectorized::size()) { + svbool_t mask = svcmpne_u8(pg, svldnt1_u8(pg, src + i), ZERO_U8); + svst1_u8(pg, reinterpret_cast(dst) + i, + svsel_u8(mask, ALL_U8_TRUE_MASK, ALL_U8_FALSE_MASK)); + } +#pragma unroll + for (int64_t i = n - fraction; i < n; i += Vectorized::size()) { + pg = svwhilelt_b8(i, n); + svbool_t mask = svcmpne_u8(pg, svldnt1_u8(pg, src + i), ZERO_U8); + svst1_u8(pg, reinterpret_cast(dst) + i, + svsel_u8(mask, ALL_U8_TRUE_MASK, ALL_U8_FALSE_MASK)); + } +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return svlsl_s64_x(ptrue, a, svreinterpret_u64_s64(b)); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return svlsl_s32_x(ptrue, a, svreinterpret_u32_s32(b)); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return svlsl_s16_x(ptrue, a, svreinterpret_u16_s16(b)); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return svlsl_s8_x(ptrue, a, svreinterpret_u8_s8(b)); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return svasr_s64_x(ptrue, a, svreinterpret_u64_s64(b)); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return svasr_s32_x(ptrue, a, svreinterpret_u32_s32(b)); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return svasr_s16_x(ptrue, a, svreinterpret_u16_s16(b)); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return svasr_s8_x(ptrue, a, svreinterpret_u8_s8(b)); +} + +#endif // defined(CPU_CAPABILITY_SVE) + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_qint.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_qint.h new file mode 100644 index 0000000000000000000000000000000000000000..96e201ef36a2196fb3b09cd221766013e3223c64 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/sve/vec_qint.h @@ -0,0 +1,567 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with SVE] + +#include +#include +#include +#include +#include +#include + +#include + +// This file defines Vectorized<> for the quantized types. +// +// +// Currently, we simply use these classes as efficient converters between +// the quantized types and Vectorized, usually in bandwidth-bound cases +// where doing the arithmetic in full-precision is acceptable (e.g. +// elementwise operators). +// +// +// Conversions are as follows: +// Vectorized -> 4x Vectorized +// Vectorized -> 4x Vectorized +// Vectorized -> 1x Vectorized +// +// The size of the returned float vector is specified by the special +// constexpr function float_num_vecs. The type of the value returned +// from dequantize (and expected as an argument to quantize) is +// specified by float_vec_return_type. +// +// When writing kernels with these vectors, it is expected that floating- +// point operations will be carried out in a loop over Vectorized::float_num_vecs +// iterations. + + +namespace at::vec { +// Note [CPU_CAPABILITY namespace] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// This header, and all of its subheaders, will be compiled with +// different architecture flags for each supported set of vector +// intrinsics. So we need to make sure they aren't inadvertently +// linked together. We do this by declaring objects in an `inline +// namespace` which changes the name mangling, but can still be +// accessed as `at::vec`. +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_SVE) + +// NOTE: These are low-performance implementations that we fall back on +// if we are not building with SVE. This may not be an issue, because +// currently for quantization we assume the user has at least SVE +// installed, so these can simply act as a reference implementation. +// +// If in the future we relax this requirement (SVE+), we should probably +// revisit these implementations + +template < + typename T, + typename float_vec_return_type_, + typename int_vec_return_type_, + int size_> +struct VectorizedQuantizedConverter { + using size_type = int; + static constexpr size_type size() { + return size_; + } + + static constexpr int float_num_vecs() { + return size() / Vectorized::size(); + } + + static constexpr int int_num_vecs() { + return size() / Vectorized::size(); + } + + using float_vec_return_type = float_vec_return_type_; + using int_vec_return_type = int_vec_return_type_; + + using value_type = typename T::underlying; + std::array vals; + + VectorizedQuantizedConverter(T val) { + for (size_t i = 0; i < size(); ++i) { + vals[i] = val.val_; + } + } + + VectorizedQuantizedConverter(const void* ptr) { + memcpy(vals.data(), ptr, sizeof(value_type) * size()); + } + + void store(void* ptr, int count = size()) const { + memcpy(ptr, vals.data(), count * sizeof(value_type)); + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_zp_premul) const { + float_vec_return_type rv; + float tmp_scale[Vectorized::size()]; + float tmp_zero_point[Vectorized::size()]; + scale.store(tmp_scale); + zero_point.store(tmp_zero_point); + for (int i = 0; i < float_num_vecs(); ++i) { + float tmp_vals[Vectorized::size()]; + for (int j = 0; j < Vectorized::size(); ++j) { + tmp_vals[j] = + at::native::dequantize_val(tmp_scale[j], tmp_zero_point[j], T(vals[Vectorized::size() * i + j])); + } + rv[i] = Vectorized::loadu(tmp_vals); + } + return rv; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + float_vec_return_type rv; + float tmp_scale[Vectorized::size()]; + float tmp_zero_point[Vectorized::size()]; + scale.store(tmp_scale); + zero_point.store(tmp_zero_point); + for (int i = 0; i < float_num_vecs(); ++i) { + float tmp_vals[Vectorized::size()]; + for (int j = 0; j < Vectorized::size(); ++j) { + tmp_vals[j] = + at::native::dequantize_val(tmp_scale[j], tmp_zero_point[j], T(vals[Vectorized::size() * i + j])); + } + rv[i] = Vectorized::loadu(tmp_vals); + } + return rv; + } + + protected: + VectorizedQuantizedConverter() {} +}; + +template <> +struct Vectorized : public VectorizedQuantizedConverter< + c10::qint32, + std::array, 1>, + std::array, 1>, + VECTOR_WIDTH / 4> { + Vectorized() + : VectorizedQuantizedConverter< + c10::qint32, + std::array, 1>, + std::array, 1>, + VECTOR_WIDTH / 4>() {} + Vectorized(c10::qint32 val) + : VectorizedQuantizedConverter< + c10::qint32, + std::array, 1>, + std::array, 1>, + VECTOR_WIDTH / 4>(val) {} + Vectorized(const void* ptr) + : VectorizedQuantizedConverter< + c10::qint32, + std::array, 1>, + std::array, 1>, + VECTOR_WIDTH / 4>(ptr) {} +#if 1 + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return loadu(tmp_values); + } +#else + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return svld1_s32(ptrue, reinterpret_cast(ptr)); + svbool_t pg = svwhilelt_b32(0ull, count); + return svld1_s32(pg, reinterpret_cast(ptr)); + } +#endif + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + std::array qvals; + std::array::size()> float_vals; + + for (int i = 0; i < float_num_vecs(); ++i) { + rhs[i].store(&float_vals[i * Vectorized::size()], Vectorized::size()); + } + + at::native::quantize_vec( + scale, + zero_point, + float_vals.data(), + (c10::qint32*)qvals.data(), + Vectorized::size() * float_num_vecs()); + + return Vectorized::loadu(qvals.data()); + } + + Vectorized maximum(Vectorized b) const { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = std::max(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized minimum(Vectorized b) const { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = std::min(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = std::min( + std::max(vals[i], zero_point.vals[i]), q_six.vals[i]); + } + return retval; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + int_vec_return_type retval; + for (size_t i = 0; i < size(); ++i) { + retval[0].vals[i] = vals[i] - b.vals[i]; + } + return retval; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = + nearbyint(static_cast(inp[0].vals[i]) * multiplier) + + zero_point; + } + return retval; + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline operator*( + const Vectorized& a, + const Vectorized& b) { + Vectorized retval; + for (size_t i = 0; i < std::decay_t::size(); ++i) { + retval.vals[i] = a.vals[i] * b.vals[i]; + } + return retval; +} + +template <> +Vectorized inline operator+( + const Vectorized& a, + const Vectorized& b) { + Vectorized retval; + for (size_t i = 0; i < std::decay_t::size(); ++i) { + retval.vals[i] = a.vals[i] + b.vals[i]; + } + return retval; +} + +template <> +struct Vectorized : public VectorizedQuantizedConverter< + c10::qint8, + std::array, 4>, + std::array, 4>, + VECTOR_WIDTH> { + Vectorized() + : VectorizedQuantizedConverter< + c10::qint8, + std::array, 4>, + std::array, 4>, + VECTOR_WIDTH>() {} + Vectorized(c10::qint8 val) + : VectorizedQuantizedConverter< + c10::qint8, + std::array, 4>, + std::array, 4>, + VECTOR_WIDTH>(val) {} + Vectorized(const void* ptr) + : VectorizedQuantizedConverter< + c10::qint8, + std::array, 4>, + std::array, 4>, + VECTOR_WIDTH>(ptr) {} + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return loadu(tmp_values); + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + std::array qvals; + std::array::size()> float_vals; + + for (int i = 0; i < float_num_vecs(); ++i) { + rhs[i].store(&float_vals[i * Vectorized::size()], Vectorized::size()); + } + + at::native::quantize_vec( + scale, + zero_point, + float_vals.data(), + (c10::qint8*)qvals.data(), + Vectorized::size() * float_num_vecs()); + + return Vectorized::loadu(qvals.data()); + } + + Vectorized maximum(Vectorized b) const { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = std::max(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized minimum(Vectorized b) const { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = std::min(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = std::min( + std::max(vals[i], zero_point.vals[i]), q_six.vals[i]); + } + return retval; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + int_vec_return_type retval; + constexpr int elem_per_int_vec = size() / int_num_vecs(); + for (size_t i = 0; i < int_num_vecs(); ++i) { + for (size_t j = 0; j < elem_per_int_vec; ++j) { + retval[i].vals[j] = + static_cast(vals[i * elem_per_int_vec + j]) - + static_cast(b.vals[i * elem_per_int_vec + j]); + } + } + return retval; + } + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + constexpr int elem_per_int_vec = size() / int_num_vecs(); + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + Vectorized retval; + for (size_t i = 0; i < int_num_vecs(); ++i) { + for (size_t j = 0; j < elem_per_int_vec; ++j) { + int32_t rounded = + nearbyint(static_cast(inp[i].vals[j]) * multiplier) + + zero_point; + retval.vals[i * elem_per_int_vec + j] = + std::min(std::max(rounded, min_val), max_val); + } + } + return retval; + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template <> +struct Vectorized : public VectorizedQuantizedConverter< + c10::quint8, + std::array, 4>, + std::array, 4>, + VECTOR_WIDTH> { + Vectorized() + : VectorizedQuantizedConverter< + c10::quint8, + std::array, 4>, + std::array, 4>, + VECTOR_WIDTH>() {} + Vectorized(c10::quint8 val) + : VectorizedQuantizedConverter< + c10::quint8, + std::array, 4>, + std::array, 4>, + VECTOR_WIDTH>(val) {} + Vectorized(const void* ptr) + : VectorizedQuantizedConverter< + c10::quint8, + std::array, 4>, + std::array, 4>, + VECTOR_WIDTH>(ptr) {} +#if 1 + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return loadu(tmp_values); + } +#else + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return svld1_u8(ptrue, reinterpret_cast(ptr)); + svbool_t pg = svwhilelt_b8(0ull, count); + return svld1_u8(pg, reinterpret_cast(ptr)); + } +#endif + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + std::array qvals; + std::array::size()> float_vals; + + for (int i = 0; i < float_num_vecs(); ++i) { + rhs[i].store(&float_vals[i * Vectorized::size()], Vectorized::size()); + } + + at::native::quantize_vec( + scale, + zero_point, + float_vals.data(), + (c10::quint8*)qvals.data(), + Vectorized::size() * float_num_vecs()); + + return Vectorized::loadu(qvals.data()); + } + + Vectorized maximum(Vectorized b) const { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = std::max(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized minimum(Vectorized b) const { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = std::min(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + Vectorized retval; + for (size_t i = 0; i < size(); ++i) { + retval.vals[i] = std::min( + std::max(vals[i], zero_point.vals[i]), q_six.vals[i]); + } + return retval; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + int_vec_return_type retval; + constexpr int elem_per_int_vec = size() / int_num_vecs(); + for (size_t i = 0; i < int_num_vecs(); ++i) { + for (size_t j = 0; j < elem_per_int_vec; ++j) { + retval[i].vals[j] = + static_cast(vals[i * elem_per_int_vec + j]) - + static_cast(b.vals[i * elem_per_int_vec + j]); + } + } + return retval; + } + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + constexpr int elem_per_int_vec = size() / int_num_vecs(); + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + Vectorized retval; + for (size_t i = 0; i < int_num_vecs(); ++i) { + for (size_t j = 0; j < elem_per_int_vec; ++j) { + int32_t rounded = + nearbyint(static_cast(inp[i].vals[j]) * multiplier) + + zero_point; + retval.vals[i * elem_per_int_vec + j] = + std::min(std::max(rounded, min_val), max_val); + } + } + return retval; + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +#endif // defined(CPU_CAPABILITY_SVE) + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec.h new file mode 100644 index 0000000000000000000000000000000000000000..e4b0c4b95d845742d3038dfcb857be9eef0e8685 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec.h @@ -0,0 +1,48 @@ +#pragma once + +#if defined(CPU_CAPABILITY_AVX512) +#include +#else +#include +#include +#endif + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +inline Vectorized convert_to_bool(Vectorized x) { + __at_align__ bool buffer[x.size()]; + x.ne(Vectorized(0)).store(buffer); + + Vectorized ret; + static_assert(x.size() == ret.size()); + std::memcpy(ret, buffer, ret.size() * sizeof(bool)); + return ret; +} + +template <> +inline Vectorized Vectorized::loadu(const void* ptr) { + // See NOTE [Loading boolean values] + return convert_to_bool(Vectorized::loadu(ptr)); +} + +template <> +inline Vectorized Vectorized::loadu(const void* ptr, int64_t count) { + // See NOTE [Loading boolean values] + return convert_to_bool(Vectorized::loadu(ptr, count)); +} + +template +struct VecHoldType { using hold_type = typename VT::value_type; }; + +template <> +struct VecHoldType> { using hold_type = BFloat16; }; + +template <> +struct VecHoldType> {using hold_type = Half; }; + +template +using vechold_type = typename VecHoldType::hold_type; + +}} // namespace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128.h new file mode 100644 index 0000000000000000000000000000000000000000..c49580410aaf421642265e4e62a489ffe92720e2 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128.h @@ -0,0 +1,14 @@ +#pragma once +// ARM NEON uses 128-bit vector registers. + +#include + +#ifdef __aarch64__ +#if !defined(CPU_CAPABILITY_SVE) +#include +#include +#include +#endif + +#include +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_bfloat16_neon.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_bfloat16_neon.h new file mode 100644 index 0000000000000000000000000000000000000000..7d594c696f7a6edb9934418a21be49f03ba4361e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_bfloat16_neon.h @@ -0,0 +1,544 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] +#include +#include +#include +#include +#include +#include + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline +namespace CPU_CAPABILITY { + +// Following vec128_half_neon.h, we only support aarch64. +#if !defined(C10_MOBILE) && defined(__aarch64__) +#ifdef __BIG_ENDIAN__ +#error "Big endian is not supported." +#endif + +// Unlike the float16_t family of types, bfloat16_t is not available +// when we're not targeting bfloat16 hardware support on some +// platforms (but not Mac, so we have to be careful not to shadow the +// definitions in case they are actually there!). (See +// https://godbolt.org/z/orv6e94n4 ) So, we need to handle it as +// uint16_t in that case. +#define IMPLEMENT_AT_BF16_SHIM(vec_suffix) \ + inline at_bfloat16x4_t at_vget_low_bf16( \ + at_bfloat16x8_t a) { \ + return vget_low_##vec_suffix(a); \ + } \ + \ + inline at_bfloat16x4_t at_vget_high_bf16( \ + at_bfloat16x8_t a) { \ + return vget_high_##vec_suffix(a); \ + } \ + \ + inline at_bfloat16x8_t at_vcombine_bf16( \ + at_bfloat16x4_t low, \ + at_bfloat16x4_t high) { \ + return vcombine_##vec_suffix(low, high); \ + } \ + \ + inline at_bfloat16x8_t at_vdupq_n_bf16( \ + at_bfloat16_t value) { \ + return vdupq_n_##vec_suffix(value); \ + } \ + \ + inline at_bfloat16x8_t at_vld1q_bf16( \ + const at_bfloat16_t* ptr) { \ + return vld1q_##vec_suffix(ptr); \ + } \ + \ + inline void at_vst1q_bf16( \ + at_bfloat16_t* ptr, \ + at_bfloat16x8_t value) { \ + vst1q_##vec_suffix(ptr, value); \ + } \ + \ + template \ + inline at_bfloat16x8_t at_vreinterpretq_bf16_u16(T val) { \ + if constexpr (std::is_same_v) { \ + return val; \ + } else { \ + return vreinterpretq_bf16_u16(val); \ + } \ + } \ + template \ + inline at_bfloat16x4_t at_vreinterpret_bf16_u16(T val) { \ + if constexpr (std::is_same_v) { \ + return val; \ + } else { \ + return vreinterpret_bf16_u16(val); \ + } \ + } \ + template \ + inline uint16x8_t at_vreinterpretq_u16_bf16(T val) { \ + if constexpr (std::is_same_v) { \ + return val; \ + } else { \ + return vreinterpretq_u16_bf16(val); \ + } \ + } \ + template \ + inline uint16x4_t at_vreinterpret_u16_bf16(T val) { \ + if constexpr (std::is_same_v) { \ + return val; \ + } else { \ + return vreinterpret_u16_bf16(val); \ + } \ + } + +#ifdef __ARM_FEATURE_BF16 +using at_bfloat16x8_t = bfloat16x8_t; +using at_bfloat16x4_t = bfloat16x4_t; +using at_bfloat16_t = bfloat16_t; +IMPLEMENT_AT_BF16_SHIM(bf16) +#define at_vsetq_lane_bf16 vsetq_lane_bf16 +#define at_vgetq_lane_bf16 vgetq_lane_bf16 +#else +using at_bfloat16x8_t = uint16x8_t; +using at_bfloat16x4_t = uint16x4_t; +using at_bfloat16_t = uint16_t; +IMPLEMENT_AT_BF16_SHIM(u16) +#define at_vsetq_lane_bf16 vsetq_lane_u16 +#define at_vgetq_lane_bf16 vgetq_lane_u16 +#endif // __ARM_FEATURE_BF16 + +template +struct BlendBFloat16Regs { + static at_bfloat16x8_t impl( + const at_bfloat16x8_t& a, + const at_bfloat16x8_t& b, + at_bfloat16x8_t& res); +}; + +template +struct BlendBFloat16Regs { + static at_bfloat16x8_t impl( + const at_bfloat16x8_t& a, + const at_bfloat16x8_t& b, + at_bfloat16x8_t& res) { + return at_vsetq_lane_bf16(at_vgetq_lane_bf16(b, index), res, index); + } +}; + +template +struct BlendBFloat16Regs { + static at_bfloat16x8_t impl( + const at_bfloat16x8_t& a, + const at_bfloat16x8_t& b, + at_bfloat16x8_t& res) { + return at_vsetq_lane_bf16(at_vgetq_lane_bf16(a, index), res, index); + } +}; + +template <> +class Vectorized : public Vectorized16> { + using Base = Vectorized16>; + friend Base; + friend std::tuple, Vectorized> convert_bfloat16_float(const Vectorized& a); + friend Vectorized convert_float_bfloat16(const Vectorized& a, const Vectorized& b); + private: + Vectorized map2( + const Vectorized& second, + c10::BFloat16 (*const f)(c10::BFloat16, c10::BFloat16)) const { + __at_align__ c10::BFloat16 tmp_first[size()]; + __at_align__ c10::BFloat16 tmp_second[size()]; + store(tmp_first); // store this to tmp_first + second.store(tmp_second); + for (const auto i : c10::irange(size())) { + tmp_first[i] = f(tmp_first[i], tmp_second[i]); + } + return loadu(tmp_first); + } + + static float32x4_t convert_f32_bf16(at_bfloat16x4_t bf16) { +#ifdef __ARM_FEATURE_BF16 + return vcvt_f32_bf16(bf16); +#else + int32x4_t shift = vdupq_n_s32(16); + return vreinterpretq_f32_u32(vshlq_u32(vmovl_u16(bf16), shift)); +#endif // __ARM_FEATURE_BF16 + } + + static at_bfloat16x4_t convert_bf16_f32(const Vectorized& f32) { +#ifdef __ARM_FEATURE_BF16 + return vcvt_bf16_f32(f32); +#else + static_assert(std::is_same_v); + uint32x4_t as_uint32 = vreinterpretq_u32_f32(f32); + uint32x4_t rounding_bias = vaddq_u32(vandq_u32(vshrq_n_u32(as_uint32, 16), vdupq_n_u32(1)), vdupq_n_u32(0x7FFF)); + at_bfloat16x4_t rounded = vshrn_n_u32(vaddq_u32(as_uint32, rounding_bias), 16); + const auto bf16_nan = vdup_n_u16(0x7FC0); + return vbsl_u16(vmovn_u32(vreinterpretq_u32_f32(f32.isnan())), bf16_nan, rounded); +#endif // __ARM_FEATURE_BF16 + } + + Vectorized map_with_vec_float_method( + Vectorized (Vectorized::*m)() const) const { + float32x4_t v00 = convert_f32_bf16(at_vget_low_bf16(values)); + float32x4_t v01 = convert_f32_bf16(at_vget_high_bf16(values)); + Vectorized mv0 = (Vectorized(v00).*m)(); + Vectorized mv1 = (Vectorized(v01).*m)(); + at_bfloat16x4_t r00 = convert_bf16_f32(mv0); + at_bfloat16x4_t r01 = convert_bf16_f32(mv1); + return Vectorized(at_vcombine_bf16(r00, r01)); + } + + Vectorized map2_with_vec_float_method( + const Vectorized& second, + Vectorized (Vectorized::*m)(const Vectorized&) + const) const { + float32x4_t v00 = convert_f32_bf16(at_vget_low_bf16(values)); + float32x4_t v01 = convert_f32_bf16(at_vget_high_bf16(values)); + float32x4_t second_v00 = convert_f32_bf16(at_vget_low_bf16(second.values)); + float32x4_t second_v01 = convert_f32_bf16(at_vget_high_bf16(second.values)); + Vectorized mv0 = (Vectorized(v00).*m)(second_v00); + Vectorized mv1 = (Vectorized(v01).*m)(second_v01); + at_bfloat16x4_t r00 = convert_bf16_f32(mv0); + at_bfloat16x4_t r01 = convert_bf16_f32(mv1); + return Vectorized(at_vcombine_bf16(r00, r01)); + } + + Vectorized map2_bitmask_with_vec_float_method( + const Vectorized& second, + Vectorized (Vectorized::*m)(const Vectorized&) + const) const { + float32x4_t v00 = convert_f32_bf16(at_vget_low_bf16(values)); + float32x4_t v01 = convert_f32_bf16(at_vget_high_bf16(values)); + float32x4_t second_v00 = convert_f32_bf16(at_vget_low_bf16(second.values)); + float32x4_t second_v01 = convert_f32_bf16(at_vget_high_bf16(second.values)); + Vectorized mv0 = (Vectorized(v00).*m)(second_v00); + Vectorized mv1 = (Vectorized(v01).*m)(second_v01); + // Assume the operator returns a bitmask, not "real" floats, and + // just narrow the bits. All-ones is a NaN and will get mangled by conversion! + at_bfloat16x4_t r00 = at_vreinterpret_bf16_u16(vmovn_u32(vreinterpretq_u32_f32(mv0))); + at_bfloat16x4_t r01 = at_vreinterpret_bf16_u16(vmovn_u32(vreinterpretq_u32_f32(mv1))); + return Vectorized(at_vcombine_bf16(r00, r01)); + } + + public: + using Vectorized16::Vectorized16; + + Vectorized() = default; + + Vectorized(c10::BFloat16 val) : Vectorized16(at_vdupq_n_bf16(c10::bit_cast(val.x))) {} + Vectorized(float val) : Vectorized(c10::BFloat16(val)) {} + Vectorized( + value_type val0, + value_type val1, + value_type val2, + value_type val3, + value_type val4, + value_type val5, + value_type val6, + value_type val7) + : Vectorized16(at_bfloat16x8_t{ + c10::bit_cast(val0.x), + c10::bit_cast(val1.x), + c10::bit_cast(val2.x), + c10::bit_cast(val3.x), + c10::bit_cast(val4.x), + c10::bit_cast(val5.x), + c10::bit_cast(val6.x), + c10::bit_cast(val7.x)}) {} + + + static Vectorized blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // NOTE: blendv has the same problems as it does for Half; see comments in vec128_half_neon.h. + Vectorized vec(mask.values); + vec.values = at_vreinterpretq_bf16_u16( + vbslq_u16( + at_vreinterpretq_u16_bf16(vec.values), + at_vreinterpretq_u16_bf16(b.values), + at_vreinterpretq_u16_bf16(a.values))); + return vec; + } + static Vectorized set( + const Vectorized& a, + const Vectorized& b, + int64_t count = size()) { + uint16_t pre_mask[size()] = {0}; + for (int i = 0; i < count; i++) { + pre_mask[i] = 0xFFFF; + } + uint16x8_t mask = vld1q_u16(pre_mask); + + Vectorized vec( + at_vreinterpretq_bf16_u16( + vbslq_u16( + mask, + at_vreinterpretq_u16_bf16(b.values), + at_vreinterpretq_u16_bf16(a.values)))); + + return vec; + } + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) { + return at_vld1q_bf16(reinterpret_cast(ptr)); + } + __at_align__ at_bfloat16_t tmp_values[size()]; + std::memset(tmp_values, 0, sizeof(tmp_values)); + std::memcpy( + tmp_values, + reinterpret_cast(ptr), + count * sizeof(at_bfloat16_t)); + return at_vld1q_bf16(reinterpret_cast(tmp_values)); + } + void store(void* ptr, int64_t count = size()) const { + if (count == size()) { + at_vst1q_bf16(reinterpret_cast(ptr), values); + return; + } else { + at_bfloat16_t tmp_values[size()]; + at_vst1q_bf16(reinterpret_cast(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(at_bfloat16_t)); + } + } + Vectorized isnan() const { + // NOTE: we could make this faster by doing vectorized checks of + // exponent/payload bits. + __at_align__ c10::BFloat16 tmp[size()]; + __at_align__ c10::BFloat16 res[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + if (_isnan(tmp[i])) { + std::memset(static_cast(&res[i]), 0xFF, sizeof(c10::BFloat16)); + } else { + std::memset(static_cast(&res[i]), 0, sizeof(c10::BFloat16)); + } + } + return loadu(res); + } + bool has_inf_nan() const { + __at_align__ c10::BFloat16 tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + if (_isnan(tmp[i]) || _isinf(tmp[i])) { + return true; + } + } + return false; + } +#define DEFINE_UNARY_ELEMENTWISE_FUNC_VIA_FLOAT_METHOD(name) \ + Vectorized name() const { \ + return map_with_vec_float_method(&Vectorized::name); \ + } + +#define DEFINE_BINARY_COMPARISON_OPERATOR_VIA_FLOAT_METHOD(name) \ + Vectorized name(const Vectorized& other) const { \ + return map2_bitmask_with_vec_float_method(other, &Vectorized::name); \ + } + + DEFINE_UNARY_ELEMENTWISE_FUNC_VIA_FLOAT_METHOD(abs) + Vectorized frac() const; + DEFINE_UNARY_ELEMENTWISE_FUNC_VIA_FLOAT_METHOD(neg) + DEFINE_UNARY_ELEMENTWISE_FUNC_VIA_FLOAT_METHOD(trunc) + DEFINE_UNARY_ELEMENTWISE_FUNC_VIA_FLOAT_METHOD(sqrt) + DEFINE_UNARY_ELEMENTWISE_FUNC_VIA_FLOAT_METHOD(reciprocal) + DEFINE_BINARY_COMPARISON_OPERATOR_VIA_FLOAT_METHOD(operator==) + DEFINE_BINARY_COMPARISON_OPERATOR_VIA_FLOAT_METHOD(operator!=) + DEFINE_BINARY_COMPARISON_OPERATOR_VIA_FLOAT_METHOD(operator<) + DEFINE_BINARY_COMPARISON_OPERATOR_VIA_FLOAT_METHOD(operator<=) + DEFINE_BINARY_COMPARISON_OPERATOR_VIA_FLOAT_METHOD(operator>) + DEFINE_BINARY_COMPARISON_OPERATOR_VIA_FLOAT_METHOD(operator>=) + +#undef DEFINE_UNARY_ELEMENTWISE_FUNC_VIA_FLOAT_METHOD +#undef DEFINE_BINARY_ELEMENTWISE_FUNC_VIA_FLOAT_METHOD + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; // Vectorized + +inline std::tuple, Vectorized> convert_bfloat16_float(const Vectorized& a) { + static_assert(Vectorized::size() == 2 * Vectorized::size()); + at_bfloat16x8_t x = a; + float32x4_t x1 = Vectorized::convert_f32_bf16(at_vget_low_bf16(x)); + float32x4_t x2 = Vectorized::convert_f32_bf16(at_vget_high_bf16(x)); + return { Vectorized(x1), Vectorized(x2) }; +} +inline Vectorized convert_float_bfloat16(const Vectorized& a, const Vectorized& b) { + static_assert(Vectorized::size() == 2 * Vectorized::size()); + at_bfloat16x4_t x1 = Vectorized::convert_bf16_f32(a); + at_bfloat16x4_t x2 = Vectorized::convert_bf16_f32(b); + return Vectorized(at_vcombine_bf16(x1, x2)); +} + +template +Vectorized binary_operator_via_float( + Op op, + const Vectorized& a, + const Vectorized& b) { + const auto [a_float_low, a_float_high] = convert_bfloat16_float(a); + const auto [b_float_low, b_float_high] = convert_bfloat16_float(b); + return convert_float_bfloat16( + op(a_float_low, b_float_low), + op(a_float_high, b_float_high)); +} + +template <> +Vectorized inline operator+( + const Vectorized& a, + const Vectorized& b) { + return binary_operator_via_float(std::plus>(), a, b); +} + +template <> +Vectorized inline operator-( + const Vectorized& a, + const Vectorized& b) { + return binary_operator_via_float(std::minus>(), a, b); +} + +template <> +Vectorized inline operator*( + const Vectorized& a, + const Vectorized& b) { + return binary_operator_via_float(std::multiplies>(), a, b); +} + +template <> +Vectorized inline operator/( + const Vectorized& a, + const Vectorized& b) { + return binary_operator_via_float(std::divides>(), a, b); +} + +// frac. Implement this here so we can use subtraction +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + return binary_operator_via_float( + static_cast(*)(const Vectorized&, const Vectorized&)>(&maximum), + a, + b); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + return binary_operator_via_float( + static_cast(*)(const Vectorized&, const Vectorized&)>(&minimum), + a, + b); +} + +template <> +Vectorized inline clamp( + const Vectorized& a, + const Vectorized& min, + const Vectorized& max) { + return minimum(max, maximum(min, a)); +} + +template <> +Vectorized inline clamp_max( + const Vectorized& a, + const Vectorized& max) { + return minimum(max, a); +} + +template <> +Vectorized inline clamp_min( + const Vectorized& a, + const Vectorized& min) { + return maximum(min, a); +} + +template <> +Vectorized inline operator&( + const Vectorized& a, + const Vectorized& b) { + return Vectorized(at_vreinterpretq_bf16_u16(vandq_u16( + at_vreinterpretq_u16_bf16(a), at_vreinterpretq_u16_bf16(b)))); +} + +template <> +Vectorized inline operator|( + const Vectorized& a, + const Vectorized& b) { + return Vectorized(at_vreinterpretq_bf16_u16(vorrq_u16( + at_vreinterpretq_u16_bf16(a), at_vreinterpretq_u16_bf16(b)))); +} + +template <> +Vectorized inline operator^( + const Vectorized& a, + const Vectorized& b) { + return Vectorized(at_vreinterpretq_bf16_u16(veorq_u16( + at_vreinterpretq_u16_bf16(a), at_vreinterpretq_u16_bf16(b)))); +} + +inline Vectorized Vectorized::eq( + const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne( + const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt( + const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge( + const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt( + const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le( + const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +template <> +Vectorized inline fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + // NOTE [BF16 FMA]: There isn't an FMA that accumulates into BF16! Also, + // vbfmlalbq_f32 and vbfmlaltq_f32 take the even and odd-numbered + // elements, not the bottom and top half, so they don't seem + // particularly useful here. Ideally we would include dot product in + // the Vectorized interface... + return a * b + c; +} + +template <> +Vectorized inline fmsub( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + // See NOTE [BF16 FMA] above. + return a * b - c; +} + +#endif // !defined(C10_MOBILE) && defined(__aarch64__) + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_convert.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_convert.h new file mode 100644 index 0000000000000000000000000000000000000000..4131802c9923d44e168a69aa192f8f4a5b62406f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_convert.h @@ -0,0 +1,64 @@ +#pragma once +#include +#include + +namespace at::vec { +inline namespace CPU_CAPABILITY { +#if (defined(__aarch64__) && !defined(CPU_CAPABILITY_SVE256)) +template +struct VecConvert< + float, + 1, + src_t, + 1, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + return convert_int8_half_register_to_float(src[0]); + } +}; +template +struct VecConvert< + float, + 2, + src_t, + 1, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + const auto [v0, v1] = convert_int8_to_float(src[0]); + return VectorizedN(v0, v1); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + uint16x8_t u16_8 = vld1q_u16(reinterpret_cast(&src[0])); + auto u16_low1 = vget_low_u16(u16_8); + auto u16_high1 = vget_high_u16(u16_8); + float32x4_t f32x4_0 = vreinterpretq_f32_u32(vshlq_n_u32(vmovl_u16(u16_low1), 16)); + float32x4_t f32x4_1 = vreinterpretq_f32_u32(vshlq_n_u32(vmovl_u16(u16_high1), 16)); + result[0] = f32x4_0; + result[1] = f32x4_1; + return result; + } +}; +// Half register to full register. +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + uint16x4_t u16_8 = vld1_u16(reinterpret_cast(&src[0])); + float32x4_t f32x4_0 = vreinterpretq_f32_u32(vshlq_n_u32(vmovl_u16(u16_8), 16)); + result[0] = f32x4_0; + return result; + } +}; + +#endif // defined(__aarch64__) && !defined(CPU_CAPABILITY_SVE256) +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_float_neon.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_float_neon.h new file mode 100644 index 0000000000000000000000000000000000000000..a51a8777fb6dc371e25578f0f119e60c53349723 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_float_neon.h @@ -0,0 +1,581 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include + +#if defined(__aarch64__) && defined(AT_BUILD_ARM_VEC256_WITH_SLEEF) +#include +#endif + +// Sleef offers vectorized versions of some transcedentals +// such as sin, cos, tan etc.. +// However for now opting for STL, since we are not building +// with Sleef for mobile yet. + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +// Right now contains only aarch64 implementation. +// Due to follow two reasons aarch32 is not currently supported. +// 1. Due to difference in ISA been aarch32 and aarch64, intrinsics +// that work for aarch64 dont work for aarch32. +// 2. Android NDK r21 has problems with compiling aarch32. +// Clang seg faults. +// https://github.com/android/ndk/issues/1248 +// https://bugs.llvm.org/show_bug.cgi?id=45824 +// Most likely we will do aarch32 support with inline asm. +#if defined(__aarch64__) + +#ifdef __BIG_ENDIAN__ +#error "Big endian is not supported." +#endif + +#if defined(AT_BUILD_ARM_VEC256_WITH_SLEEF) +#define USE_SLEEF(sleef_code, non_sleef_code) sleef_code +#else +#define USE_SLEEF(sleef_code, non_sleef_code) non_sleef_code +#endif + +template +struct BlendRegs { + static float32x4_t impl( + const float32x4_t& a, const float32x4_t& b, float32x4_t& res); +}; + +template +struct BlendRegs{ + static float32x4_t impl( + const float32x4_t& a, const float32x4_t& b, float32x4_t& res) { + return vsetq_lane_f32(vgetq_lane_f32(b, index), res, index); + } +}; + +template +struct BlendRegs{ + static float32x4_t impl( + const float32x4_t& a, const float32x4_t& b, float32x4_t& res) { + return vsetq_lane_f32(vgetq_lane_f32(a, index), res, index); + } +}; + +template <> class Vectorized { +private: + float32x4_t values; +public: + using value_type = float; + using size_type = int; + static constexpr size_type size() { + return 4; + } + Vectorized() {} + Vectorized(float32x4_t v) : values(v) {} + Vectorized(float val) : values{vdupq_n_f32(val)} {} + Vectorized(float val0, float val1, float val2, float val3) : + values{val0, val1, val2, val3} {} + Vectorized(float (&arr)[4]) : Vectorized(arr[0], arr[1], arr[2], arr[3]) {} + operator float32x4_t() const { + return values; + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + Vectorized vec; + vec.values = + BlendRegs<0, (mask & 0x01)!=0>::impl( + a.values, b.values, vec.values); + vec.values = + BlendRegs<1, (mask & 0x02)!=0>::impl( + a.values, b.values, vec.values); + vec.values = + BlendRegs<2, (mask & 0x04)!=0>::impl( + a.values, b.values, vec.values); + vec.values = + BlendRegs<3, (mask & 0x08)!=0>::impl( + a.values, b.values, vec.values); + return vec; + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + // TODO + // NB: This requires that each value, i.e., each uint value, + // of the mask either all be zeros or all be 1s. + // We perhaps need some kind of an assert? + // But that will affect performance. + Vectorized vec(mask.values); + vec.values = vbslq_f32( + vreinterpretq_u32_f32(vec.values), + b.values, + a.values); + return vec; + } + template + static Vectorized arange(float base = 0.f, step_t step = static_cast(1)) { + const Vectorized base_vec(base); + const Vectorized step_vec(step); + const Vectorized step_sizes(0, 1, 2, 3); + return fmadd(step_sizes, step_vec, base_vec); + } + static Vectorized set(const Vectorized& a, const Vectorized& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + { + Vectorized vec; + static uint32x4_t mask_low = {0xFFFFFFFF, 0x0, 0x0, 0x0}; + vec.values = vreinterpretq_f32_u32(mask_low); + vec.values = vbslq_f32( + vreinterpretq_u32_f32(vec.values), + b.values, + a.values); + return vec; + } + case 2: + { + Vectorized vec; + static uint32x4_t mask_low = {0xFFFFFFFF, 0xFFFFFFFF, 0x0, 0x0}; + vec.values = vreinterpretq_f32_u32(mask_low); + vec.values = vbslq_f32( + vreinterpretq_u32_f32(vec.values), + b.values, + a.values); + return vec; + } + case 3: + { + Vectorized vec; + static uint32x4_t mask_low = {0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0x0}; + vec.values = vreinterpretq_f32_u32(mask_low); + vec.values = vbslq_f32( + vreinterpretq_u32_f32(vec.values), + b.values, + a.values); + return vec; + } + } + return b; + } + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) { + return vld1q_f32(reinterpret_cast(ptr)); + } else { + __at_align__ float tmp_values[size()]; + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0.0; + } + std::memcpy( + tmp_values, + reinterpret_cast(ptr), + count * sizeof(float)); + return vld1q_f32(reinterpret_cast(tmp_values)); + } + } + void store(void* ptr, int64_t count = size()) const { + if (count == size()) { + vst1q_f32(reinterpret_cast(ptr), values); + } else { + float tmp_values[size()]; + vst1q_f32(reinterpret_cast(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(float)); + } + } + // Very slow implementation of indexing. + // Only required because vec256_qint refers to this. + // Once we specialize that implementation for ARM + // this should be removed. TODO (kimishpatel) + float operator[](int idx) const { + __at_align__ float tmp[size()]; + store(tmp); + return tmp[idx]; + } + float operator[](int idx) { + __at_align__ float tmp[size()]; + store(tmp); + return tmp[idx]; + } + // For boolean version where we want to if any 1/all zero + // etc. can be done faster in a different way. + int zero_mask() const { + __at_align__ float tmp[size()]; + store(tmp); + int mask = 0; + for (int i = 0; i < size(); ++ i) { + if (tmp[i] == 0.f) { + mask |= (1 << i); + } + } + return mask; + } + Vectorized isnan() const { + return vreinterpretq_f32_u32(vmvnq_u32(vceqq_f32(values, values))); + } + bool has_inf_nan() const { + __at_align__ float tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + if(_isnan(tmp[i]) || _isinf(tmp[i])) { + return true; + } + } + return false; + } + Vectorized map(float (*const f)(float)) const { + __at_align__ float tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + Vectorized map2( + const Vectorized& second, + float (*const f)(float, float)) const { + __at_align__ float tmp[size()]; + __at_align__ float tmp_second[size()]; + store(tmp); + second.store(tmp_second); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i], tmp_second[i]); + } + return loadu(tmp); + } + Vectorized abs() const { + return Vectorized(vabsq_f32(values)); + } + Vectorized angle() const { + auto zero = Vectorized(0); + auto pi = Vectorized(c10::pi); + auto tmp = blendv(zero, pi, *this < zero); + return blendv(tmp, *this, isnan()); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return Vectorized(0.f); + } + Vectorized conj() const { + return *this; + } +#define DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC_WITH_SLEEF_NAME(name, sleef_name) \ + Vectorized name() const { \ + return USE_SLEEF( \ + Vectorized(sleef_name(values)), \ + map(std::name) \ + ); \ + } + +#define DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(name) \ + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC_WITH_SLEEF_NAME(name, Sleef_##name##f4_u10) + + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(acos) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(acosh) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(asin) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(asinh) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(atan) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(atanh) + +#define DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC_WITH_SLEEF_NAME(name, sleef_name) \ + Vectorized name(const Vectorized &arg) const { \ + return USE_SLEEF( \ + Vectorized(sleef_name(values, arg.values)), \ + map2(arg, std::name) \ + ); \ + } + +#define DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC(name) \ + DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC_WITH_SLEEF_NAME(name, Sleef_##name##f4_u10) + + DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC(atan2) + DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC_WITH_SLEEF_NAME(copysign, Sleef_copysignf4) + Vectorized erf() const; + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC_WITH_SLEEF_NAME(erfc, Sleef_erfcf4_u15) + Vectorized erfinv() const { + return map(calc_erfinv); + } + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(exp) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(exp2) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(expm1) + Vectorized exp_u20() const { + return exp(); + } + DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC_WITH_SLEEF_NAME(fmod, Sleef_fmodf4) + DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC_WITH_SLEEF_NAME(hypot, Sleef_hypotf4_u05) + Vectorized i0() const { + return map(calc_i0); + } + Vectorized i0e() const { + return map(calc_i0e); + } + Vectorized digamma() const { + return map(calc_digamma); + } + Vectorized igamma(const Vectorized &x) const { + return map2(x, calc_igamma); + } + Vectorized igammac(const Vectorized &x) const { + return map2(x, calc_igammac); + } + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(log) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(log10) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(log1p) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(log2) + DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC_WITH_SLEEF_NAME(nextafter, Sleef_nextafterf4) + Vectorized frac() const; + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(sin) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(sinh) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(cos) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(cosh) + Vectorized ceil() const { + return map(at::native::ceil_impl); + } + Vectorized floor() const { + return map(at::native::floor_impl); + } + Vectorized neg() const { + return Vectorized( + vnegq_f32(values)); + } + Vectorized round() const { + // We do not use std::round because we would like to round midway numbers to the nearest even integer. + return map(at::native::round_impl); + } + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(tan) + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(tanh) + Vectorized trunc() const { + return Vectorized(vrndq_f32(values)); + } + DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC(lgamma) + Vectorized sqrt() const { + return Vectorized(vsqrtq_f32(values)); + } + Vectorized reciprocal() const { + return Vectorized(vdivq_f32(vdupq_n_f32(1.0f), values)); + } + Vectorized rsqrt() const { + return this->sqrt().reciprocal(); + } + DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC(pow) + Vectorized operator==(const Vectorized& other) const { + return Vectorized(vreinterpretq_f32_u32(vceqq_f32(values, other.values))); + } + + Vectorized operator!=(const Vectorized& other) const { + float32x4_t r0 = vreinterpretq_f32_u32( + vmvnq_u32(vceqq_f32(values, other.values))); + return Vectorized(r0); + } + + Vectorized operator<(const Vectorized& other) const { + return Vectorized(vreinterpretq_f32_u32(vcltq_f32(values, other.values))); + } + + Vectorized operator<=(const Vectorized& other) const { + return Vectorized(vreinterpretq_f32_u32(vcleq_f32(values, other.values))); + } + + Vectorized operator>(const Vectorized& other) const { + return Vectorized(vreinterpretq_f32_u32(vcgtq_f32(values, other.values))); + } + + Vectorized operator>=(const Vectorized& other) const { + return Vectorized(vreinterpretq_f32_u32(vcgeq_f32(values, other.values))); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized(vaddq_f32(a, b)); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized(vsubq_f32(a, b)); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return Vectorized(vmulq_f32(a, b)); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return Vectorized(vdivq_f32(a, b)); +} + +// frac. Implement this here so we can use subtraction +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +//Added sleef Implementation for Maximum +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + if(!a.has_inf_nan() && !b.has_inf_nan()){ + return USE_SLEEF( + Vectorized(Sleef_fmaxf4(a, b)), + Vectorized(vmaxq_f32(a,b))); + } + else{ + return Vectorized(vmaxq_f32(a, b)); + } +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return Vectorized(vminq_f32(a, b)); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min, const Vectorized& max) { + return minimum(max, maximum(min, a)); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + return minimum(max, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + return maximum(min, a); +} + +template <> +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized(vreinterpretq_f32_u32(vandq_u32( + vreinterpretq_u32_f32(a), + vreinterpretq_u32_f32(b)))); +} + +template <> +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized(vreinterpretq_f32_u32(vorrq_u32( + vreinterpretq_u32_f32(a), + vreinterpretq_u32_f32(b)))); +} + +template <> +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized(vreinterpretq_f32_u32(veorq_u32( + vreinterpretq_u32_f32(a), + vreinterpretq_u32_f32(b)))); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0f); +} + +template <> +inline void convert(const float* src, int32_t* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + vst1q_s32(dst + i, vcvtq_s32_f32(vld1q_f32(src + i))); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +template <> +inline void convert(const int32_t* src, float* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + vst1q_f32(dst + i, vcvtq_f32_s32(vld1q_s32(src + i))); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +template <> +Vectorized inline fmadd(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return Vectorized(vfmaq_f32(c, a, b)); +} + +template <> +Vectorized inline fmsub(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return Vectorized(vnegq_f32(vfmsq_f32(c, a, b))); +} + +inline Vectorized Vectorized::erf() const{ + // constants + const Vectorized neg_zero_vec(-0.f); + const Vectorized one_vec(1.0f); + const Vectorized p(0.3275911f); + const Vectorized p1(0.254829592f); + const Vectorized p2(-0.284496736f); + const Vectorized p3(1.421413741f); + const Vectorized p4(-1.453152027f); + const Vectorized p5(1.061405429f); + // sign(x) + auto sign_mask = neg_zero_vec & *this; + auto abs_vec = this->abs(); + // t = 1 / (p * abs(x) + 1) + auto tmp0 = fmadd(p, abs_vec, one_vec); + auto t = one_vec / tmp0; + // r = p5 * t ^ 4 + p4 * t ^ 3 + p3 * t ^ 2 + p2 * t + p1 + auto tmp1 = fmadd(p5, t, p4); + auto tmp2 = fmadd(tmp1, t, p3); + auto tmp3 = fmadd(tmp2, t, p2); + auto r = fmadd(tmp3, t, p1); + // - exp(- x * x) + auto pow_2 = (*this) * (*this); + auto neg_pow_2 = pow_2 ^ neg_zero_vec; + auto tmp4 = neg_pow_2.map(std::exp); // This can be swapped for a faster implementation of exp. + auto tmp5 = tmp4 ^ neg_zero_vec; + // erf(x) = sign(x) * (1 - r * t * exp(- x * x)) + auto tmp6 = t * tmp5; + auto tmp7 = fmadd(tmp6, r, one_vec); + return tmp7 ^ sign_mask; +} +#undef DEFINE_SLEEF_COMPATIBLE_BINARY_ELEMENTWISE_FUNC +#undef DEFINE_SLEEF_COMPATIBLE_UNARY_ELEMENTWISE_FUNC +#endif /* defined(aarch64) */ + +}} // namespace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_half_neon.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_half_neon.h new file mode 100644 index 0000000000000000000000000000000000000000..e75e9d67655c23a840c99cf9381b80be5fa840e4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_half_neon.h @@ -0,0 +1,593 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#include +#include +#include +#include + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +// Right now contains only aarch64 implementation. +// Due to follow two reasons aarch32 is not currently supported. +// 1. Due to difference in ISA been aarch32 and aarch64, intrinsics +// that work for aarch64 dont work for aarch32. +// 2. Android NDK r21 has problems with compiling aarch32. +// Clang seg faults. +// https://github.com/android/ndk/issues/1248 +// https://bugs.llvm.org/show_bug.cgi?id=45824 +// Most likely we will do aarch32 support with inline asm. +#if !defined(C10_MOBILE) && defined(__aarch64__) + +#ifdef __BIG_ENDIAN__ +#error "Big endian is not supported." +#endif + +template +struct BlendHalfRegs { + static float16x8_t impl( + const float16x8_t& a, + const float16x8_t& b, + float16x8_t& res); +}; + +template +struct BlendHalfRegs { + static float16x8_t impl( + const float16x8_t& a, + const float16x8_t& b, + float16x8_t& res) { + return vsetq_lane_f16(vgetq_lane_f16(b, index), res, index); + } +}; + +template +struct BlendHalfRegs { + static float16x8_t impl( + const float16x8_t& a, + const float16x8_t& b, + float16x8_t& res) { + return vsetq_lane_f16(vgetq_lane_f16(a, index), res, index); + } +}; + +// On ARM, Half type supports float16_t->Half constructor and Half->float16_t +// conversion +template <> +class Vectorized : public Vectorized16> { + using Base = Vectorized16>; + friend Base; + private: + // We use these private map functions to implement various methods + Vectorized map_with_vec_float_method( + Vectorized (Vectorized::*m)() const) const { + float32x4_t v00 = vcvt_f32_f16(vget_low_f16(values)); + float32x4_t v01 = vcvt_f32_f16(vget_high_f16(values)); + Vectorized mv0 = (Vectorized(v00).*m)(); + Vectorized mv1 = (Vectorized(v01).*m)(); + float16x4_t r00 = vcvt_f16_f32(mv0); + float16x4_t r01 = vcvt_f16_f32(mv1); + return Vectorized(vcombine_f16(r00, r01)); + } + + Vectorized map2_with_vec_float_method( + const Vectorized& second, + Vectorized (Vectorized::*m)(const Vectorized&) + const) const { + float32x4_t v00 = vcvt_f32_f16(vget_low_f16(values)); + float32x4_t v01 = vcvt_f32_f16(vget_high_f16(values)); + float32x4_t second_v00 = vcvt_f32_f16(vget_low_f16(second.values)); + float32x4_t second_v01 = vcvt_f32_f16(vget_high_f16(second.values)); + Vectorized mv0 = (Vectorized(v00).*m)(Vectorized(second_v00)); + Vectorized mv1 = (Vectorized(v01).*m)(Vectorized(second_v01)); + float16x4_t r00 = vcvt_f16_f32(mv0); + float16x4_t r01 = vcvt_f16_f32(mv1); + + // Pack result into Vectorized + return Vectorized(vcombine_f16(r00, r01)); + } + + Vectorized map2_bitmask_with_vec_float_method( + const Vectorized& second, + Vectorized (Vectorized::*m)(const Vectorized&) + const) const { + float32x4_t v00 = vcvt_f32_f16(vget_low_f16(values)); + float32x4_t v01 = vcvt_f32_f16(vget_high_f16(values)); + float32x4_t second_v00 = vcvt_f32_f16(vget_low_f16(second.values)); + float32x4_t second_v01 = vcvt_f32_f16(vget_high_f16(second.values)); + Vectorized mv0 = (Vectorized(v00).*m)(Vectorized(second_v00)); + Vectorized mv1 = (Vectorized(v01).*m)(Vectorized(second_v01)); + // Assume the operator returns a bitmask, not "real" floats, and + // just narrow the bits. All-ones is a NaN and will get mangled by conversion! + float16x4_t r00 = vreinterpret_f16_u16(vmovn_u32(vreinterpretq_u32_f32(mv0))); + float16x4_t r01 = vreinterpret_f16_u16(vmovn_u32(vreinterpretq_u32_f32(mv1))); + + // Pack result into Vectorized + return Vectorized(vcombine_f16(r00, r01)); + } + + public: + using Vectorized16::Vectorized16; + + Vectorized() = default; + + // A ctor that accepts c10::Half is needed to fit interface with vec_base.h + // A second constructor that takes float16_t is also included + Vectorized(c10::Half val) + : Vectorized((float16_t)val) {} + Vectorized(float16_t val) + : Vectorized16(vdupq_n_f16(val)) {} + Vectorized( + value_type val0, + value_type val1, + value_type val2, + value_type val3, + value_type val4, + value_type val5, + value_type val6, + value_type val7) + : Vectorized16(float16x8_t{ + val0, + val1, + val2, + val3, + val4, + val5, + val6, + val7}) {} + + + static Vectorized blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // Note: using blendv is very awkward because 0xFFFF is one of + // many NaN's in FP16 It's unfortunate that the mask has type Half + // (required from vec_base) + + // TODO + // NB: This requires that each value, i.e., each uint value, + // of the mask either all be zeros or all be 1s. + // We perhaps need some kind of an assert? + // But that will affect performance. + + // NOTE [vbslq_f16]: vbslq_f16 doesn't work on clang without + // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC. vbslq_u16 generates the + // same instruction anyway. see https://godbolt.org/z/cY4a55Y7P + Vectorized vec(mask.values); + vec.values = vreinterpretq_f16_u16( + vbslq_u16( + vreinterpretq_u16_f16(vec.values), + vreinterpretq_u16_f16(b.values), + vreinterpretq_u16_f16(a.values))); + return vec; + } + static Vectorized set( + const Vectorized& a, + const Vectorized& b, + int64_t count = size()) { + uint16_t pre_mask[size()] = {0}; + for (int i = 0; i < count; i++) { + pre_mask[i] = 0xFFFF; + } + uint16x8_t mask = vld1q_u16(pre_mask); + + // Using blendv is awkward because 0xFFFF is one of many NaN's in FP16 + // so we directly use vbslq_u16 instead. (See NOTE [vbslq_f16] above.) + Vectorized vec( + vreinterpretq_f16_u16( + vbslq_u16( + mask, + vreinterpretq_u16_f16(b.values), + vreinterpretq_u16_f16(a.values)))); + + return vec; + } + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) { + return vld1q_f16(reinterpret_cast(ptr)); + } + __at_align__ float16_t tmp_values[size()]; + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy( + tmp_values, + reinterpret_cast(ptr), + count * sizeof(float16_t)); + return vld1q_f16(reinterpret_cast(tmp_values)); + } + void store(void* ptr, int64_t count = size()) const { + if (count == size()) { + vst1q_f16(reinterpret_cast(ptr), values); + return; + } else { + float16_t tmp_values[size()]; + vst1q_f16(reinterpret_cast(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(float16_t)); + } + } + // For boolean version where we want to if any 1/all zero + // etc. can be done faster in a different way. + Vectorized isnan() const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return vreinterpretq_f16_u16(vmvnq_u16(vceqq_f16(values, values))); +#else + // NOTE: we could make this faster by doing vectorized checks of + // exponent/payload bits. + __at_align__ c10::Half tmp[size()]; + __at_align__ c10::Half res[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + if (_isnan(tmp[i])) { + std::memset(static_cast(&res[i]), 0xFF, sizeof(c10::Half)); + } else { + std::memset(static_cast(&res[i]), 0, sizeof(c10::Half)); + } + } + return loadu(res); +#endif + } + bool has_inf_nan() const { + __at_align__ c10::Half tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + if (_isnan(tmp[i]) || _isinf(tmp[i])) { + return true; + } + } + return false; + } + Vectorized abs() const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vabsq_f16(values)); +#else + return map_with_vec_float_method(&Vectorized::abs); +#endif + } + Vectorized frac() const; + Vectorized neg() const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vnegq_f16(values)); +#else + return map_with_vec_float_method(&Vectorized::neg); +#endif + } + Vectorized trunc() const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vrndq_f16(values)); +#else + return map_with_vec_float_method(&Vectorized::trunc); +#endif + } + Vectorized sqrt() const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vsqrtq_f16(values)); +#else + return map_with_vec_float_method(&Vectorized::sqrt); +#endif + } + Vectorized reciprocal() const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + auto ones = vdupq_n_f16(1.0f); + return Vectorized(vdivq_f16(ones, values)); +#else + return map_with_vec_float_method(&Vectorized::reciprocal); +#endif + } + Vectorized operator==(const Vectorized& other) const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vreinterpretq_f16_u16(vceqq_f16(values, other.values))); +#else + return map2_bitmask_with_vec_float_method(other, &Vectorized::operator==); +#endif + } + + Vectorized operator!=(const Vectorized& other) const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vreinterpretq_f16_u16( + vmvnq_u16(vceqq_f16(values, other.values)))); +#else + return map2_bitmask_with_vec_float_method(other, &Vectorized::operator!=); +#endif + } + + Vectorized operator<(const Vectorized& other) const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vreinterpretq_f16_u16(vcltq_f16(values, other.values))); +#else + return map2_bitmask_with_vec_float_method(other, &Vectorized::operator<); +#endif + } + + Vectorized operator<=(const Vectorized& other) const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vreinterpretq_f16_u16(vcleq_f16(values, other.values))); +#else + return map2_bitmask_with_vec_float_method(other, &Vectorized::operator<=); +#endif + } + + Vectorized operator>(const Vectorized& other) const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vreinterpretq_f16_u16(vcgtq_f16(values, other.values))); +#else + return map2_bitmask_with_vec_float_method(other, &Vectorized::operator>); +#endif + } + + Vectorized operator>=(const Vectorized& other) const { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vreinterpretq_f16_u16(vcgeq_f16(values, other.values))); +#else + return map2_bitmask_with_vec_float_method(other, &Vectorized::operator>=); +#endif + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; // Vectorized + +inline std::tuple, Vectorized> convert_half_float(const Vectorized& a) { + static_assert(Vectorized::size() == 2 * Vectorized::size()); + float16x8_t x = a; + float32x4_t x1 = vcvt_f32_f16(vget_low_f16(x)); + float32x4_t x2 = vcvt_f32_f16(vget_high_f16(x)); + return { Vectorized(x1), Vectorized(x2) }; +} +inline Vectorized convert_float_half(const Vectorized& a, const Vectorized& b) { + static_assert(Vectorized::size() == 2 * Vectorized::size()); + float32x4_t x = a; + float32x4_t y = b; + float16x4_t x1 = vcvt_f16_f32(x); + float16x4_t x2 = vcvt_f16_f32(y); + return Vectorized(vcombine_f16(x1, x2)); +} + +template +Vectorized binary_operator_via_float( + Op op, + const Vectorized& a, + const Vectorized& b) { + const auto [a_float_low, a_float_high] = convert_half_float(a); + const auto [b_float_low, b_float_high] = convert_half_float(b); + return convert_float_half( + op(a_float_low, b_float_low), + op(a_float_high, b_float_high)); +} + +template <> +Vectorized inline operator+( + const Vectorized& a, + const Vectorized& b) { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vaddq_f16(a, b)); +#else + return binary_operator_via_float(std::plus>(), a, b); +#endif +} + +template <> +Vectorized inline operator-( + const Vectorized& a, + const Vectorized& b) { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vsubq_f16(a, b)); +#else + return binary_operator_via_float(std::minus>(), a, b); +#endif +} + +template <> +Vectorized inline operator*( + const Vectorized& a, + const Vectorized& b) { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vmulq_f16(a, b)); +#else + return binary_operator_via_float(std::multiplies>(), a, b); +#endif +} + +template <> +Vectorized inline operator/( + const Vectorized& a, + const Vectorized& b) { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vdivq_f16(a, b)); +#else + return binary_operator_via_float(std::divides>(), a, b); +#endif +} + +// frac. Implement this here so we can use subtraction +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vmaxq_f16(a, b)); +#else + return binary_operator_via_float( + static_cast(*)(const Vectorized&, const Vectorized&)>(&maximum), + a, + b); +#endif +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vminq_f16(a, b)); +#else + return binary_operator_via_float( + static_cast(*)(const Vectorized&, const Vectorized&)>(&minimum), + a, + b); +#endif +} + +template <> +Vectorized inline clamp( + const Vectorized& a, + const Vectorized& min, + const Vectorized& max) { + return minimum(max, maximum(min, a)); +} + +template <> +Vectorized inline clamp_max( + const Vectorized& a, + const Vectorized& max) { + return minimum(max, a); +} + +template <> +Vectorized inline clamp_min( + const Vectorized& a, + const Vectorized& min) { + return maximum(min, a); +} + +template <> +Vectorized inline operator&( + const Vectorized& a, + const Vectorized& b) { + return Vectorized(vreinterpretq_f16_u16(vandq_u16( + vreinterpretq_u16_f16(a), vreinterpretq_u16_f16(b)))); +} + +template <> +Vectorized inline operator|( + const Vectorized& a, + const Vectorized& b) { + return Vectorized(vreinterpretq_f16_u16(vorrq_u16( + vreinterpretq_u16_f16(a), vreinterpretq_u16_f16(b)))); +} + +template <> +Vectorized inline operator^( + const Vectorized& a, + const Vectorized& b) { + return Vectorized(vreinterpretq_f16_u16(veorq_u16( + vreinterpretq_u16_f16(a), vreinterpretq_u16_f16(b)))); +} + +inline Vectorized Vectorized::eq( + const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne( + const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt( + const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge( + const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt( + const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le( + const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +// These are global functions, so the defaults in vec_base.h should +// work fine if __ARM_FEATURE_FP16_VECTOR_ARITHMETIC is not available. +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC +template <> +inline void convert(const float16_t* src, int16_t* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); + i += Vectorized::size()) { + vst1q_s16(dst + i, vcvtq_s16_f16(vld1q_f16(src + i))); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +template <> +inline void convert(const int16_t* src, float16_t* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); + i += Vectorized::size()) { + vst1q_f16(dst + i, vcvtq_f16_s16(vld1q_s16(src + i))); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} +#endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + +template <> +Vectorized inline fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vfmaq_f16(c, a, b)); +#else + return a * b + c; +#endif +} + +template <> +Vectorized inline fmsub( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { +#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC + return Vectorized(vnegq_f16(vfmsq_f16(c, a, b))); +#else + return a * b - c; +#endif +} +#endif // !defined(C10_MOBILE) && defined(__aarch64__) + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_reduced_precision_common_neon.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_reduced_precision_common_neon.h new file mode 100644 index 0000000000000000000000000000000000000000..fec580eef4d6297354596d5b28e51e16167a8b21 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec128/vec128_reduced_precision_common_neon.h @@ -0,0 +1,266 @@ +#pragma once +// Shared code for bfloat16 and float16. + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +// Shared implementation between Vectorized and +// Vectorized. Uses CRTP to allow derived class +// customization. +template typename BlendRegs, typename Derived> +struct Vectorized16 { + protected: + VecT values; + public: + using value_type = ValueT; + using size_type = int; + static constexpr size_type size() { + static_assert(sizeof(VecT) == 8 * sizeof(value_type)); + return 8; + } + + protected: + Derived map2( + const Derived& second, + value_type (*const f)(value_type, value_type)) const { + __at_align__ value_type tmp_first[size()]; + __at_align__ value_type tmp_second[size()]; + static_cast(this)->store(tmp_first); // store this to tmp_first + second.store(tmp_second); + for (const auto i : c10::irange(size())) { + tmp_first[i] = f(tmp_first[i], tmp_second[i]); + } + return Derived::loadu(tmp_first); + } + + public: + Vectorized16() = default; + Vectorized16(VecT v) : values(v) {} + + operator VecT() const { + return values; + } + + template + static Derived blend(const Derived& a, const Derived& b) { + Derived vec; + vec.values = BlendRegs<0, (mask & 0x01) != 0>::impl( + a.values, b.values, vec.values); + vec.values = BlendRegs<1, (mask & 0x02) != 0>::impl( + a.values, b.values, vec.values); + vec.values = BlendRegs<2, (mask & 0x04) != 0>::impl( + a.values, b.values, vec.values); + vec.values = BlendRegs<3, (mask & 0x08) != 0>::impl( + a.values, b.values, vec.values); + + vec.values = BlendRegs<4, (mask & 0x10) != 0>::impl( + a.values, b.values, vec.values); + vec.values = BlendRegs<5, (mask & 0x20) != 0>::impl( + a.values, b.values, vec.values); + vec.values = BlendRegs<6, (mask & 0x40) != 0>::impl( + a.values, b.values, vec.values); + vec.values = BlendRegs<7, (mask & 0x80) != 0>::impl( + a.values, b.values, vec.values); + + return vec; + } + + template + static Derived arange( + value_type base = 0, + step_t step = static_cast(1)) { + const Derived base_vec(base); + const Derived step_vec(step); + const Derived step_sizes( + value_type(0), + value_type(1), + value_type(2), + value_type(3), + value_type(4), + value_type(5), + value_type(6), + value_type(7)); + return fmadd(step_sizes, step_vec, base_vec); + } + + // Very slow implementation of indexing. + // Only required because vec256_qint refers to this. + // Once we specialize that implementation for ARM + // this should be removed. TODO (kimishpatel) + value_type operator[](int idx) const { + __at_align__ value_type tmp[size()]; + static_cast(this)->store(tmp); + return tmp[idx]; + } + + int zero_mask() const { + __at_align__ value_type tmp[size()]; + static_cast(this)->store(tmp); + int mask = 0; + for (int i = 0; i < size(); ++i) { + if (tmp[i] == 0) { + mask |= (1 << i); + } + } + return mask; + } + + Derived map(value_type (*const f)(value_type)) const { + __at_align__ value_type tmp[size()]; + static_cast(this)->store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return Derived::loadu(tmp); + } + + Derived angle() const { + auto zero = Derived(0); + auto pi = Derived(c10::pi); + auto tmp = Derived::blendv(zero, pi, *static_cast(this) < zero); + return Derived::blendv(tmp, *static_cast(this), static_cast(this)->isnan()); + } + Derived real() const { + return *this; + } + Derived imag() const { + return Derived(0); + } + Derived conj() const { + return *this; + } + + // Sleef does not support FP16/BF16, so many math functions are applied by + // converting to FP32, applying the math function, and then converting back to + // FP16/BF16. + Derived acos() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::acos); + } + Derived acosh() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::acosh); + } + Derived asin() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::asin); + } + Derived asinh() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::asinh); + } + Derived atan() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::atan); + } + Derived atanh() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::atanh); + } + Derived atan2(const Derived& exp) const { + return static_cast(this)->map2_with_vec_float_method(exp, &Vectorized::atan2); + } + Derived copysign(const Derived& sign) const { + return static_cast(this)->map2_with_vec_float_method(sign, &Vectorized::copysign); + } + Derived erf() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::erf); + } + Derived erfc() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::erfc); + } + Derived erfinv() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::erfinv); + } + Derived exp() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::exp); + } + Derived exp2() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::exp2); + } + Derived expm1() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::expm1); + } + Derived exp_u20() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::exp_u20); + } + Derived fmod(const Derived& q) const { + // This function is questionable with a conversion, so we use map2 + return map2(q, std::fmod); + } + Derived hypot(const Derived& b) const { + return static_cast(this)->map2_with_vec_float_method(b, &Vectorized::hypot); + } + Derived i0() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::i0); + } + Derived i0e() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::i0e); + } + Derived digamma() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::digamma); + } + Derived igamma(const Derived& x) const { + return static_cast(this)->map2_with_vec_float_method(x, &Vectorized::igamma); + } + Derived igammac(const Derived& x) const { + return static_cast(this)->map2_with_vec_float_method(x, &Vectorized::igammac); + } + Derived log() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::log); + } + Derived log10() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::log10); + } + Derived log1p() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::log1p); + } + Derived log2() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::log2); + } + Derived nextafter(const Derived& b) const { + // This function does not make sense with conversion, so we use map2 + return map2(b, std::nextafter); + } + Derived sin() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::sin); + } + Derived sinh() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::sinh); + } + Derived cos() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::cos); + } + Derived cosh() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::cosh); + } + Derived ceil() const { + // This function is questionable with a conversion, so we use map + return map(at::native::ceil_impl); + } + Derived floor() const { + // This function is questionable with a conversion, so we use map + return map(at::native::floor_impl); + } + Derived round() const { + // This function is questionable with a conversion, so we use map + return map(at::native::round_impl); + } + Derived tan() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::tan); + } + Derived tanh() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::tanh); + } + Derived lgamma() const { + return static_cast(this)->map_with_vec_float_method(&Vectorized::lgamma); + } + Derived rsqrt() const { + return static_cast(this)->sqrt().reciprocal(); + } + Derived pow(const Derived& exp) const { + return static_cast(this)->map2_with_vec_float_method(exp, &Vectorized::pow); + } + +}; + + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/missing_vld1_neon.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/missing_vld1_neon.h new file mode 100644 index 0000000000000000000000000000000000000000..5540c8bc782faedbadb0794142580bad1207afc0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/missing_vld1_neon.h @@ -0,0 +1,452 @@ +/* Workaround for missing vld1_*_x2 and vst1_*_x2 intrinsics in gcc-7. */ + +__extension__ extern __inline uint8x8x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_u8_x2 (const uint8_t *__a) +{ + uint8x8x2_t ret; + asm volatile("ld1 {%S0.8b - %T0.8b}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline int8x8x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_s8_x2 (const int8_t *__a) +{ + int8x8x2_t ret; + asm volatile("ld1 {%S0.8b - %T0.8b}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline uint16x4x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_u16_x2 (const uint16_t *__a) +{ + uint16x4x2_t ret; + asm volatile("ld1 {%S0.4h - %T0.4h}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline int16x4x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_s16_x2 (const int16_t *__a) +{ + int16x4x2_t ret; + asm volatile("ld1 {%S0.4h - %T0.4h}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline uint32x2x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_u32_x2 (const uint32_t *__a) +{ + uint32x2x2_t ret; + asm volatile("ld1 {%S0.2s - %T0.2s}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline int32x2x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_s32_x2 (const int32_t *__a) +{ + int32x2x2_t ret; + asm volatile("ld1 {%S0.2s - %T0.2s}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline uint64x1x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_u64_x2 (const uint64_t *__a) +{ + uint64x1x2_t ret; + asm volatile("ld1 {%S0.1d - %T0.1d}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline int64x1x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_s64_x2 (const int64_t *__a) +{ + int64x1x2_t ret; + __builtin_aarch64_simd_oi __o; + asm volatile("ld1 {%S0.1d - %T0.1d}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline float16x4x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_f16_x2 (const float16_t *__a) +{ + float16x4x2_t ret; + asm volatile("ld1 {%S0.4h - %T0.4h}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline float32x2x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_f32_x2 (const float32_t *__a) +{ + float32x2x2_t ret; + asm volatile("ld1 {%S0.2s - %T0.2s}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline float64x1x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_f64_x2 (const float64_t *__a) +{ + float64x1x2_t ret; + asm volatile("ld1 {%S0.1d - %T0.1d}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline poly8x8x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_p8_x2 (const poly8_t *__a) +{ + poly8x8x2_t ret; + asm volatile("ld1 {%S0.8b - %T0.8b}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline poly16x4x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_p16_x2 (const poly16_t *__a) +{ + poly16x4x2_t ret; + asm volatile("ld1 {%S0.4h - %T0.4h}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline poly64x1x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1_p64_x2 (const poly64_t *__a) +{ + poly64x1x2_t ret; + asm volatile("ld1 {%S0.1d - %T0.1d}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline uint8x16x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_u8_x2 (const uint8_t *__a) +{ + uint8x16x2_t ret; + asm volatile("ld1 {%S0.16b - %T0.16b}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline int8x16x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_s8_x2 (const int8_t *__a) +{ + int8x16x2_t ret; + asm volatile("ld1 {%S0.16b - %T0.16b}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline uint16x8x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_u16_x2 (const uint16_t *__a) +{ + uint16x8x2_t ret; + asm volatile("ld1 {%S0.8h - %T0.8h}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline int16x8x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_s16_x2 (const int16_t *__a) +{ + int16x8x2_t ret; + asm volatile("ld1 {%S0.8h - %T0.8h}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline uint32x4x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_u32_x2 (const uint32_t *__a) +{ + uint32x4x2_t ret; + asm volatile("ld1 {%S0.4s - %T0.4s}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline int32x4x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_s32_x2 (const int32_t *__a) +{ + int32x4x2_t ret; + asm volatile("ld1 {%S0.4s - %T0.4s}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline uint64x2x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_u64_x2 (const uint64_t *__a) +{ + uint64x2x2_t ret; + asm volatile("ld1 {%S0.2d - %T0.2d}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline int64x2x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_s64_x2 (const int64_t *__a) +{ + int64x2x2_t ret; + asm volatile("ld1 {%S0.2d - %T0.2d}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline float16x8x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_f16_x2 (const float16_t *__a) +{ + float16x8x2_t ret; + asm volatile("ld1 {%S0.8h - %T0.8h}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline float32x4x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_f32_x2 (const float32_t *__a) +{ + float32x4x2_t ret; + asm volatile("ld1 {%S0.4s - %T0.4s}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline float64x2x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_f64_x2 (const float64_t *__a) +{ + float64x2x2_t ret; + asm volatile("ld1 {%S0.2d - %T0.2d}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline poly8x16x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_p8_x2 (const poly8_t *__a) +{ + poly8x16x2_t ret; + asm volatile("ld1 {%S0.16b - %T0.16b}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline poly16x8x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_p16_x2 (const poly16_t *__a) +{ + poly16x8x2_t ret; + asm volatile("ld1 {%S0.8h - %T0.8h}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +__extension__ extern __inline poly64x2x2_t +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vld1q_p64_x2 (const poly64_t *__a) +{ + poly64x2x2_t ret; + asm volatile("ld1 {%S0.2d - %T0.2d}, %1" : "=w" (ret) : "Q"(*__a)); + return ret; +} + +/* vst1x2 */ + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_s64_x2 (int64_t * __a, int64x1x2_t val) +{ + asm volatile("st1 {%S1.1d - %T1.1d}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_u64_x2 (uint64_t * __a, uint64x1x2_t val) +{ + asm volatile("st1 {%S1.1d - %T1.1d}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_f64_x2 (float64_t * __a, float64x1x2_t val) +{ + asm volatile("st1 {%S1.1d - %T1.1d}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_s8_x2 (int8_t * __a, int8x8x2_t val) +{ + asm volatile("st1 {%S1.8b - %T1.8b}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_p8_x2 (poly8_t * __a, poly8x8x2_t val) +{ + asm volatile("st1 {%S1.8b - %T1.8b}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_s16_x2 (int16_t * __a, int16x4x2_t val) +{ + asm volatile("st1 {%S1.4h - %T1.4h}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_p16_x2 (poly16_t * __a, poly16x4x2_t val) +{ + asm volatile("st1 {%S1.4h - %T1.4h}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_s32_x2 (int32_t * __a, int32x2x2_t val) +{ + asm volatile("st1 {%S1.2s - %T1.2s}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_u8_x2 (uint8_t * __a, uint8x8x2_t val) +{ + asm volatile("st1 {%S1.8b - %T1.8b}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_u16_x2 (uint16_t * __a, uint16x4x2_t val) +{ + asm volatile("st1 {%S1.4h - %T1.4h}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_u32_x2 (uint32_t * __a, uint32x2x2_t val) +{ + asm volatile("st1 {%S1.2s - %T1.2s}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_f16_x2 (float16_t * __a, float16x4x2_t val) +{ + asm volatile("st1 {%S1.4h - %T1.4h}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_f32_x2 (float32_t * __a, float32x2x2_t val) +{ + asm volatile("st1 {%S1.2s - %T1.2s}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1_p64_x2 (poly64_t * __a, poly64x1x2_t val) +{ + asm volatile("st1 {%S1.1d - %T1.1d}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_s8_x2 (int8_t * __a, int8x16x2_t val) +{ + asm volatile("st1 {%S1.16b - %T1.16b}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_p8_x2 (poly8_t * __a, poly8x16x2_t val) +{ + asm volatile("st1 {%S1.16b - %T1.16b}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_s16_x2 (int16_t * __a, int16x8x2_t val) +{ + asm volatile("st1 {%S1.8h - %T1.8h}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_p16_x2 (poly16_t * __a, poly16x8x2_t val) +{ + asm volatile("st1 {%S1.8h - %T1.8h}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_s32_x2 (int32_t * __a, int32x4x2_t val) +{ + asm volatile("st1 {%S1.4s - %T1.4s}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_s64_x2 (int64_t * __a, int64x2x2_t val) +{ + asm volatile("st1 {%S1.2d - %T1.2d}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_u8_x2 (uint8_t * __a, uint8x16x2_t val) +{ + asm volatile("st1 {%S1.16b - %T1.16b}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_u16_x2 (uint16_t * __a, uint16x8x2_t val) +{ + asm volatile("st1 {%S1.8h - %T1.8h}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_u32_x2 (uint32_t * __a, uint32x4x2_t val) +{ + asm volatile("st1 {%S1.4s - %T1.4s}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_u64_x2 (uint64_t * __a, uint64x2x2_t val) +{ + asm volatile("st1 {%S1.2d - %T1.2d}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_f16_x2 (float16_t * __a, float16x8x2_t val) +{ + asm volatile("st1 {%S1.8h - %T1.8h}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_f32_x2 (float32_t * __a, float32x4x2_t val) +{ + asm volatile("st1 {%S1.4s - %T1.4s}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_f64_x2 (float64_t * __a, float64x2x2_t val) +{ + asm volatile("st1 {%S1.2d - %T1.2d}, %0" : "=Q" (*__a) : "w" (val)); +} + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_p64_x2 (poly64_t * __a, poly64x2x2_t val) +{ + asm volatile("st1 {%S1.2d - %T1.2d}, %0" : "=Q" (*__a) : "w" (val)); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/missing_vst1_neon.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/missing_vst1_neon.h new file mode 100644 index 0000000000000000000000000000000000000000..711d16f9b231f0de8ef7950de809337027b1b2ee --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/missing_vst1_neon.h @@ -0,0 +1,8 @@ +/* Workaround for missing vst1q_f32_x2 in gcc-8. */ + +__extension__ extern __inline void +__attribute__ ((__always_inline__, __gnu_inline__, __artificial__)) +vst1q_f32_x2 (float32_t * __a, float32x4x2_t val) +{ + asm volatile("st1 {%S1.4s - %T1.4s}, %0" : "=Q" (*__a) : "w" (val)); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256.h new file mode 100644 index 0000000000000000000000000000000000000000..83bb70bdbcbfd9234c60c9b6c439d59219b94178 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256.h @@ -0,0 +1,333 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include + +#include +#if !(defined(__VSX__) || defined(CPU_CAPABILITY_VSX) || defined(CPU_CAPABILITY_ZVECTOR)) +#if defined(CPU_CAPABILITY_SVE256) +#include +#endif +#include +#include +#include +#include +#include +#include +#include +#include +#elif defined(__VSX__) || defined(CPU_CAPABILITY_VSX) +#include +#else +#include +#include +#include +#endif + +#include +#include + +#include +#include +#include +#include +#include + +namespace at::vec { + +// Note [CPU_CAPABILITY namespace] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// This header, and all of its subheaders, will be compiled with +// different architecture flags for each supported set of vector +// intrinsics. So we need to make sure they aren't inadvertently +// linked together. We do this by declaring objects in an `inline +// namespace` which changes the name mangling, but can still be +// accessed as `at::vec`. +inline namespace CPU_CAPABILITY { + +inline std::ostream& operator<<(std::ostream& stream, const c10::qint32& val) { + stream << val.val_; + return stream; +} +inline std::ostream& operator<<(std::ostream& stream, const c10::qint8& val) { + stream << static_cast(val.val_); + return stream; +} +inline std::ostream& operator<<(std::ostream& stream, const c10::quint8& val) { + stream << static_cast(val.val_); + return stream; +} + +template +std::ostream& operator<<(std::ostream& stream, const Vectorized& vec) { + T buf[Vectorized::size()]; + vec.store(buf); + stream << "vec["; + for (int i = 0; i != Vectorized::size(); i++) { + if (i != 0) { + stream << ", "; + } + stream << buf[i]; + } + stream << "]"; + return stream; +} + + +#if defined(CPU_CAPABILITY_AVX2) + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ CAST (AVX2) ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template<> +inline Vectorized cast(const Vectorized& src) { + return _mm256_castpd_ps(src); +} + +template<> +inline Vectorized cast(const Vectorized& src) { + return _mm256_castps_pd(src); +} + +template<> +inline Vectorized cast(const Vectorized& src) { + return _mm256_castsi256_ps(src); +} + +template<> +inline Vectorized cast(const Vectorized& src) { + return _mm256_castsi256_pd(src); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ GATHER ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +#ifndef _MSC_VER +// MSVC is not working well on complex function overload. +template +std::enable_if_t> +inline gather(const double* base_addr, const Vectorized& vindex) { + return _mm256_i64gather_pd(base_addr, vindex, scale); +} + +template +std::enable_if_t> +inline gather(const float* base_addr, const Vectorized& vindex) { + return _mm256_i32gather_ps(base_addr, vindex, scale); +} +#endif +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ MASK GATHER ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +#ifndef _MSC_VER +// MSVC is not working well on complex function overload. +template +std::enable_if_t> +inline mask_gather(const Vectorized& src, const double* base_addr, + const Vectorized& vindex, Vectorized& mask) { + return _mm256_mask_i64gather_pd(src, base_addr, vindex, mask, scale); +} + +template +std::enable_if_t> +inline mask_gather(const Vectorized& src, const float* base_addr, + const Vectorized& vindex, Vectorized& mask) { + return _mm256_mask_i32gather_ps(src, base_addr, vindex, mask, scale); +} +#endif +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ CONVERT ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +// Only works for inputs in the range: [-2^51, 2^51] +// From: https://stackoverflow.com/a/41148578 +template<> +Vectorized +inline convert_to_int_of_same_size(const Vectorized &src) { + auto x = _mm256_add_pd(src, _mm256_set1_pd(0x0018000000000000)); + return _mm256_sub_epi64( + _mm256_castpd_si256(x), + _mm256_castpd_si256(_mm256_set1_pd(0x0018000000000000)) + ); +} + +template<> +Vectorized +inline convert_to_int_of_same_size(const Vectorized &src) { + return _mm256_cvttps_epi32(src); +} + +// From: https://stackoverflow.com/a/41148578 +template<> +Vectorized +inline convert_to_fp_of_same_size(const Vectorized &src) { + __m256i magic_i_lo = _mm256_set1_epi64x(0x4330000000000000); /* 2^52 */ + __m256i magic_i_hi32 = _mm256_set1_epi64x(0x4530000080000000); /* 2^84 + 2^63 */ + __m256i magic_i_all = _mm256_set1_epi64x(0x4530000080100000); /* 2^84 + 2^63 + 2^52 */ + __m256d magic_d_all = _mm256_castsi256_pd(magic_i_all); + + __m256i v_lo = _mm256_blend_epi32(magic_i_lo, src, 0b01010101); /* v_low = low32 + 2^52 */ + __m256i v_hi = _mm256_srli_epi64(src, 32); + v_hi = _mm256_xor_si256(v_hi, magic_i_hi32); /* v_hi = high32*2^32 + 2^84 + 2^63 */ + /* int64 = low32 + high32*2^32 = v_hi + v_lo - 2^52 - 2^63 - 2^84 */ + __m256d v_hi_dbl = _mm256_sub_pd(_mm256_castsi256_pd(v_hi), magic_d_all); + __m256d result = _mm256_add_pd(v_hi_dbl, _mm256_castsi256_pd(v_lo)); + return result; +} + +template<> +Vectorized +inline convert_to_fp_of_same_size(const Vectorized &src) { + return _mm256_cvtepi32_ps(src); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ INTERLEAVE ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template <> +std::pair, Vectorized> +inline interleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, a1, a3, a3} + // b = {b0, b1, b2, b3} + + // swap lanes: + // a_swapped = {a0, a1, b0, b1} + // b_swapped = {a2, a3, b2, b3} + auto a_swapped = _mm256_permute2f128_pd(a, b, 0b0100000); // 0, 2. 4 bits apart + auto b_swapped = _mm256_permute2f128_pd(a, b, 0b0110001); // 1, 3. 4 bits apart + + // group cols crossing lanes: + // return {a0, b0, a1, b1} + // {a2, b2, a3, b3} + return std::make_pair(_mm256_permute4x64_pd(a_swapped, 0b11011000), // 0, 2, 1, 3 + _mm256_permute4x64_pd(b_swapped, 0b11011000)); // 0, 2, 1, 3 +} + +template <> +std::pair, Vectorized> +inline interleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, a1, a2, a3, a4, a5, a6, a7} + // b = {b0, b1, b2, b3, b4, b5, b6, b7} + + // swap lanes: + // a_swapped = {a0, a1, a2, a3, b0, b1, b2, b3} + // b_swapped = {a4, a5, a6, a7, b4, b5, b6, b7} + // TODO: can we support caching this? + auto a_swapped = _mm256_permute2f128_ps(a, b, 0b0100000); // 0, 2. 4 bits apart + auto b_swapped = _mm256_permute2f128_ps(a, b, 0b0110001); // 1, 3. 4 bits apart + + // group cols crossing lanes: + // return {a0, b0, a1, b1, a2, b2, a3, b3} + // {a4, b4, a5, b5, a6, b6, a7, b7} + const __m256i group_ctrl = _mm256_setr_epi32(0, 4, 1, 5, 2, 6, 3, 7); + return std::make_pair(_mm256_permutevar8x32_ps(a_swapped, group_ctrl), + _mm256_permutevar8x32_ps(b_swapped, group_ctrl)); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ DEINTERLEAVE ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template <> +std::pair, Vectorized> +inline deinterleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1} + // b = {a2, b2, a3, b3} + + // group cols crossing lanes: + // a_grouped = {a0, a1, b0, b1} + // b_grouped = {a2, a3, b2, b3} + auto a_grouped = _mm256_permute4x64_pd(a, 0b11011000); // 0, 2, 1, 3 + auto b_grouped = _mm256_permute4x64_pd(b, 0b11011000); // 0, 2, 1, 3 + + // swap lanes: + // return {a0, a1, a2, a3} + // {b0, b1, b2, b3} + return std::make_pair(_mm256_permute2f128_pd(a_grouped, b_grouped, 0b0100000), // 0, 2. 4 bits apart + _mm256_permute2f128_pd(a_grouped, b_grouped, 0b0110001)); // 1, 3. 4 bits apart +} + +template <> +std::pair, Vectorized> +inline deinterleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1, a2, b2, a3, b3} + // b = {a4, b4, a5, b5, a6, b6, a7, b7} + + // group cols crossing lanes: + // a_grouped = {a0, a1, a2, a3, b0, b1, b2, b3} + // b_grouped = {a4, a5, a6, a7, b4, b5, b6, b7} + // TODO: can we support caching this? + const __m256i group_ctrl = _mm256_setr_epi32(0, 2, 4, 6, 1, 3, 5, 7); + auto a_grouped = _mm256_permutevar8x32_ps(a, group_ctrl); + auto b_grouped = _mm256_permutevar8x32_ps(b, group_ctrl); + + // swap lanes: + // return {a0, a1, a2, a3, a4, a5, a6, a7} + // {b0, b1, b2, b3, b4, b5, b6, b7} + return std::make_pair(_mm256_permute2f128_ps(a_grouped, b_grouped, 0b0100000), // 0, 2. 4 bits apart + _mm256_permute2f128_ps(a_grouped, b_grouped, 0b0110001)); // 1, 3. 4 bits apart +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ FLIP ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template<> +inline Vectorized flip(const Vectorized & v) { + const __m256i mask_float = _mm256_set_epi32(0, 1, 2, 3, 4, 5, 6, 7); + return _mm256_permutevar8x32_ps(v, mask_float); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + return _mm256_permute4x64_pd(v, 27); // 27 == _MM_SHUFFLE(0, 1, 2, 3) +} + +template<> +inline Vectorized flip(const Vectorized & v) { + return _mm256_permute4x64_epi64(v, 27); // 27 == _MM_SHUFFLE(0, 1, 2, 3) +} + +template<> +inline Vectorized flip(const Vectorized & v) { + const __m256i mask_int32 = _mm256_set_epi32(0, 1, 2, 3, 4, 5, 6, 7); + return _mm256_permutevar8x32_epi32(v, mask_int32); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + const __m256i mask = _mm256_set_epi8( + 1, 0, 3, 2, 5, 4, 7, 6, 9, 8, 11, 10, 13, 12, 15, 14, + 1, 0, 3, 2, 5, 4, 7, 6, 9, 8, 11, 10, 13, 12, 15, 14 + ); + auto reversed = _mm256_shuffle_epi8(v, mask); + return _mm256_permute2x128_si256(reversed, reversed, 1); +} + +inline __m256i flip8(const __m256i & v) { + const __m256i mask_int8 = _mm256_set_epi8( + 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, + 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 + ); + auto reversed = _mm256_shuffle_epi8(v, mask_int8); + return _mm256_permute2x128_si256(reversed, reversed, 1); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + return flip8(v); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + return flip8(v); +} + +inline Vectorized operator&&( + const Vectorized& self, + const Vectorized& other) { + const __m256i* self_ = reinterpret_cast(self.as_bytes()); + const __m256i* other_ = reinterpret_cast(other.as_bytes()); + __m256i out = _mm256_and_si256(*self_, *other_); + Vectorized ret; + std::memcpy(ret, &out, ret.size() * sizeof(bool)); + return ret; +} + +#endif // (defined(CPU_CAPABILITY_AVX2) + +}} // namepsace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_16bit_float.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_16bit_float.h new file mode 100644 index 0000000000000000000000000000000000000000..e661f69b40d7972b378a68d3a3d462f6901520dd --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_16bit_float.h @@ -0,0 +1,737 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +// Used for shared functions and classes for vec256_bfloat16.h and vec256_half.h. +// Any functions/classes that are common between those two files should be defined here. +// Any non-shared functions/classes should be defined in the respective files. + +#include +#include + +#if defined(CPU_CAPABILITY_AVX2) +#define SLEEF_STATIC_LIBS +#include +#endif + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX2) + +#ifndef SLEEF_CONST +#if (defined(__GNUC__) || defined(__CLANG__)) && !defined(__INTEL_COMPILER) +#define SLEEF_CONST const +#else +#define SLEEF_CONST +#endif +#define SLEEF_CONST_OLD SLEEF_CONST +#else +#define SLEEF_CONST_OLD +#endif + + +// bfloat16 conversion +static inline void cvtbf16_fp32(const __m128i& a, __m256& o) { + o = _mm256_castsi256_ps(_mm256_slli_epi32(_mm256_cvtepu16_epi32(a), 16)); +} + +static inline void cvtbf16_fp32(const __m256i& a, __m256& o1, __m256& o2) { + __m128i lo = _mm256_extractf128_si256(a, 0); + __m128i hi = _mm256_extractf128_si256(a, 1); + cvtbf16_fp32(lo, o1); + cvtbf16_fp32(hi, o2); +} + +static inline __m128i cvtfp32_bf16(const __m256& src) { + __m256i value = _mm256_castps_si256(src); + __m256i nan = _mm256_set1_epi32(0xffff); + __m256i mask = _mm256_castps_si256(_mm256_cmp_ps(src, src, _CMP_ORD_Q)); + __m256i ones = _mm256_set1_epi32(0x1); + __m256i vec_bias = _mm256_set1_epi32(0x7fff); + // uint32_t lsb = (input >> 16) & 1; + auto t_value = _mm256_and_si256(_mm256_srli_epi32(value, 16), ones); + // uint32_t rounding_bias = 0x7fff + lsb; + t_value = _mm256_add_epi32(t_value, vec_bias); + // input += rounding_bias; + t_value = _mm256_add_epi32(t_value, value); + // input = input >> 16; + t_value = _mm256_srli_epi32(t_value, 16); + // Check NaN before converting back to bf16 + t_value = _mm256_blendv_epi8(nan, t_value, mask); + t_value = _mm256_packus_epi32(t_value, t_value); // t[4-7] t[4-7] t[0-4] t[0-4] + t_value = _mm256_permute4x64_epi64(t_value, 0xd8); // 11 01 10 00 + return _mm256_castsi256_si128(t_value); +} + +static inline __m256i cvtfp32_bf16(const __m256& a, const __m256& b) { + __m256i lo = _mm256_castps_si256(a); + __m256i hi = _mm256_castps_si256(b); + __m256i nan = _mm256_set1_epi32(0xffff); + __m256i mask_lo = _mm256_castps_si256(_mm256_cmp_ps(a, a, _CMP_ORD_Q)); + __m256i mask_hi = _mm256_castps_si256(_mm256_cmp_ps(b, b, _CMP_ORD_Q)); + __m256i ones = _mm256_set1_epi32(0x1); + __m256i vec_bias = _mm256_set1_epi32(0x7fff); + // uint32_t lsb = (input >> 16) & 1; + auto t_lo = _mm256_and_si256(_mm256_srli_epi32(lo, 16), ones); + auto t_hi = _mm256_and_si256(_mm256_srli_epi32(hi, 16), ones); + // uint32_t rounding_bias = 0x7fff + lsb; + t_lo = _mm256_add_epi32(t_lo, vec_bias); + t_hi = _mm256_add_epi32(t_hi, vec_bias); + // input += rounding_bias; + t_lo = _mm256_add_epi32(t_lo, lo); + t_hi = _mm256_add_epi32(t_hi, hi); + // input = input >> 16; + t_lo = _mm256_srli_epi32(t_lo, 16); + t_hi = _mm256_srli_epi32(t_hi, 16); + // Check NaN before converting back to bf16 + t_lo = _mm256_blendv_epi8(nan, t_lo, mask_lo); + t_hi = _mm256_blendv_epi8(nan, t_hi, mask_hi); + + t_lo = _mm256_packus_epi32(t_lo, t_hi); // t_hi[4-7] t_lo[4-7] t_hi[0-4] t_lo[0-4] + return _mm256_permute4x64_epi64(t_lo, 0xd8); // 11 01 10 00 +} + +static inline __m256i merge_compare_result(const __m256& a, const __m256& b) { + __m256i lo = _mm256_castps_si256(a); + __m256i hi = _mm256_castps_si256(b); + lo = _mm256_srli_epi32(lo, 16); + hi = _mm256_srli_epi32(hi, 16); + auto out = _mm256_packus_epi32(lo, hi); + return _mm256_permute4x64_epi64(out, 0xd8); +} + +// float16 conversion +static inline void cvtfp16_fp32(const __m128i& a, __m256& o) { + o = _mm256_cvtph_ps(a); +} + +static inline void cvtfp16_fp32(const __m256i& a, __m256& o1, __m256& o2) { + __m128i lo = _mm256_extractf128_si256(a, 0); + __m128i hi = _mm256_extractf128_si256(a, 1); + cvtfp16_fp32(lo, o1); + cvtfp16_fp32(hi, o2); +} + +static inline __m128i cvtfp32_fp16(const __m256& src) { + return _mm256_cvtps_ph( + src, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); +} + +static inline __m256i cvtfp32_fp16(const __m256& a, const __m256& b) { + __m128i lo = _mm256_cvtps_ph( + a, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + __m128i hi = _mm256_cvtps_ph( + b, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + return _mm256_insertf128_si256(_mm256_castsi128_si256(lo), hi, 1); +} + +// dtype conversion between float16/bfloat16 and float32 +template , int> = 0> +inline void cvt_to_fp32(const __m128i& a, __m256& o); +template <> inline void cvt_to_fp32(const __m128i& a, __m256& o) { + cvtbf16_fp32(a, o); +} +template <> inline void cvt_to_fp32(const __m128i& a, __m256& o) { + cvtfp16_fp32(a, o); +} + +template , int> = 0> +inline void cvt_to_fp32(const __m256i& a, __m256& o1, __m256& o2); +template <> inline void cvt_to_fp32(const __m256i& a, __m256& o1, __m256& o2) { + cvtbf16_fp32(a, o1, o2); +} +template <> inline void cvt_to_fp32(const __m256i& a, __m256& o1, __m256& o2) { + cvtfp16_fp32(a, o1, o2); +} + +template , int> = 0> +inline __m256i cvt_from_fp32(const __m256& a, const __m256& b); +template <> inline __m256i cvt_from_fp32(const __m256& a, const __m256& b) { + return cvtfp32_bf16(a, b); +} +template <> inline __m256i cvt_from_fp32(const __m256& a, const __m256& b) { + return merge_compare_result(a, b); +} +template <> inline __m256i cvt_from_fp32(const __m256& a, const __m256& b) { + return cvtfp32_fp16(a, b); +} +template <> inline __m256i cvt_from_fp32(const __m256& a, const __m256& b) { + return cvtfp32_fp16(a, b); +} + +template +class Vectorized16 { +static_assert( + is_reduced_floating_point_v, + "Support only float16 and bfloat16."); +protected: + __m256i values; +public: + using value_type = uint16_t; + using size_type = int; + static constexpr size_type size() { + return 16; + } + Vectorized16() {} + Vectorized16(__m256i v) : values(v) {} + Vectorized16(T val) { + value_type uw = val.x; + values = _mm256_set1_epi16(uw); + } + Vectorized16(T val1, T val2, T val3, T val4, + T val5, T val6, T val7, T val8, + T val9, T val10, T val11, T val12, + T val13, T val14, T val15, T val16) { + values = _mm256_setr_epi16( + val1.x, val2.x, val3.x, val4.x, val5.x, val6.x, val7.x, val8.x, + val9.x, val10.x, val11.x, val12.x, val13.x, val14.x, val15.x, val16.x); + } + operator __m256i() const { + return values; + } + T& operator[](int idx) = delete; + const T& operator[](int idx) const = delete; + int zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit and others are translated to 0-bit + __m256i cmp = _mm256_cmpeq_epi16(values, _mm256_set1_epi16(0)); + return _mm256_movemask_epi8(cmp); + } + static Vectorized loadu(const void* ptr, int16_t count = size()) { + if (count == size()) + return _mm256_loadu_si256(reinterpret_cast(ptr)); + + __at_align__ int16_t tmp_values[size()]; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (const auto i : c10::irange(count, size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, ptr, count * sizeof(int16_t)); + return _mm256_loadu_si256(reinterpret_cast(tmp_values)); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + _mm256_storeu_si256(reinterpret_cast<__m256i*>(ptr), values); + } else if (count > 0) { + __at_align__ int16_t tmp_values[size()]; + _mm256_storeu_si256(reinterpret_cast<__m256i*>(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(int16_t)); + } + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + __at_align__ int16_t tmp_values[size()]; + a.store(tmp_values); + if (mask & 0x01) + tmp_values[0] = _mm256_extract_epi16(b.values, 0); + if (mask & 0x02) + tmp_values[1] = _mm256_extract_epi16(b.values, 1); + if (mask & 0x04) + tmp_values[2] = _mm256_extract_epi16(b.values, 2); + if (mask & 0x08) + tmp_values[3] = _mm256_extract_epi16(b.values, 3); + if (mask & 0x10) + tmp_values[4] = _mm256_extract_epi16(b.values, 4); + if (mask & 0x20) + tmp_values[5] = _mm256_extract_epi16(b.values, 5); + if (mask & 0x40) + tmp_values[6] = _mm256_extract_epi16(b.values, 6); + if (mask & 0x80) + tmp_values[7] = _mm256_extract_epi16(b.values, 7); + if (mask & 0x100) + tmp_values[8] = _mm256_extract_epi16(b.values, 8); + if (mask & 0x200) + tmp_values[9] = _mm256_extract_epi16(b.values, 9); + if (mask & 0x400) + tmp_values[10] = _mm256_extract_epi16(b.values, 10); + if (mask & 0x800) + tmp_values[11] = _mm256_extract_epi16(b.values, 11); + if (mask & 0x1000) + tmp_values[12] = _mm256_extract_epi16(b.values, 12); + if (mask & 0x2000) + tmp_values[13] = _mm256_extract_epi16(b.values, 13); + if (mask & 0x4000) + tmp_values[14] = _mm256_extract_epi16(b.values, 14); + if (mask & 0x8000) + tmp_values[15] = _mm256_extract_epi16(b.values, 15); + return loadu(tmp_values); + } + static Vectorized blendv(const Vectorized& a, + const Vectorized& b, const Vectorized& mask) { + return _mm256_blendv_epi8(a.values, b.values, mask.values); + } + template + static Vectorized arange(T base = 0.f, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step, + base + 8 * step, base + 9 * step, base + 10 * step, base + 11 * step, + base + 12 * step, base + 13 * step, base + 14 * step, base + 15 * step); + } + static Vectorized set(const Vectorized& a, + const Vectorized& b, int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + case 8: + return blend<255>(a, b); + case 9: + return blend<511>(a, b); + case 10: + return blend<1023>(a, b); + case 11: + return blend<2047>(a, b); + case 12: + return blend<4095>(a, b); + case 13: + return blend<8191>(a, b); + case 14: + return blend<16383>(a, b); + case 15: + return blend<32767>(a, b); + } + return b; + } + +// 'const' type qualifier on return type has no effect, but sleef defines this this way +// For example `Sleef_exp2f8_u10` signature is `const __m256 (__m256)` +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Wignored-qualifiers") + Vectorized map(SLEEF_CONST __m256 (*SLEEF_CONST_OLD vop)(__m256)) const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + const auto o1 = vop(lo); + const auto o2 = vop(hi); + return cvt_from_fp32(o1, o2); + } +C10_DIAGNOSTIC_POP() + Vectorized isnan() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + lo = _mm256_cmp_ps(lo, _mm256_set1_ps(0.0f), _CMP_UNORD_Q); + hi = _mm256_cmp_ps(hi, _mm256_set1_ps(0.0f), _CMP_UNORD_Q); + return merge_compare_result(lo, hi); + } + Vectorized abs() const { + return _mm256_andnot_si256(_mm256_set1_epi16(0x8000), values); + } + Vectorized angle() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + auto angle_lambda = [](__m256 values_2) { + const auto zero_vec = _mm256_set1_ps(0.f); + const auto nan_vec = _mm256_set1_ps(NAN); + const auto not_nan_mask = _mm256_cmp_ps(values_2, values_2, _CMP_EQ_OQ); + const auto nan_mask = _mm256_cmp_ps(not_nan_mask, zero_vec, _CMP_EQ_OQ); + const auto pi = _mm256_set1_ps(c10::pi); + + const auto neg_mask = _mm256_cmp_ps(values_2, zero_vec, _CMP_LT_OQ); + auto angle = _mm256_blendv_ps(zero_vec, pi, neg_mask); + angle = _mm256_blendv_ps(angle, nan_vec, nan_mask); + return angle; + }; + auto o1 = angle_lambda(lo); + auto o2 = angle_lambda(hi); + return cvt_from_fp32(o1, o2); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm256_set1_epi16(0); + } + Vectorized conj() const { + return *this; + } + Vectorized acos() const { + return map(Sleef_acosf8_u10); + } + Vectorized acosh() const { + return map(Sleef_acoshf8_u10); + } + Vectorized asin() const { + return map(Sleef_asinf8_u10); + } + Vectorized atan() const { + return map(Sleef_atanf8_u10); + } + Vectorized atanh() const { + return map(Sleef_atanhf8_u10); + } + Vectorized atan2(const Vectorized &b) const { + __m256 lo, hi; + __m256 b1, b2; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(b.values, b1, b2); + auto o1 = Sleef_atan2f8_u10(lo, b1); + auto o2 = Sleef_atan2f8_u10(hi, b2); + return cvt_from_fp32(o1, o2); + } + Vectorized copysign(const Vectorized &sign) const { + // copy sign bit (0x8000) from sign and remaining bits from values + __m256i mask_value = _mm256_set1_epi32(~0x80008000); + __m256i mask_signbit = _mm256_set1_epi32(0x80008000); + return Vectorized( + _mm256_or_si256( + _mm256_and_si256(values, mask_value), + _mm256_and_si256(sign, mask_signbit))); + } + Vectorized erf() const { + return map(Sleef_erff8_u10); + } + Vectorized erfc() const { + return map(Sleef_erfcf8_u15); + } + Vectorized erfinv() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + __at_align__ float tmp1[size() / 2], tmp2[size() / 2]; + _mm256_storeu_ps(reinterpret_cast(tmp1), lo); + _mm256_storeu_ps(reinterpret_cast(tmp2), hi); + for (int64_t i = 0; i < size() / 2; i++) { + tmp1[i] = calc_erfinv(tmp1[i]); + tmp2[i] = calc_erfinv(tmp2[i]); + } + auto o1 = _mm256_loadu_ps(tmp1); + auto o2 = _mm256_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized exp() const { + return map(Sleef_expf8_u10); + } + Vectorized exp2() const { + return map(Sleef_exp2f8_u10); + } + Vectorized expm1() const { + return map(Sleef_expm1f8_u10); + } + Vectorized exp_u20() const { + return exp(); + } + Vectorized fmod(const Vectorized & q) const { + __m256 x_lo, x_hi; + cvt_to_fp32(values, x_lo, x_hi); + __m256 q_lo, q_hi; + cvt_to_fp32(q.values, q_lo, q_hi); + auto o1 = Sleef_fmodf8(x_lo, q_lo); + auto o2 = Sleef_fmodf8(x_hi, q_hi); + return cvt_from_fp32(o1, o2); + } + Vectorized hypot(const Vectorized &b) const { + __m256 lo, hi; + __m256 b1, b2; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(b.values, b1, b2); + auto o1 = Sleef_hypotf8_u05(lo, b1); + auto o2 = Sleef_hypotf8_u05(hi, b2); + return cvt_from_fp32(o1, o2); + } + Vectorized i0() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + __at_align__ float tmp1[size() / 2], tmp2[size() / 2]; + _mm256_storeu_ps(reinterpret_cast(tmp1), lo); + _mm256_storeu_ps(reinterpret_cast(tmp2), hi); + for (int64_t i = 0; i < size() / 2; i++) { + tmp1[i] = calc_i0(tmp1[i]); + tmp2[i] = calc_i0(tmp2[i]); + } + auto o1 = _mm256_loadu_ps(tmp1); + auto o2 = _mm256_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized i0e() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + constexpr auto sz = size(); + __at_align__ float tmp1[sz / 2], tmp2[sz / 2]; + _mm256_storeu_ps(reinterpret_cast(tmp1), lo); + _mm256_storeu_ps(reinterpret_cast(tmp2), hi); + + for (auto i = decltype(sz){0}; i < sz / 2; i++) { + tmp1[i] = calc_i0e(tmp1[i]); + tmp2[i] = calc_i0e(tmp2[i]); + } + const auto o1 = _mm256_loadu_ps(tmp1); + const auto o2 = _mm256_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized digamma() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + constexpr auto sz = size(); + __at_align__ float tmp1[sz / 2], tmp2[sz / 2]; + _mm256_storeu_ps(reinterpret_cast(tmp1), lo); + _mm256_storeu_ps(reinterpret_cast(tmp2), hi); + + for (auto i = decltype(sz){0}; i < sz / 2; i++) { + tmp1[i] = calc_digamma(tmp1[i]); + tmp2[i] = calc_digamma(tmp2[i]); + } + const auto o1 = _mm256_loadu_ps(tmp1); + const auto o2 = _mm256_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized igamma(const Vectorized &x) const { + __m256 lo, hi; + __m256 xlo, xhi; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(x.values, xlo, xhi); + __at_align__ float tmp1[size() / 2], tmp2[size() / 2]; + _mm256_storeu_ps(reinterpret_cast(tmp1), lo); + _mm256_storeu_ps(reinterpret_cast(tmp2), hi); + __at_align__ float tmpx1[size() / 2], tmpx2[size() / 2]; + _mm256_storeu_ps(reinterpret_cast(tmpx1), xlo); + _mm256_storeu_ps(reinterpret_cast(tmpx2), xhi); + for (int64_t i = 0; i < size() / 2; ++i) { + tmp1[i] = calc_igamma(tmp1[i], tmpx1[i]); + tmp2[i] = calc_igamma(tmp2[i], tmpx2[i]); + } + auto o1 = _mm256_loadu_ps(tmp1); + auto o2 = _mm256_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + + Vectorized igammac(const Vectorized &x) const { + __m256 lo, hi; + __m256 xlo, xhi; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(x.values, xlo, xhi); + __at_align__ float tmp1[size() / 2], tmp2[size() / 2]; + _mm256_storeu_ps(reinterpret_cast(tmp1), lo); + _mm256_storeu_ps(reinterpret_cast(tmp2), hi); + __at_align__ float tmpx1[size() / 2], tmpx2[size() / 2]; + _mm256_storeu_ps(reinterpret_cast(tmpx1), xlo); + _mm256_storeu_ps(reinterpret_cast(tmpx2), xhi); + for (int64_t i = 0; i < size() / 2; ++i) { + tmp1[i] = calc_igammac(tmp1[i], tmpx1[i]); + tmp2[i] = calc_igammac(tmp2[i], tmpx2[i]); + } + auto o1 = _mm256_loadu_ps(tmp1); + auto o2 = _mm256_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized log() const { + return map(Sleef_logf8_u10); + } + Vectorized log2() const { + return map(Sleef_log2f8_u10); + } + Vectorized log10() const { + return map(Sleef_log10f8_u10); + } + Vectorized log1p() const { + return map(Sleef_log1pf8_u10); + } + Vectorized sin() const { + return map(Sleef_sinf8_u10); + } + Vectorized sinh() const { + return map(Sleef_sinhf8_u10); + } + Vectorized cos() const { + return map(Sleef_cosf8_u10); + } + Vectorized cosh() const { + return map(Sleef_coshf8_u10); + } + Vectorized ceil() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm256_ceil_ps(lo); + auto o2 = _mm256_ceil_ps(hi); + return cvt_from_fp32(o1, o2); + } + Vectorized floor() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm256_floor_ps(lo); + auto o2 = _mm256_floor_ps(hi); + return cvt_from_fp32(o1, o2); + } + Vectorized neg() const { + return _mm256_xor_si256(values, _mm256_set1_epi16(0x8000)); + } + Vectorized round() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm256_round_ps(lo, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + auto o2 = _mm256_round_ps(hi, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + return cvt_from_fp32(o1, o2); + } + Vectorized tan() const { + return map(Sleef_tanf8_u10); + } + Vectorized tanh() const { + return map(Sleef_tanhf8_u10); + } + Vectorized trunc() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm256_round_ps(lo, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + auto o2 = _mm256_round_ps(hi, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + return cvt_from_fp32(o1, o2); + } + Vectorized lgamma() const { + return map(Sleef_lgammaf8_u10); + } + Vectorized sqrt() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm256_sqrt_ps(lo); + auto o2 = _mm256_sqrt_ps(hi); + return cvt_from_fp32(o1, o2); + } + Vectorized reciprocal() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + auto ones = _mm256_set1_ps(1); + auto o1 = _mm256_div_ps(ones, lo); + auto o2 = _mm256_div_ps(ones, hi); + return cvt_from_fp32(o1, o2); + } + Vectorized rsqrt() const { + __m256 lo, hi; + cvt_to_fp32(values, lo, hi); + auto ones = _mm256_set1_ps(1); + auto o1 = _mm256_div_ps(ones, _mm256_sqrt_ps(lo)); + auto o2 = _mm256_div_ps(ones, _mm256_sqrt_ps(hi)); + return cvt_from_fp32(o1, o2); + } + Vectorized pow(const Vectorized &b) const { + __m256 lo, hi; + __m256 b1, b2; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(b.values, b1, b2); + auto o1 = Sleef_powf8_u10(lo, b1); + auto o2 = Sleef_powf8_u10(hi, b2); + return cvt_from_fp32(o1, o2); + } +private: + template + Vectorized inline binary_compare(const VectorizedType& b, Op op) const { + __m256 a_lo, a_hi; + __m256 b_lo, b_hi; + cvt_to_fp32(values, a_lo, a_hi); + cvt_to_fp32(b.values, b_lo, b_hi); + auto o1 = op(a_lo, b_lo); + auto o2 = op(a_hi, b_hi); + return cvt_from_fp32(o1, o2); + } + +public: + Vectorized inline operator>(const Vectorized& other) const { + return binary_compare(other, [](__m256 x, __m256 y) { return _mm256_cmp_ps(x, y, _CMP_GT_OQ); }); + } + Vectorized inline operator<(const Vectorized& other) const { + return binary_compare(other, [](__m256 x, __m256 y) { return _mm256_cmp_ps(x, y, _CMP_LT_OQ); }); + } + Vectorized inline operator>=(const Vectorized& other) const { + return binary_compare(other, [](__m256 x, __m256 y) { return _mm256_cmp_ps(x, y, _CMP_GE_OQ); }); + } + Vectorized inline operator<=(const Vectorized& other) const { + return binary_compare(other, [](__m256 x, __m256 y) { return _mm256_cmp_ps(x, y, _CMP_LE_OQ); }); + } + Vectorized inline operator==(const Vectorized16& other) const { + return binary_compare(other, [](__m256 x, __m256 y) { return _mm256_cmp_ps(x, y, _CMP_EQ_OQ); }); + } + Vectorized inline operator!=(const Vectorized16& other) const { + return binary_compare(other, [](__m256 x, __m256 y) { return _mm256_cmp_ps(x, y, _CMP_NEQ_UQ); }); + } +}; + +template +static inline Vectorized binary_op_as_fp32(const Vectorized& a, const Vectorized& b, Op op) { + __m256 a_lo, a_hi; + __m256 b_lo, b_hi; + cvt_to_fp32(__m256i(a), a_lo, a_hi); + cvt_to_fp32(__m256i(b), b_lo, b_hi); + auto o1 = op(a_lo, b_lo); + auto o2 = op(a_hi, b_hi); + return cvt_from_fp32(o1, o2); +} + +#define CONVERT_VECTORIZED_INIT(type, name) \ +inline std::tuple, Vectorized> convert_##name##_float(const Vectorized& a) { \ + __m256 o1, o2; \ + cvt_to_fp32(__m256i(a), o1, o2); \ + return std::make_tuple(o1, o2); \ +} \ +inline Vectorized convert_float_##name(const Vectorized& a, const Vectorized& b) { \ + return cvt_from_fp32(__m256(a), __m256(b)); \ +} + +#define LOAD_FP32_VECTORIZED_INIT(type, name) \ +inline void load_fp32_from_##name(const type *data, Vectorized& out) { \ + auto values = _mm_loadu_si128(reinterpret_cast(data)); \ + __m256 out_values; \ + cvt_to_fp32(values, out_values); \ + out = out_values; \ +} \ +\ +inline void load_fp32_from_##name(const type *data, Vectorized& out1, Vectorized& out2) { \ + auto vec = Vectorized::loadu(data); \ + __m256 out1_values, out2_values; \ + cvt_to_fp32(vec, out1_values, out2_values); \ + out1 = out1_values; \ + out2 = out2_values; \ +} + +#else // CPU_CAPABILITY_AVX2 + +#define CONVERT_NON_VECTORIZED_INIT(type, name) \ +inline std::tuple, Vectorized> convert_##name##_float(const Vectorized& a) { \ + constexpr int64_t K = Vectorized::size(); \ + __at_align__ float arr[K]; \ + __at_align__ type arr2[K]; \ + a.store(arr2); \ + convert(arr2, arr, K); \ + return std::make_tuple( \ + Vectorized::loadu(arr), \ + Vectorized::loadu(arr + Vectorized::size())); \ +} \ +inline Vectorized convert_float_##name(const Vectorized& a, const Vectorized& b) { \ + constexpr int64_t K = Vectorized::size(); \ + __at_align__ float arr[K]; \ + __at_align__ type arr2[K]; \ + a.store(arr); \ + b.store(arr + Vectorized::size()); \ + convert(arr, arr2, K); \ + return Vectorized::loadu(arr2); \ +} + +#define LOAD_FP32_NON_VECTORIZED_INIT(type, name) \ +inline void load_fp32_from_##name(const type *data, Vectorized& out) { \ + __at_align__ float values[Vectorized::size()]; \ + for (const auto k : c10::irange(Vectorized::size())) { \ + values[k] = data[k]; \ + } \ + out = Vectorized::loadu(values); \ +} \ +\ +inline void load_fp32_from_##name(const type *data, Vectorized& out1, Vectorized& out2) { \ + load_fp32_from_##name(data, out1); \ + data += Vectorized::size(); \ + load_fp32_from_##name(data, out2); \ +} + +#endif // CPU_CAPABILITY_AVX2 +}} // namespace::at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_bfloat16.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_bfloat16.h new file mode 100644 index 0000000000000000000000000000000000000000..ac69e8613f714a8ff0770fd0aae724732079acb3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_bfloat16.h @@ -0,0 +1,230 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX2) + +template <> +class Vectorized: public Vectorized16 { +public: + using Vectorized16::Vectorized16; + + using value_type = BFloat16; + + Vectorized frac() const; + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m256& x, const __m256& y) { return _mm256_add_ps(x, y); }); +} +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m256& x, const __m256& y) { return _mm256_sub_ps(x, y); }); +} +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m256& x, const __m256& y) { return _mm256_mul_ps(x, y); }); +} +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m256& x, const __m256& y) { return _mm256_div_ps(x, y); }); +} +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return _mm256_and_si256(a, b); +} +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return _mm256_or_si256(a, b); +} +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return _mm256_xor_si256(a, b); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0f); +} + +// frac. Implement this here so we can use subtraction +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + __m256 a_lo, a_hi; + __m256 b_lo, b_hi; + cvtbf16_fp32(__m256i(a), a_lo, a_hi); + cvtbf16_fp32(__m256i(b), b_lo, b_hi); + auto max_lo = _mm256_max_ps(a_lo, b_lo); + auto max_hi = _mm256_max_ps(a_hi, b_hi); + auto nan_lo = _mm256_cmp_ps(a_lo, b_lo, _CMP_UNORD_Q); + auto nan_hi = _mm256_cmp_ps(a_hi, b_hi, _CMP_UNORD_Q); + // Exploit the fact that all-ones is a NaN. + auto o1 = _mm256_or_ps(max_lo, nan_lo); + auto o2 = _mm256_or_ps(max_hi, nan_hi); + return cvtfp32_bf16(o1, o2); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + __m256 a_lo, a_hi; + __m256 b_lo, b_hi; + cvtbf16_fp32(__m256i(a), a_lo, a_hi); + cvtbf16_fp32(__m256i(b), b_lo, b_hi); + auto min_lo = _mm256_min_ps(a_lo, b_lo); + auto min_hi = _mm256_min_ps(a_hi, b_hi); + auto nan_lo = _mm256_cmp_ps(a_lo, b_lo, _CMP_UNORD_Q); + auto nan_hi = _mm256_cmp_ps(a_hi, b_hi, _CMP_UNORD_Q); + // Exploit the fact that all-ones is a NaN. + auto o1 = _mm256_or_ps(min_lo, nan_lo); + auto o2 = _mm256_or_ps(min_hi, nan_hi); + return cvtfp32_bf16(o1, o2); +} + +template <> +Vectorized inline clamp(const Vectorized& a, + const Vectorized& min, const Vectorized& max) { + __m256 a_lo, a_hi; + __m256 min_lo, min_hi; + __m256 max_lo, max_hi; + cvtbf16_fp32(__m256i(a), a_lo, a_hi); + cvtbf16_fp32(__m256i(min), min_lo, min_hi); + cvtbf16_fp32(__m256i(max), max_lo, max_hi); + auto o1 = _mm256_min_ps(max_lo, _mm256_max_ps(min_lo, a_lo)); + auto o2 = _mm256_min_ps(max_hi, _mm256_max_ps(min_hi, a_hi)); + return cvtfp32_bf16(o1, o2); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + __m256 a_lo, a_hi; + __m256 max_lo, max_hi; + cvtbf16_fp32(__m256i(a), a_lo, a_hi); + cvtbf16_fp32(__m256i(max), max_lo, max_hi); + auto o1 = _mm256_min_ps(max_lo, a_lo); + auto o2 = _mm256_min_ps(max_hi, a_hi); + return cvtfp32_bf16(o1, o2); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + __m256 a_lo, a_hi; + __m256 min_lo, min_hi; + cvtbf16_fp32(__m256i(a), a_lo, a_hi); + cvtbf16_fp32(__m256i(min), min_lo, min_hi); + auto o1 = _mm256_max_ps(min_lo, a_lo); + auto o2 = _mm256_max_ps(min_hi, a_hi); + return cvtfp32_bf16(o1, o2); +} + +template <> +inline void convert(const BFloat16* src, BFloat16* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + auto vsrc = _mm256_loadu_si256(reinterpret_cast<__m256i*>((void*)(src + i))); + _mm256_storeu_si256(reinterpret_cast<__m256i*>((void*)(dst + i)), vsrc); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = src[i]; + } +} + +template <> +inline void convert(const float* src, BFloat16* dst, int64_t n) { + int64_t i; + for (i = 0; i + Vectorized::size() <= n; i += Vectorized::size()) { + __m256 a = _mm256_loadu_ps(&src[i]); + __m256 b = _mm256_loadu_ps(&src[i + 8]); + + __m256i bf = cvtfp32_bf16(a, b); + _mm256_storeu_si256(reinterpret_cast<__m256i*>(&dst[i]), bf); + } + for (; i < n; i++) { + dst[i] = c10::convert(src[i]); + } +} + +template <> +inline void convert(const double* src, BFloat16* dst, int64_t n) { + auto load_float = [](const double *src) -> __m256 { + // Load one float vector from an array of doubles + __m128 a = _mm256_cvtpd_ps(_mm256_loadu_pd(src)); + __m128 b = _mm256_cvtpd_ps(_mm256_loadu_pd(src + 4)); + return _mm256_insertf128_ps(_mm256_castps128_ps256(a), b, 1); + }; + + int64_t i; + for (i = 0; i + Vectorized::size() <= n; i += Vectorized::size()) { + __m256 a = load_float(&src[i]); + __m256 b = load_float(&src[i + 8]); + + __m256i bf = cvtfp32_bf16(a, b); + _mm256_storeu_si256(reinterpret_cast<__m256i*>(&dst[i]), bf); + } + for (; i < n; i++) { + dst[i] = c10::convert(src[i]); + } +} + +template <> +Vectorized inline fmadd(const Vectorized& a, + const Vectorized& b, const Vectorized& c) { + __m256 a_lo, a_hi; + __m256 b_lo, b_hi; + __m256 c_lo, c_hi; + cvtbf16_fp32(__m256i(a), a_lo, a_hi); + cvtbf16_fp32(__m256i(b), b_lo, b_hi); + cvtbf16_fp32(__m256i(c), c_lo, c_hi); + auto o1 = _mm256_fmadd_ps(a_lo, b_lo, c_lo); + auto o2 = _mm256_fmadd_ps(a_hi, b_hi, c_hi); + return cvtfp32_bf16(o1, o2); +} + +CONVERT_VECTORIZED_INIT(BFloat16, bfloat16) +LOAD_FP32_VECTORIZED_INIT(BFloat16, bf16) + +#else // defined(CPU_CAPABILITY_AVX2) + +#if !(defined(__aarch64__) && !defined(C10_MOBILE) && !defined(__CUDACC__) && !defined(CPU_CAPABILITY_SVE256)) +CONVERT_NON_VECTORIZED_INIT(BFloat16, bfloat16) +#endif + +LOAD_FP32_NON_VECTORIZED_INIT(BFloat16, bf16) +#endif // defined(CPU_CAPABILITY_AVX2) +}} // namsepace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_complex_double.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_complex_double.h new file mode 100644 index 0000000000000000000000000000000000000000..b4d8776d7ae4faa4ee4b616e73db97e5e451f7ed --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_complex_double.h @@ -0,0 +1,455 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#include + +#if defined(CPU_CAPABILITY_AVX2) +#define SLEEF_STATIC_LIBS +#include +#endif + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX2) + +template <> class Vectorized> { +private: + __m256d values; +public: + using value_type = c10::complex; + using size_type = int; + static constexpr size_type size() { + return 2; + } + Vectorized() {} + Vectorized(__m256d v) : values(v) {} + Vectorized(c10::complex val) { + double real_value = val.real(); + double imag_value = val.imag(); + values = _mm256_setr_pd(real_value, imag_value, + real_value, imag_value); + } + Vectorized(c10::complex val1, c10::complex val2) { + values = _mm256_setr_pd(val1.real(), val1.imag(), + val2.real(), val2.imag()); + } + operator __m256d() const { + return values; + } + template + static Vectorized> blend(const Vectorized>& a, const Vectorized>& b) { + // convert c10::complex index mask to V index mask: xy -> xxyy + static_assert (mask > -1 && mask < 4, "Unexpected mask value"); + switch (mask) { + case 0: + return a; + case 1: + return _mm256_blend_pd(a.values, b.values, 0x03); + case 2: + return _mm256_blend_pd(a.values, b.values, 0x0c); + case 3: break; + } + return b; + } + static Vectorized> blendv(const Vectorized>& a, const Vectorized>& b, + const Vectorized>& mask) { + // convert c10::complex index mask to V index mask: xy -> xxyy + auto mask_ = _mm256_unpacklo_pd(mask.values, mask.values); + return _mm256_blendv_pd(a.values, b.values, mask_); + + } + template + static Vectorized> arange(c10::complex base = 0., step_t step = static_cast(1)) { + return Vectorized>(base, + base + step); + } + static Vectorized> set(const Vectorized>& a, const Vectorized>& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + } + return b; + } + static Vectorized> loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return _mm256_loadu_pd(reinterpret_cast(ptr)); + + __at_align__ double tmp_values[2*size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(2*size())) { + tmp_values[i] = 0.0; + } + std::memcpy( + tmp_values, + reinterpret_cast(ptr), + count * sizeof(c10::complex)); + return _mm256_load_pd(tmp_values); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + _mm256_storeu_pd(reinterpret_cast(ptr), values); + } else if (count > 0) { + double tmp_values[2*size()]; + _mm256_storeu_pd(reinterpret_cast(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(c10::complex)); + } + } + const c10::complex& operator[](int idx) const = delete; + c10::complex& operator[](int idx) = delete; + Vectorized> map(c10::complex (*const f)(const c10::complex &)) const { + __at_align__ c10::complex tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + __m256d abs_2_() const { + auto val_2 = _mm256_mul_pd(values, values); // a*a b*b + return _mm256_hadd_pd(val_2, val_2); // a*a+b*b a*a+b*b + } + __m256d abs_() const { + auto real = _mm256_movedup_pd(values); // real real + // movehdup_pd does not exist... + auto imag = _mm256_permute_pd(values, 0xf); // imag imag + return Sleef_hypotd4_u05(real, imag); // abs abs + } + Vectorized> abs() const { + const __m256d real_mask = _mm256_castsi256_pd(_mm256_setr_epi64x(0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000)); + return _mm256_and_pd(abs_(), real_mask); // abs 0 + } + __m256d angle_() const { + //angle = atan2(b/a) + auto b_a = _mm256_permute_pd(values, 0x05); // b a + return Sleef_atan2d4_u10(values, b_a); // 90-angle angle + } + Vectorized> angle() const { + const __m256d real_mask = _mm256_castsi256_pd(_mm256_setr_epi64x(0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000)); + auto angle = _mm256_permute_pd(angle_(), 0x05); // angle 90-angle + return _mm256_and_pd(angle, real_mask); // angle 0 + } + Vectorized> sgn() const { + auto abs = abs_(); + auto zero = _mm256_setzero_pd(); + auto mask = _mm256_cmp_pd(abs, zero, _CMP_EQ_OQ); + auto div = _mm256_div_pd(values, abs); + return _mm256_blendv_pd(div, zero, mask); + } + __m256d real_() const { + const __m256d real_mask = _mm256_castsi256_pd(_mm256_setr_epi64x(0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000)); + return _mm256_and_pd(values, real_mask); + } + Vectorized> real() const { + return real_(); + } + __m256d imag_() const { + const __m256d imag_mask = _mm256_castsi256_pd(_mm256_setr_epi64x(0x0000000000000000, 0xFFFFFFFFFFFFFFFF, + 0x0000000000000000, 0xFFFFFFFFFFFFFFFF)); + return _mm256_and_pd(values, imag_mask); + } + Vectorized> imag() const { + return _mm256_permute_pd(imag_(), 0x05); //b a + } + __m256d conj_() const { + const __m256d sign_mask = _mm256_setr_pd(0.0, -0.0, 0.0, -0.0); + return _mm256_xor_pd(values, sign_mask); // a -b + } + Vectorized> conj() const { + return conj_(); + } + Vectorized> log() const { + // Most trigonomic ops use the log() op to improve complex number performance. + return map(std::log); + } + Vectorized> log2() const { + const __m256d log2_ = _mm256_set1_pd(std::log(2)); + return _mm256_div_pd(log(), log2_); + } + Vectorized> log10() const { + const __m256d log10_ = _mm256_set1_pd(std::log(10)); + return _mm256_div_pd(log(), log10_); + } + Vectorized> log1p() const { + return map(std::log1p); + } + Vectorized> asin() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // // asin(x) + // // = -i*ln(iz + sqrt(1 -z^2)) + // // = -i*ln((ai - b) + sqrt(1 - (a + bi)*(a + bi))) + // // = -i*ln((-b + ai) + sqrt(1 - (a**2 - b**2) - 2*abi)) + // const __m256d one = _mm256_set1_pd(1); + + // auto conj = conj_(); + // auto b_a = _mm256_permute_pd(conj, 0x05); //-b a + // auto ab = _mm256_mul_pd(conj, b_a); //-ab -ab + // auto im = _mm256_add_pd(ab, ab); //-2ab -2ab + + // auto val_2 = _mm256_mul_pd(values, values); // a*a b*b + // auto re = _mm256_hsub_pd(val_2, _mm256_permute_pd(val_2, 0x05)); // a*a-b*b b*b-a*a + // re = _mm256_sub_pd(one, re); + + // auto root = Vectorized(_mm256_blend_pd(re, im, 0x0A)).sqrt(); //sqrt(re + i*im) + // auto ln = Vectorized(_mm256_add_pd(b_a, root)).log(); //ln(iz + sqrt()) + // return Vectorized(_mm256_permute_pd(ln.values, 0x05)).conj(); //-i*ln() + return map(std::asin); + } + Vectorized> acos() const { + // acos(x) = pi/2 - asin(x) + constexpr auto pi_2d = c10::pi / 2; + const __m256d pi_2 = _mm256_setr_pd(pi_2d, 0.0, pi_2d, 0.0); + return _mm256_sub_pd(pi_2, asin()); + } + Vectorized> atan() const; + Vectorized> atanh() const { + return map(std::atanh); + } + Vectorized> exp() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //exp(a + bi) + // // = exp(a)*(cos(b) + sin(b)i) + // auto exp = Sleef_expd4_u10(values); //exp(a) exp(b) + // exp = _mm256_blend_pd(exp, _mm256_permute_pd(exp, 0x05), 0x0A); //exp(a) exp(a) + + // auto sin_cos = Sleef_sincosd4_u10(values); //[sin(a), cos(a)] [sin(b), cos(b)] + // auto cos_sin = _mm256_blend_pd(_mm256_permute_pd(sin_cos.y, 0x05), + // sin_cos.x, 0x0A); //cos(b) sin(b) + // return _mm256_mul_pd(exp, cos_sin); + return map(std::exp); + } + Vectorized> exp2() const { + // Use identity 2**x = exp(log(2) * x) + const __m256d ln_2 = _mm256_set1_pd(c10::ln_2); + Vectorized> scaled_values = _mm256_mul_pd(values, ln_2); + return scaled_values.exp(); + } + Vectorized> expm1() const { + return map(std::expm1); + } + Vectorized> sin() const { + return map(std::sin); + } + Vectorized> sinh() const { + return map(std::sinh); + } + Vectorized> cos() const { + return map(std::cos); + } + Vectorized> cosh() const { + return map(std::cosh); + } + Vectorized> ceil() const { + return _mm256_ceil_pd(values); + } + Vectorized> floor() const { + return _mm256_floor_pd(values); + } + Vectorized> neg() const { + auto zero = _mm256_setzero_pd(); + return _mm256_sub_pd(zero, values); + } + Vectorized> round() const { + return _mm256_round_pd(values, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + } + Vectorized> tan() const { + return map(std::tan); + } + Vectorized> tanh() const { + return map(std::tanh); + } + Vectorized> trunc() const { + return _mm256_round_pd(values, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + } + Vectorized> sqrt() const { + return map(std::sqrt); + } + Vectorized> reciprocal() const; + Vectorized> rsqrt() const { + return sqrt().reciprocal(); + } + Vectorized> pow(const Vectorized> &exp) const { + __at_align__ c10::complex x_tmp[size()]; + __at_align__ c10::complex y_tmp[size()]; + store(x_tmp); + exp.store(y_tmp); + for (const auto i : c10::irange(size())) { + x_tmp[i] = std::pow(x_tmp[i], y_tmp[i]); + } + return loadu(x_tmp); + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized> operator==(const Vectorized>& other) const { + return _mm256_cmp_pd(values, other.values, _CMP_EQ_OQ); + } + Vectorized> operator!=(const Vectorized>& other) const { + return _mm256_cmp_pd(values, other.values, _CMP_NEQ_UQ); + } + Vectorized> operator<(const Vectorized>&) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator<=(const Vectorized>&) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator>(const Vectorized>&) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator>=(const Vectorized>&) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized> eq(const Vectorized>& other) const; + Vectorized> ne(const Vectorized>& other) const; +}; + +template <> Vectorized> inline operator+(const Vectorized> &a, const Vectorized> &b) { + return _mm256_add_pd(a, b); +} + +template <> Vectorized> inline operator-(const Vectorized> &a, const Vectorized> &b) { + return _mm256_sub_pd(a, b); +} + +template <> Vectorized> inline operator*(const Vectorized> &a, const Vectorized> &b) { + //(a + bi) * (c + di) = (ac - bd) + (ad + bc)i + const __m256d sign_mask = _mm256_setr_pd(0.0, -0.0, 0.0, -0.0); + auto ac_bd = _mm256_mul_pd(a, b); //ac bd + + auto d_c = _mm256_permute_pd(b, 0x05); //d c + d_c = _mm256_xor_pd(sign_mask, d_c); //d -c + auto ad_bc = _mm256_mul_pd(a, d_c); //ad -bc + + auto ret = _mm256_hsub_pd(ac_bd, ad_bc); //ac - bd ad + bc + return ret; +} + +template <> Vectorized> inline operator/(const Vectorized> &a, const Vectorized> &b) { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //re + im*i = (a + bi) / (c + di) + // auto mask = _mm256_set1_pd(-0.f); + // auto fabs_cd = _mm256_andnot_pd(mask, b); // |c| |d| + // auto fabs_dc = _mm256_permute_pd(fabs_cd, 0x05); // |d| |c| + // auto scale = _mm256_div_pd(_mm256_set1_pd(1.0f), _mm256_max_pd(fabs_cd, fabs_dc)); // 1/sc 1/sc + // auto a2 = _mm256_mul_pd(a, scale); // a/sc b/sc + // auto b2 = _mm256_mul_pd(b, scale); // c/sc d/sc + // auto acbd2 = _mm256_mul_pd(a2, b2); + + // const __m256d sign_mask = _mm256_setr_pd(-0.0, 0.0, -0.0, 0.0); + // auto dc2 = _mm256_permute_pd(b2, 0x05); // d/sc c/sc + // dc2 = _mm256_xor_pd(sign_mask, dc2); // -d/|c,d| c/sc + // auto adbc2 = _mm256_mul_pd(a2, dc2); //-ad/sc^2 bc/sc^2 + // auto res2 = _mm256_hadd_pd(acbd2, adbc2); //(ac+bd)/sc^2 (bc-ad)/sc^2 + + // // get the denominator + // auto denom2 = Vectorized>(b2).abs_2_(); // (c^2+d^2)/sc^2 (c^2+d^2)/sc^2 + // res2 = _mm256_div_pd(res2, denom2); + // return res2; + __at_align__ c10::complex tmp1[Vectorized>::size()]; + __at_align__ c10::complex tmp2[Vectorized>::size()]; + __at_align__ c10::complex out[Vectorized>::size()]; + a.store(tmp1); + b.store(tmp2); + for (const auto i : c10::irange(Vectorized>::size())) { + out[i] = tmp1[i] / tmp2[i]; + } + return _mm256_loadu_pd(reinterpret_cast(out)); +} + +// reciprocal. Implement this here so we can use multiplication. +inline Vectorized> Vectorized>::reciprocal() const{ + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //re + im*i = (a + bi) / (c + di) + // //re = (ac + bd)/abs_2() = c/abs_2() + // //im = (bc - ad)/abs_2() = d/abs_2() + // const __m256d sign_mask = _mm256_setr_pd(0.0, -0.0, 0.0, -0.0); + // auto c_d = _mm256_xor_pd(sign_mask, values); //c -d + // return _mm256_div_pd(c_d, abs_2_()); + __at_align__ c10::complex tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = c10::complex(1) / tmp[i]; + } + return loadu(tmp); +} + +inline Vectorized> Vectorized>::atan() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // // atan(x) = i/2 * ln((i + z)/(i - z)) + // const __m256d i = _mm256_setr_pd(0.0, 1.0, 0.0, 1.0); + // const Vectorized i_half = _mm256_setr_pd(0.0, 0.5, 0.0, 0.5); + + // auto sum = Vectorized(_mm256_add_pd(i, values)); // a 1+b + // auto sub = Vectorized(_mm256_sub_pd(i, values)); // -a 1-b + // auto ln = (sum/sub).log(); // ln((i + z)/(i - z)) + // return i_half*ln; // i/2*ln() + return map(std::atan); +} + +template <> +Vectorized> inline maximum(const Vectorized>& a, const Vectorized>& b) { + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + auto mask = _mm256_cmp_pd(abs_a, abs_b, _CMP_LT_OQ); + auto max = _mm256_blendv_pd(a, b, mask); + // Exploit the fact that all-ones is a NaN. + auto isnan = _mm256_cmp_pd(abs_a, abs_b, _CMP_UNORD_Q); + return _mm256_or_pd(max, isnan); +} + +template <> +Vectorized> inline minimum(const Vectorized>& a, const Vectorized>& b) { + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + auto mask = _mm256_cmp_pd(abs_a, abs_b, _CMP_GT_OQ); + auto min = _mm256_blendv_pd(a, b, mask); + // Exploit the fact that all-ones is a NaN. + auto isnan = _mm256_cmp_pd(abs_a, abs_b, _CMP_UNORD_Q); + return _mm256_or_pd(min, isnan); +} + +template <> +Vectorized> inline operator&(const Vectorized>& a, const Vectorized>& b) { + return _mm256_and_pd(a, b); +} + +template <> +Vectorized> inline operator|(const Vectorized>& a, const Vectorized>& b) { + return _mm256_or_pd(a, b); +} + +template <> +Vectorized> inline operator^(const Vectorized>& a, const Vectorized>& b) { + return _mm256_xor_pd(a, b); +} + +inline Vectorized> Vectorized>::eq(const Vectorized>& other) const { + auto eq = (*this == other); // compares real and imag individually + // If both real numbers and imag numbers are equal, then the complex numbers are equal + return (eq.real() & eq.imag()) & Vectorized>(_mm256_set1_pd(1.0)); +} + +inline Vectorized> Vectorized>::ne(const Vectorized>& other) const { + auto ne = (*this != other); // compares real and imag individually + // If either real numbers or imag numbers are not equal, then the complex numbers are not equal + return (ne.real() | ne.imag()) & Vectorized>(_mm256_set1_pd(1.0)); +} + +#endif + +}} // namespace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_complex_float.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_complex_float.h new file mode 100644 index 0000000000000000000000000000000000000000..bec9490c7554ac4ce504ad438326d3a1fbcb2ee4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_complex_float.h @@ -0,0 +1,492 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#include +#if defined(CPU_CAPABILITY_AVX2) +#define SLEEF_STATIC_LIBS +#include +#endif + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX2) + +template <> class Vectorized> { +private: + __m256 values; +public: + using value_type = c10::complex; + using size_type = int; + static constexpr size_type size() { + return 4; + } + Vectorized() {} + Vectorized(__m256 v) : values(v) {} + Vectorized(c10::complex val) { + float real_value = val.real(); + float imag_value = val.imag(); + values = _mm256_setr_ps(real_value, imag_value, + real_value, imag_value, + real_value, imag_value, + real_value, imag_value + ); + } + Vectorized(c10::complex val1, c10::complex val2, c10::complex val3, c10::complex val4) { + values = _mm256_setr_ps(val1.real(), val1.imag(), + val2.real(), val2.imag(), + val3.real(), val3.imag(), + val4.real(), val4.imag() + ); + } + operator __m256() const { + return values; + } + template + static Vectorized> blend(const Vectorized>& a, const Vectorized>& b) { + // convert c10::complex index mask to V index mask: xy -> xxyy + static_assert(mask > -1 && mask < 16, "Unexpected mask range"); + switch (mask) { + case 0: + return a; + case 1: + return _mm256_blend_ps(a.values, b.values, 0x03); //b0000 0001 = b0000 0011 + case 2: + return _mm256_blend_ps(a.values, b.values, 0x0C); //b0000 0010 = b0000 1100 + case 3: + return _mm256_blend_ps(a.values, b.values, 0x0F); //b0000 0011 = b0000 1111 + case 4: + return _mm256_blend_ps(a.values, b.values, 0x30); //b0000 0100 = b0011 0000 + case 5: + return _mm256_blend_ps(a.values, b.values, 0x33); //b0000 0101 = b0011 0011 + case 6: + return _mm256_blend_ps(a.values, b.values, 0x3C); //b0000 0110 = b0011 1100 + case 7: + return _mm256_blend_ps(a.values, b.values, 0x3F); //b0000 0111 = b0011 1111 + case 8: + return _mm256_blend_ps(a.values, b.values, 0xC0); //b0000 1000 = b1100 0000 + case 9: + return _mm256_blend_ps(a.values, b.values, 0xC3); //b0000 1001 = b1100 0011 + case 10: + return _mm256_blend_ps(a.values, b.values, 0xCC); //b0000 1010 = b1100 1100 + case 11: + return _mm256_blend_ps(a.values, b.values, 0xCF); //b0000 1011 = b1100 1111 + case 12: + return _mm256_blend_ps(a.values, b.values, 0xF0); //b0000 1100 = b1111 0000 + case 13: + return _mm256_blend_ps(a.values, b.values, 0xF3); //b0000 1101 = b1111 0011 + case 14: + return _mm256_blend_ps(a.values, b.values, 0xFC); //b0000 1110 = b1111 1100 + default: break; + } + return b; + } + static Vectorized> blendv(const Vectorized>& a, const Vectorized>& b, + const Vectorized>& mask) { + // convert c10::complex index mask to V index mask: xy -> xxyy + auto mask_ = _mm256_unpacklo_ps(mask.values, mask.values); + return _mm256_blendv_ps(a.values, b.values, mask_); + + } + template + static Vectorized> arange(c10::complex base = 0., step_t step = static_cast(1)) { + return Vectorized>(base, + base + step, + base + c10::complex(2)*step, + base + c10::complex(3)*step); + } + static Vectorized> set(const Vectorized>& a, const Vectorized>& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + } + return b; + } + static Vectorized> loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return _mm256_loadu_ps(reinterpret_cast(ptr)); + + __at_align__ float tmp_values[2*size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(2*size())) { + tmp_values[i] = 0.0; + } + std::memcpy( + tmp_values, + reinterpret_cast(ptr), + count * sizeof(c10::complex)); + return _mm256_load_ps(tmp_values); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + _mm256_storeu_ps(reinterpret_cast(ptr), values); + } else if (count > 0) { + float tmp_values[2*size()]; + _mm256_storeu_ps(reinterpret_cast(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(c10::complex)); + } + } + const c10::complex& operator[](int idx) const = delete; + c10::complex& operator[](int idx) = delete; + Vectorized> map(c10::complex (*const f)(const c10::complex &)) const { + __at_align__ c10::complex tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + __m256 abs_2_() const { + auto val_2 = _mm256_mul_ps(values, values); // a*a b*b + auto ret = _mm256_hadd_ps(val_2, val_2); // a*a+b*b a*a+b*b + return _mm256_permute_ps(ret, 0xD8); + } + __m256 abs_() const { + auto real = _mm256_moveldup_ps(values); // real real + auto imag = _mm256_movehdup_ps(values); // imag imag + return Sleef_hypotf8_u05(real, imag); // abs abs + } + Vectorized> abs() const { + const __m256 real_mask = _mm256_castsi256_ps(_mm256_setr_epi32(0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000)); + return _mm256_and_ps(abs_(), real_mask); // abs 0 + } + __m256 angle_() const { + //angle = atan2(b/a) + auto b_a = _mm256_permute_ps(values, 0xB1); // b a + return Sleef_atan2f8_u10(values, b_a); // 90-angle angle + } + Vectorized> angle() const { + const __m256 real_mask = _mm256_castsi256_ps(_mm256_setr_epi32(0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000)); + auto angle = _mm256_permute_ps(angle_(), 0xB1); // angle 90-angle + return _mm256_and_ps(angle, real_mask); // angle 0 + } + Vectorized> sgn() const { + auto abs = abs_(); + auto zero = _mm256_setzero_ps(); + auto mask = _mm256_cmp_ps(abs, zero, _CMP_EQ_OQ); + auto div = _mm256_div_ps(values, abs); + return _mm256_blendv_ps(div, zero, mask); + } + __m256 real_() const { + const __m256 real_mask = _mm256_castsi256_ps(_mm256_setr_epi32(0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000)); + return _mm256_and_ps(values, real_mask); + } + Vectorized> real() const { + return real_(); + } + __m256 imag_() const { + const __m256 imag_mask = _mm256_castsi256_ps(_mm256_setr_epi32(0x00000000, 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, + 0x00000000, 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF)); + return _mm256_and_ps(values, imag_mask); + } + Vectorized> imag() const { + return _mm256_permute_ps(imag_(), 0xB1); //b a + } + __m256 conj_() const { + const __m256 sign_mask = _mm256_setr_ps(0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0); + return _mm256_xor_ps(values, sign_mask); // a -b + } + Vectorized> conj() const { + return conj_(); + } + Vectorized> log() const { + // Most trigonomic ops use the log() op to improve complex number performance. + return map(std::log); + } + Vectorized> log2() const { + const __m256 log2_ = _mm256_set1_ps(std::log(2)); + return _mm256_div_ps(log(), log2_); + } + Vectorized> log10() const { + const __m256 log10_ = _mm256_set1_ps(std::log(10)); + return _mm256_div_ps(log(), log10_); + } + Vectorized> log1p() const { + return map(std::log1p); + } + Vectorized> asin() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // // asin(x) + // // = -i*ln(iz + sqrt(1 -z^2)) + // // = -i*ln((ai - b) + sqrt(1 - (a + bi)*(a + bi))) + // // = -i*ln((-b + ai) + sqrt(1 - (a**2 - b**2) - 2*abi)) + // const __m256 one = _mm256_set1_ps(1); + + // auto conj = conj_(); + // auto b_a = _mm256_permute_ps(conj, 0xB1); //-b a + // auto ab = _mm256_mul_ps(conj, b_a); //-ab -ab + // auto im = _mm256_add_ps(ab, ab); //-2ab -2ab + + // auto val_2 = _mm256_mul_ps(values, values); // a*a b*b + // auto re = _mm256_hsub_ps(val_2, _mm256_permute_ps(val_2, 0xB1)); // a*a-b*b b*b-a*a + // re = _mm256_permute_ps(re, 0xD8); + // re = _mm256_sub_ps(one, re); + + // auto root = Vectorized(_mm256_blend_ps(re, im, 0xAA)).sqrt(); //sqrt(re + i*im) + // auto ln = Vectorized(_mm256_add_ps(b_a, root)).log(); //ln(iz + sqrt()) + // return Vectorized(_mm256_permute_ps(ln.values, 0xB1)).conj(); //-i*ln() + return map(std::asin); + } + Vectorized> acos() const { + return map(std::acos); + } + Vectorized> atan() const; + Vectorized> atanh() const { + return map(std::atanh); + } + Vectorized> exp() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //exp(a + bi) + // // = exp(a)*(cos(b) + sin(b)i) + // auto exp = Sleef_expf8_u10(values); //exp(a) exp(b) + // exp = _mm256_blend_ps(exp, _mm256_permute_ps(exp, 0xB1), 0xAA); //exp(a) exp(a) + + // auto sin_cos = Sleef_sincosf8_u10(values); //[sin(a), cos(a)] [sin(b), cos(b)] + // auto cos_sin = _mm256_blend_ps(_mm256_permute_ps(sin_cos.y, 0xB1), + // sin_cos.x, 0xAA); //cos(b) sin(b) + // return _mm256_mul_ps(exp, cos_sin); + return map(std::exp); + } + Vectorized> exp2() const { + // Use identity 2**x = exp(log(2) * x) + const __m256 ln_2 = _mm256_set1_ps(c10::ln_2); + Vectorized> scaled_values = _mm256_mul_ps(values, ln_2); + return scaled_values.exp(); + } + Vectorized> expm1() const { + return map(std::expm1); + } + Vectorized> sin() const { + return map(std::sin); + } + Vectorized> sinh() const { + return map(std::sinh); + } + Vectorized> cos() const { + return map(std::cos); + } + Vectorized> cosh() const { + return map(std::cosh); + } + Vectorized> ceil() const { + return _mm256_ceil_ps(values); + } + Vectorized> floor() const { + return _mm256_floor_ps(values); + } + Vectorized> neg() const { + auto zero = _mm256_setzero_ps(); + return _mm256_sub_ps(zero, values); + } + Vectorized> round() const { + return _mm256_round_ps(values, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + } + Vectorized> tan() const { + return map(std::tan); + } + Vectorized> tanh() const { + return map(std::tanh); + } + Vectorized> trunc() const { + return _mm256_round_ps(values, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + } + Vectorized> sqrt() const { + return map(std::sqrt); + } + Vectorized> reciprocal() const; + Vectorized> rsqrt() const { + return sqrt().reciprocal(); + } + Vectorized> pow(const Vectorized> &exp) const { + __at_align__ c10::complex x_tmp[size()]; + __at_align__ c10::complex y_tmp[size()]; + store(x_tmp); + exp.store(y_tmp); + for (const auto i : c10::irange(size())) { + x_tmp[i] = std::pow(x_tmp[i], y_tmp[i]); + } + return loadu(x_tmp); + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized> operator==(const Vectorized>& other) const { + return _mm256_cmp_ps(values, other.values, _CMP_EQ_OQ); + } + Vectorized> operator!=(const Vectorized>& other) const { + return _mm256_cmp_ps(values, other.values, _CMP_NEQ_UQ); + } + Vectorized> operator<(const Vectorized>& /*other*/) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator<=(const Vectorized>& /*other*/) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator>(const Vectorized>& /*other*/) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator>=(const Vectorized>& /*other*/) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized> eq(const Vectorized>& other) const; + Vectorized> ne(const Vectorized>& other) const; +}; + +template <> Vectorized> inline operator+(const Vectorized> &a, const Vectorized> &b) { + return _mm256_add_ps(a, b); +} + +template <> Vectorized> inline operator-(const Vectorized> &a, const Vectorized> &b) { + return _mm256_sub_ps(a, b); +} + +template <> Vectorized> inline operator*(const Vectorized> &a, const Vectorized> &b) { + //(a + bi) * (c + di) = (ac - bd) + (ad + bc)i + const __m256 sign_mask = _mm256_setr_ps(0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0); + auto ac_bd = _mm256_mul_ps(a, b); //ac bd + + auto d_c = _mm256_permute_ps(b, 0xB1); //d c + d_c = _mm256_xor_ps(sign_mask, d_c); //d -c + auto ad_bc = _mm256_mul_ps(a, d_c); //ad -bc + + auto ret = _mm256_hsub_ps(ac_bd, ad_bc); //ac - bd ad + bc + ret = _mm256_permute_ps(ret, 0xD8); + return ret; +} + +template <> Vectorized> inline operator/(const Vectorized> &a, const Vectorized> &b) { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //re + im*i = (a + bi) / (c + di) + // auto mask = _mm256_set1_ps(-0.f); + // auto fabs_cd = _mm256_andnot_ps(mask, b); // |c| |d| + // auto fabs_dc = _mm256_permute_ps(fabs_cd, 0xB1); // |d| |c| + // auto scale = _mm256_rcp_ps(_mm256_max_ps(fabs_cd, fabs_dc)); // 1/sc 1/sc + // auto a2 = _mm256_mul_ps(a, scale); // a/sc b/sc + // auto b2 = _mm256_mul_ps(b, scale); // c/sc d/sc + // auto acbd2 = _mm256_mul_ps(a2, b2); + + // const __m256 sign_mask = _mm256_setr_ps(-0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0); + // auto dc2 = _mm256_permute_ps(b2, 0xB1); // d/sc c/sc + // dc2 = _mm256_xor_ps(sign_mask, dc2); // -d/|c,d| c/sc + // auto adbc2 = _mm256_mul_ps(a2, dc2); //-ad/sc^2 bc/sc^2 + // auto res2 = _mm256_hadd_ps(acbd2, adbc2); //(ac+bd)/sc^2 (bc-ad)/sc^2 + // res2 = _mm256_permute_ps(res2, 0xD8); + + // // get the denominator + // auto denom2 = Vectorized>(b2).abs_2_(); // (c^2+d^2)/sc^2 (c^2+d^2)/sc^2 + // res2 = _mm256_div_ps(res2, denom2); + // return res2; + __at_align__ c10::complex tmp1[Vectorized>::size()]; + __at_align__ c10::complex tmp2[Vectorized>::size()]; + __at_align__ c10::complex out[Vectorized>::size()]; + a.store(tmp1); + b.store(tmp2); + for (const auto i : c10::irange(Vectorized>::size())) { + out[i] = tmp1[i] / tmp2[i]; + } + return _mm256_loadu_ps(reinterpret_cast(out)); +} + +// reciprocal. Implement this here so we can use multiplication. +inline Vectorized> Vectorized>::reciprocal() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //re + im*i = (a + bi) / (c + di) + // //re = (ac + bd)/abs_2() = c/abs_2() + // //im = (bc - ad)/abs_2() = d/abs_2() + // const __m256 sign_mask = _mm256_setr_ps(0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0); + // auto c_d = _mm256_xor_ps(sign_mask, values); //c -d + // return _mm256_div_ps(c_d, abs_2_()); + __at_align__ c10::complex tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = c10::complex(1) / tmp[i]; + } + return loadu(tmp); +} + +inline Vectorized> Vectorized>::atan() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // // atan(x) = i/2 * ln((i + z)/(i - z)) + // const __m256 i = _mm256_setr_ps(0.0, 1.0, 0.0, 1.0, 0.0, 1.0, 0.0, 1.0); + // const Vectorized i_half = _mm256_setr_ps(0.0, 0.5, 0.0, 0.5, 0.0, 0.5, 0.0, 0.5); + + // auto sum = Vectorized(_mm256_add_ps(i, values)); // a 1+b + // auto sub = Vectorized(_mm256_sub_ps(i, values)); // -a 1-b + // auto ln = (sum/sub).log(); // ln((i + z)/(i - z)) + // return i_half*ln; // i/2*ln() + return map(std::atan); +} + +template <> +Vectorized> inline maximum(const Vectorized>& a, const Vectorized>& b) { + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + auto mask = _mm256_cmp_ps(abs_a, abs_b, _CMP_LT_OQ); + auto max = _mm256_blendv_ps(a, b, mask); + // Exploit the fact that all-ones is a NaN. + auto isnan = _mm256_cmp_ps(abs_a, abs_b, _CMP_UNORD_Q); + return _mm256_or_ps(max, isnan); +} + +template <> +Vectorized> inline minimum(const Vectorized>& a, const Vectorized>& b) { + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + auto mask = _mm256_cmp_ps(abs_a, abs_b, _CMP_GT_OQ); + auto min = _mm256_blendv_ps(a, b, mask); + // Exploit the fact that all-ones is a NaN. + auto isnan = _mm256_cmp_ps(abs_a, abs_b, _CMP_UNORD_Q); + return _mm256_or_ps(min, isnan); +} + +template <> +Vectorized> inline operator&(const Vectorized>& a, const Vectorized>& b) { + return _mm256_and_ps(a, b); +} + +template <> +Vectorized> inline operator|(const Vectorized>& a, const Vectorized>& b) { + return _mm256_or_ps(a, b); +} + +template <> +Vectorized> inline operator^(const Vectorized>& a, const Vectorized>& b) { + return _mm256_xor_ps(a, b); +} + +inline Vectorized> Vectorized>::eq( + const Vectorized>& other) const { + auto eq = (*this == other); // compares real and imag individually + // If both real numbers and imag numbers are equal, then the complex numbers are equal + return (eq.real() & eq.imag()) & Vectorized>(_mm256_set1_ps(1.0f)); +} + +inline Vectorized> Vectorized>::ne( + const Vectorized>& other) const { + auto ne = (*this != other); // compares real and imag individually + // If either real numbers or imag numbers are not equal, then the complex numbers are not equal + return (ne.real() | ne.imag()) & Vectorized>(_mm256_set1_ps(1.0f)); +} + +#endif + +}} // namespace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_convert.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_convert.h new file mode 100644 index 0000000000000000000000000000000000000000..9dbdb4f3dfb2c338b0755e420b67497e261636d1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_convert.h @@ -0,0 +1,328 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX2) && !defined(_MSC_VER) + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + __m256 value; + cvtbf16_fp32(_mm256_castsi256_si128(src[0]), value); + result[0] = value; + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN result; + __m256 value; + cvtfp16_fp32(_mm256_castsi256_si128(src[0]), value); + result[0] = value; + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + result[0] = _mm256_castsi128_si256(cvtfp32_bf16(src[0])); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + result[0] = convert_float_bfloat16(src[0], src[1]); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + std::tie(result[0], result[1]) = convert_bfloat16_float(src[0]); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN result; + result[0] = _mm256_castsi128_si256(cvtfp32_fp16(src[0])); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN result; + result[0] = convert_float_half(src[0], src[1]); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN result; + std::tie(result[0], result[1]) = convert_half_float(src[0]); + return result; + } +}; + +template <> +inline Vectorized convert_to_fp_of_same_size( + const Vectorized& src); + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto low_double = at::vec::convert_to_fp_of_same_size(src[0]); + auto low = _mm256_cvtpd_ps(low_double); + auto high_double = at::vec::convert_to_fp_of_same_size(src[1]); + auto high = _mm256_cvtpd_ps(high_double); + return Vectorized( + _mm256_insertf128_ps(_mm256_castps128_ps256(low), high, 1)); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + // Scalarization is the most reliable way of converting fp to int64 on AVX2. + // Check: https://stackoverflow.com/questions/41144668 + float buffer[8]; + src.store(buffer); + at::vec::VectorizedN result; + result[0] = Vectorized( + static_cast(buffer[0]), + static_cast(buffer[1]), + static_cast(buffer[2]), + static_cast(buffer[3])); + result[1] = Vectorized( + static_cast(buffer[4]), + static_cast(buffer[5]), + static_cast(buffer[6]), + static_cast(buffer[7])); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto low = _mm256_shuffle_epi32(src[0], _MM_SHUFFLE(2, 0, 2, 0)); + auto high = _mm256_shuffle_epi32(src[1], _MM_SHUFFLE(2, 0, 2, 0)); + auto low_perm = _mm256_permute4x64_epi64(low, _MM_SHUFFLE(3, 1, 2, 0)); + auto high_perm = _mm256_permute4x64_epi64(high, _MM_SHUFFLE(3, 1, 2, 0)); + return Vectorized(_mm256_blend_epi32(low_perm, high_perm, 0xF0)); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + at::vec::VectorizedN result; + result[0] = _mm256_cvtepi32_epi64(_mm256_castsi256_si128(src[0])); + result[1] = _mm256_cvtepi32_epi64(_mm256_extracti128_si256(src[0], 1)); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto src128 = _mm256_castsi256_si128(src[0]); + return Vectorized(_mm256_cvtepi8_epi32(src128)); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto src128 = _mm256_castsi256_si128(src[0]); + return Vectorized(_mm256_cvtepu8_epi32(src128)); + } +}; + + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + return Vectorized(_mm256_cvttps_epi32(src[0])); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + return Vectorized(_mm256_cvtepi32_ps(src[0])); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto src128 = _mm256_castsi256_si128(src[0]); + return Vectorized(_mm256_cvtepu8_epi16(src128)); + } +}; + +template +struct VecConvert< + dst_t, + 1, + src_t, + 1, + typename std::enable_if_t< + (is_reduced_floating_point_v && is_8bit_integer_v) || + (is_reduced_floating_point_v && is_8bit_integer_v), + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN tmp_fp32 = VecConvert::apply(src); + return VecConvert::apply(tmp_fp32); + } +}; + +template +struct VecConvert< + dst_t, + 1, + float, + 2, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + at::vec::Vectorized vec1 = convert_float_to_int8(src[0]); + at::vec::Vectorized vec2 = convert_float_to_int8(src[1]); + __m128 lane2 = _mm256_castps256_ps128(_mm256_castsi256_ps(vec2)); + __m256 combined = _mm256_insertf128_ps(_mm256_castsi256_ps(vec1), lane2, 1); + // Shuffle [191:128] bit from combined in to [127:64] bit of result + __m256i result = _mm256_permute4x64_epi64(_mm256_castps_si256(combined), 0b11011000); + return at::vec::Vectorized(result); + } +}; + +template +struct VecConvert< + dst_t, + 1, + float, + 1, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + return convert_float_to_int8(src[0]); + } +}; + +template +struct VecConvert< + float, + 2, + src_t, + 1, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + // Shuffle [127:64] bit from src[0] in to [191:128] bit of shuffled + __m256i shuffled = _mm256_permute4x64_epi64(src[0], 0b11011000); + __m256i src2 = _mm256_castsi128_si256( + _mm_castps_si128( + _mm256_extractf128_ps(_mm256_castsi256_ps(shuffled), 1) // Extract the second 128-bit lane + ) + ); + return VectorizedN(convert_int8_to_float(src[0]), convert_int8_to_float(src2)); + } +}; + +template +struct VecConvert< + dst_t, + 1, + int64_t, + 2, + std::enable_if_t< + std::is_same_v || + std::is_same_v>> { + static inline VectorizedN apply( + const VectorizedN& src) { + return VecConvert::apply( + VecConvert::apply(src)); + } +}; + +#endif /* defined(CPU_CAPABILITY_AVX2) && !defined(_MSC_VER) */ + + +#if (defined(CPU_CAPABILITY_AVX2) && !defined(_MSC_VER)) +template +struct VecConvert< + float, + 1, + src_t, + 1, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + return convert_int8_to_float(src[0]); + } +}; +#endif + +template +struct VecConvert< + float, + 1, + src_t, + 1, + typename std::enable_if_t, void>> { + static inline VectorizedN apply(const VectorizedN& src) { + auto [res_vec1, res_vec2] = convert_to_float(src[0]); + return res_vec1; + } +}; + +template +struct VecConvert< + dst_t, + 1, + float, + 1, + typename std::enable_if_t, void>> { + static inline VectorizedN apply(const VectorizedN& src) { + return convert_from_float(src[0], src[0]); + } +}; + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_double.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_double.h new file mode 100644 index 0000000000000000000000000000000000000000..b4b878859cbb871be29c49a050d350b35b335c77 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_double.h @@ -0,0 +1,450 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#if defined(CPU_CAPABILITY_AVX2) +#define SLEEF_STATIC_LIBS +#include +#endif + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + + +#if defined(CPU_CAPABILITY_AVX2) + +template <> class Vectorized { +private: + __m256d values; +public: + using value_type = double; + using size_type = int; + static constexpr size_type size() { + return 4; + } + Vectorized() {} + Vectorized(__m256d v) : values(v) {} + Vectorized(double val) { + values = _mm256_set1_pd(val); + } + Vectorized(double val1, double val2, double val3, double val4) { + values = _mm256_setr_pd(val1, val2, val3, val4); + } + operator __m256d() const { + return values; + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + return _mm256_blend_pd(a.values, b.values, mask); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + return _mm256_blendv_pd(a.values, b.values, mask.values); + } + template + static Vectorized arange(double base = 0., step_t step = static_cast(1)) { + return Vectorized(base, base + step, base + 2 * step, base + 3 * step); + } + static Vectorized set(const Vectorized& a, const Vectorized& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return _mm256_loadu_pd(reinterpret_cast(ptr)); + + + __at_align__ double tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0.0; + } + std::memcpy( + tmp_values, + reinterpret_cast(ptr), + count * sizeof(double)); + return _mm256_load_pd(tmp_values); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + _mm256_storeu_pd(reinterpret_cast(ptr), values); + } else if (count > 0) { + double tmp_values[size()]; + _mm256_storeu_pd(reinterpret_cast(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(double)); + } + } + const double& operator[](int idx) const = delete; + double& operator[](int idx) = delete; + int zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit and others are translated to 0-bit + __m256d cmp = _mm256_cmp_pd(values, _mm256_set1_pd(0.0), _CMP_EQ_OQ); + return _mm256_movemask_pd(cmp); + } + Vectorized isnan() const { + return _mm256_cmp_pd(values, _mm256_set1_pd(0.0), _CMP_UNORD_Q); + } + bool has_inf_nan() const { + __m256d self_sub = _mm256_sub_pd(values, values); + return (_mm256_movemask_epi8(_mm256_castpd_si256(self_sub)) & 0x77777777) != 0; + } + Vectorized map(double (*const f)(double)) const { + __at_align__ double tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + Vectorized abs() const { + auto mask = _mm256_set1_pd(-0.f); + return _mm256_andnot_pd(mask, values); + } + Vectorized angle() const { + const auto zero_vec = _mm256_set1_pd(0.f); + const auto nan_vec = _mm256_set1_pd(NAN); + const auto not_nan_mask = _mm256_cmp_pd(values, values, _CMP_EQ_OQ); + const auto nan_mask = _mm256_cmp_pd(not_nan_mask, zero_vec, _CMP_EQ_OQ); + const auto pi = _mm256_set1_pd(c10::pi); + + const auto neg_mask = _mm256_cmp_pd(values, zero_vec, _CMP_LT_OQ); + auto angle = _mm256_blendv_pd(zero_vec, pi, neg_mask); + angle = _mm256_blendv_pd(angle, nan_vec, nan_mask); + return angle; + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm256_set1_pd(0); + } + Vectorized conj() const { + return *this; + } + Vectorized acos() const { + return Vectorized(Sleef_acosd4_u10(values)); + } + Vectorized acosh() const { + return Vectorized(Sleef_acoshd4_u10(values)); + } + Vectorized asin() const { + return Vectorized(Sleef_asind4_u10(values)); + } + Vectorized asinh() const { + return Vectorized(Sleef_asinhd4_u10(values)); + } + Vectorized atan() const { + return Vectorized(Sleef_atand4_u10(values)); + } + Vectorized atanh() const { + return Vectorized(Sleef_atanhd4_u10(values)); + } + Vectorized atan2(const Vectorized &b) const { + return Vectorized(Sleef_atan2d4_u10(values, b)); + } + Vectorized copysign(const Vectorized &sign) const { + return Vectorized(Sleef_copysignd4(values, sign)); + } + Vectorized erf() const { + return Vectorized(Sleef_erfd4_u10(values)); + } + Vectorized erfc() const { + return Vectorized(Sleef_erfcd4_u15(values)); + } + Vectorized erfinv() const { + return map(calc_erfinv); + } + Vectorized exp() const { + return Vectorized(Sleef_expd4_u10(values)); + } + Vectorized exp2() const { + return Vectorized(Sleef_exp2d4_u10(values)); + } + Vectorized expm1() const { + return Vectorized(Sleef_expm1d4_u10(values)); + } + Vectorized exp_u20() const { + return exp(); + } + Vectorized fmod(const Vectorized& q) const { + return Vectorized(Sleef_fmodd4(values, q)); + } + Vectorized hypot(const Vectorized &b) const { + return Vectorized(Sleef_hypotd4_u05(values, b)); + } + Vectorized i0() const { + return map(calc_i0); + } + Vectorized i0e() const { + return map(calc_i0e); + } + Vectorized digamma() const { + return map(calc_digamma); + } + Vectorized igamma(const Vectorized &x) const { + __at_align__ double tmp[size()]; + __at_align__ double tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (const auto i : c10::irange(size())) { + tmp[i] = calc_igamma(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized igammac(const Vectorized &x) const { + __at_align__ double tmp[size()]; + __at_align__ double tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (const auto i : c10::irange(size())) { + tmp[i] = calc_igammac(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized log() const { + return Vectorized(Sleef_logd4_u10(values)); + } + Vectorized log2() const { + return Vectorized(Sleef_log2d4_u10(values)); + } + Vectorized log10() const { + return Vectorized(Sleef_log10d4_u10(values)); + } + Vectorized log1p() const { + return Vectorized(Sleef_log1pd4_u10(values)); + } + Vectorized sin() const { + return Vectorized(Sleef_sind4_u10(values)); + } + Vectorized sinh() const { + return Vectorized(Sleef_sinhd4_u10(values)); + } + Vectorized cos() const { + return Vectorized(Sleef_cosd4_u10(values)); + } + Vectorized cosh() const { + return Vectorized(Sleef_coshd4_u10(values)); + } + Vectorized ceil() const { + return _mm256_ceil_pd(values); + } + Vectorized floor() const { + return _mm256_floor_pd(values); + } + Vectorized frac() const; + Vectorized neg() const { + return _mm256_xor_pd(_mm256_set1_pd(-0.), values); + } + Vectorized nextafter(const Vectorized &b) const { + return Vectorized(Sleef_nextafterd4(values, b)); + } + Vectorized round() const { + return _mm256_round_pd(values, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + } + Vectorized tan() const { + return Vectorized(Sleef_tand4_u10(values)); + } + Vectorized tanh() const { + return Vectorized(Sleef_tanhd4_u10(values)); + } + Vectorized trunc() const { + return _mm256_round_pd(values, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + } + Vectorized lgamma() const { + return Vectorized(Sleef_lgammad4_u10(values)); + } + Vectorized sqrt() const { + return _mm256_sqrt_pd(values); + } + Vectorized reciprocal() const { + return _mm256_div_pd(_mm256_set1_pd(1), values); + } + Vectorized rsqrt() const { + return _mm256_div_pd(_mm256_set1_pd(1), _mm256_sqrt_pd(values)); + } + Vectorized pow(const Vectorized &b) const { + return Vectorized(Sleef_powd4_u10(values, b)); + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized operator==(const Vectorized& other) const { + return _mm256_cmp_pd(values, other.values, _CMP_EQ_OQ); + } + + Vectorized operator!=(const Vectorized& other) const { + return _mm256_cmp_pd(values, other.values, _CMP_NEQ_UQ); + } + + Vectorized operator<(const Vectorized& other) const { + return _mm256_cmp_pd(values, other.values, _CMP_LT_OQ); + } + + Vectorized operator<=(const Vectorized& other) const { + return _mm256_cmp_pd(values, other.values, _CMP_LE_OQ); + } + + Vectorized operator>(const Vectorized& other) const { + return _mm256_cmp_pd(values, other.values, _CMP_GT_OQ); + } + + Vectorized operator>=(const Vectorized& other) const { + return _mm256_cmp_pd(values, other.values, _CMP_GE_OQ); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; +}; + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm256_add_pd(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm256_sub_pd(a, b); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return _mm256_mul_pd(a, b); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return _mm256_div_pd(a, b); +} + +// frac. Implement this here so we can use subtraction. +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + Vectorized max = _mm256_max_pd(a, b); + Vectorized isnan = _mm256_cmp_pd(a, b, _CMP_UNORD_Q); + // Exploit the fact that all-ones is a NaN. + return _mm256_or_pd(max, isnan); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + Vectorized min = _mm256_min_pd(a, b); + Vectorized isnan = _mm256_cmp_pd(a, b, _CMP_UNORD_Q); + // Exploit the fact that all-ones is a NaN. + return _mm256_or_pd(min, isnan); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min, const Vectorized& max) { + return _mm256_min_pd(max, _mm256_max_pd(min, a)); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + return _mm256_max_pd(min, a); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + return _mm256_min_pd(max, a); +} + +template <> +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return _mm256_and_pd(a, b); +} + +template <> +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return _mm256_or_pd(a, b); +} + +template <> +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return _mm256_xor_pd(a, b); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0); +} + +template <> +inline void convert(const double* src, double* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + _mm256_storeu_pd(dst + i, _mm256_loadu_pd(src + i)); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = src[i]; + } +} + +#ifdef CPU_CAPABILITY_AVX2 +template <> +Vectorized inline fmadd(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return _mm256_fmadd_pd(a, b, c); +} + +template <> +Vectorized inline fmsub(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return _mm256_fmsub_pd(a, b, c); +} +#endif + +#endif + +}} // namespace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_float.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_float.h new file mode 100644 index 0000000000000000000000000000000000000000..d57c28cfdbdc0ce8b47f000832bf7cd5b682e44e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_float.h @@ -0,0 +1,692 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#if defined(CPU_CAPABILITY_AVX2) +#define SLEEF_STATIC_LIBS +#include +#endif + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX2) + +template <> class Vectorized { +private: + __m256 values; +public: + using value_type = float; + using size_type = int; + static constexpr size_type size() { + return 8; + } + Vectorized() {} + Vectorized(__m256 v) : values(v) {} + Vectorized(float val) { + values = _mm256_set1_ps(val); + } + Vectorized(float val1, float val2, float val3, float val4, + float val5, float val6, float val7, float val8) { + values = _mm256_setr_ps(val1, val2, val3, val4, val5, val6, val7, val8); + } + Vectorized(const float (&arr)[8]) + : Vectorized(arr[0], arr[1], arr[2], arr[3], arr[4], arr[5], arr[6], arr[7]) {} + operator __m256() const { + return values; + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + return _mm256_blend_ps(a.values, b.values, mask); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + return _mm256_blendv_ps(a.values, b.values, mask.values); + } + template + static Vectorized arange(float base = 0.f, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step); + } + static Vectorized set(const Vectorized& a, const Vectorized& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return _mm256_loadu_ps(reinterpret_cast(ptr)); + __at_align__ float tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0.0; + } + std::memcpy( + tmp_values, reinterpret_cast(ptr), count * sizeof(float)); + return _mm256_loadu_ps(tmp_values); + } + void store(void* ptr, int64_t count = size()) const { + if (count == size()) { + _mm256_storeu_ps(reinterpret_cast(ptr), values); + } else if (count > 0) { + float tmp_values[size()]; + _mm256_storeu_ps(reinterpret_cast(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(float)); + } + } + const float& operator[](int idx) const = delete; + float& operator[](int idx) = delete; + int zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit and others are translated to 0-bit + __m256 cmp = _mm256_cmp_ps(values, _mm256_set1_ps(0.0f), _CMP_EQ_OQ); + return _mm256_movemask_ps(cmp); + } + Vectorized isnan() const { + return _mm256_cmp_ps(values, _mm256_set1_ps(0.0f), _CMP_UNORD_Q); + } + + bool has_inf_nan() const { + __m256 self_sub = _mm256_sub_ps(values, values); + return (_mm256_movemask_epi8(_mm256_castps_si256(self_sub)) & 0x77777777) != 0; + } + + Vectorized map(float (*const f)(float)) const { + __at_align__ float tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + Vectorized abs() const { + auto mask = _mm256_set1_ps(-0.f); + return _mm256_andnot_ps(mask, values); + } + Vectorized angle() const { + const auto zero_vec = _mm256_set1_ps(0.f); + const auto nan_vec = _mm256_set1_ps(NAN); + const auto not_nan_mask = _mm256_cmp_ps(values, values, _CMP_EQ_OQ); + const auto nan_mask = _mm256_cmp_ps(not_nan_mask, zero_vec, _CMP_EQ_OQ); + const auto pi = _mm256_set1_ps(c10::pi); + + const auto neg_mask = _mm256_cmp_ps(values, zero_vec, _CMP_LT_OQ); + auto angle = _mm256_blendv_ps(zero_vec, pi, neg_mask); + angle = _mm256_blendv_ps(angle, nan_vec, nan_mask); + return angle; + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm256_set1_ps(0); + } + Vectorized conj() const { + return *this; + } + Vectorized acos() const { + return Vectorized(Sleef_acosf8_u10(values)); + } + Vectorized acosh() const { + return Vectorized(Sleef_acoshf8_u10(values)); + } + Vectorized asin() const { + return Vectorized(Sleef_asinf8_u10(values)); + } + Vectorized asinh() const { + return Vectorized(Sleef_asinhf8_u10(values)); + } + Vectorized atan() const { + return Vectorized(Sleef_atanf8_u10(values)); + } + Vectorized atanh() const { + return Vectorized(Sleef_atanhf8_u10(values)); + } + Vectorized atan2(const Vectorized &b) const { + return Vectorized(Sleef_atan2f8_u10(values, b)); + } + Vectorized copysign(const Vectorized &sign) const { + return Vectorized(Sleef_copysignf8(values, sign)); + } + Vectorized erf() const { + // constants + const auto neg_zero_vec = _mm256_set1_ps(-0.f); + const auto one_vec = _mm256_set1_ps(1.0f); + const auto p = _mm256_set1_ps(0.3275911f); + const auto p1 = _mm256_set1_ps(0.254829592f); + const auto p2 = _mm256_set1_ps(-0.284496736f); + const auto p3 = _mm256_set1_ps(1.421413741f); + const auto p4 = _mm256_set1_ps(-1.453152027f); + const auto p5 = _mm256_set1_ps(1.061405429f); + // sign(x) + auto sign_mask = _mm256_and_ps(neg_zero_vec, values); + auto abs_vec = _mm256_xor_ps(sign_mask, values); + // t = 1 / (p * abs(x) + 1) + auto tmp0 = _mm256_fmadd_ps(p, abs_vec, one_vec); + auto t = _mm256_div_ps(one_vec, tmp0); + // r = p5 * t ^ 4 + p4 * t ^ 3 + p3 * t ^ 2 + p2 * t + p1 + auto tmp1 = _mm256_fmadd_ps(p5, t, p4); + auto tmp2 = _mm256_fmadd_ps(tmp1, t, p3); + auto tmp3 = _mm256_fmadd_ps(tmp2, t, p2); + auto r = _mm256_fmadd_ps(tmp3, t, p1); + // - exp(- x * x) + auto pow_2 = _mm256_mul_ps(values, values); + auto neg_pow_2 = _mm256_xor_ps(neg_zero_vec, pow_2); + // auto tmp4 = exp(neg_pow_2); + auto tmp4 = Vectorized(Sleef_expf8_u10(neg_pow_2)); + auto tmp5 = _mm256_xor_ps(neg_zero_vec, tmp4); + // erf(x) = sign(x) * (1 - r * t * exp(- x * x)) + auto tmp6 = _mm256_mul_ps(tmp5, t); + auto tmp7 = _mm256_fmadd_ps(tmp6, r, one_vec); + return _mm256_xor_ps(sign_mask, tmp7); + } + Vectorized erfc() const { + return Vectorized(Sleef_erfcf8_u15(values)); + } + Vectorized erfinv() const { + return map(calc_erfinv); + } + Vectorized exp() const { + return Vectorized(Sleef_expf8_u10(values)); + } + Vectorized exp2() const { + return Vectorized(Sleef_exp2f8_u10(values)); + } + Vectorized expm1() const { + return Vectorized(Sleef_expm1f8_u10(values)); + } + Vectorized exp_u20() const { + // A faster version of exp with ULP=20 + const __m256 vec_factorial_1 = + _mm256_set1_ps(0.999999701f); // 1/factorial(1) + const __m256 vec_factorial_2 = + _mm256_set1_ps(0.499991506f); // 1/factorial(2) + const __m256 vec_factorial_3 = + _mm256_set1_ps(0.166676521f); // 1/factorial(3) + const __m256 vec_factorial_4 = + _mm256_set1_ps(0.0418978221f); // 1/factorial(4) + const __m256 vec_factorial_5 = + _mm256_set1_ps(0.00828929059f); // 1/factorial(5) + const __m256 vec_exp_log2ef = + _mm256_castsi256_ps(_mm256_set1_epi32(0x3fb8aa3b)); // log2(e) + const __m256 vec_half = _mm256_set1_ps(0.5f); + const __m256 vec_one = _mm256_set1_ps(1.f); + const __m256 vec_zero = _mm256_set1_ps(0.f); + const __m256 vec_two = _mm256_set1_ps(2.f); + const __m256 vec_ln2f = _mm256_castsi256_ps(_mm256_set1_epi32(0x3f317218)); // ln(2) + const __m256 vec_ln_flt_min = _mm256_castsi256_ps(_mm256_set1_epi32(0xc2aeac50)); + const __m256 vec_ln_flt_max = _mm256_castsi256_ps(_mm256_set1_epi32(0x42b17218)); + const __m256i vec_127 = _mm256_set1_epi32(0x0000007f); + const int n_mantissa_bits = 23; + + // exp(x) = + // = exp(n * ln(2) + r) // divide x by ln(2) and get quot and rem + // = 2^n * exp(r) // simplify the exp(n*ln(2)) expression + + auto less_ln_flt_min_mask = + _mm256_cmp_ps(values, vec_ln_flt_min, 1 /*_CMP_LT_OS*/); + auto vec_src = _mm256_min_ps(values, vec_ln_flt_max); + vec_src = _mm256_max_ps(vec_src, vec_ln_flt_min); + + // fx = floorf(x * log2ef + 0.5) + auto vec_fx = _mm256_fmadd_ps(vec_src, vec_exp_log2ef, vec_half); + vec_fx = _mm256_floor_ps(vec_fx); + + // x = x - fx * ln2 + auto vec_exp_poly = _mm256_fnmadd_ps(vec_fx, vec_ln2f, vec_src); + + // compute polynomial + auto vec_res = + _mm256_fmadd_ps(vec_exp_poly, vec_factorial_5, vec_factorial_4); + vec_res = _mm256_fmadd_ps(vec_exp_poly, vec_res, vec_factorial_3); + vec_res = _mm256_fmadd_ps(vec_exp_poly, vec_res, vec_factorial_2); + vec_res = _mm256_fmadd_ps(vec_exp_poly, vec_res, vec_factorial_1); + vec_res = _mm256_fmadd_ps(vec_exp_poly, vec_res, vec_one); + + // compute 2^(n-1) + auto vec_exp_number = _mm256_sub_ps(vec_fx, vec_one); + auto vec_exp_number_i = _mm256_cvtps_epi32(vec_exp_number); + auto vec_two_pow_n_i = _mm256_add_epi32(vec_exp_number_i, vec_127); + vec_two_pow_n_i = _mm256_slli_epi32(vec_two_pow_n_i, n_mantissa_bits); + auto vec_two_pow_n = _mm256_castsi256_ps(vec_two_pow_n_i); + vec_two_pow_n = + _mm256_blendv_ps(vec_two_pow_n, vec_zero, less_ln_flt_min_mask); + + // y = y * 2^n + vec_res = _mm256_mul_ps(vec_res, vec_two_pow_n); + vec_res = _mm256_mul_ps(vec_res, vec_two); + return vec_res; + } + Vectorized fmod(const Vectorized& q) const { + return Vectorized(Sleef_fmodf8(values, q)); + } + Vectorized log() const { + return Vectorized(Sleef_logf8_u10(values)); + } + Vectorized log2() const { + return Vectorized(Sleef_log2f8_u10(values)); + } + Vectorized log10() const { + return Vectorized(Sleef_log10f8_u10(values)); + } + Vectorized log1p() const { + return Vectorized(Sleef_log1pf8_u10(values)); + } + Vectorized frac() const; + Vectorized sin() const { + return Vectorized(Sleef_sinf8_u35(values)); + } + Vectorized sinh() const { + return Vectorized(Sleef_sinhf8_u10(values)); + } + Vectorized cos() const { + return Vectorized(Sleef_cosf8_u35(values)); + } + Vectorized cosh() const { + return Vectorized(Sleef_coshf8_u10(values)); + } + Vectorized ceil() const { + return _mm256_ceil_ps(values); + } + Vectorized floor() const { + return _mm256_floor_ps(values); + } + Vectorized hypot(const Vectorized &b) const { + return Vectorized(Sleef_hypotf8_u05(values, b)); + } + Vectorized i0() const { + return map(calc_i0); + } + Vectorized i0e() const { + return map(calc_i0e); + } + Vectorized digamma() const { + return map(calc_digamma); + } + Vectorized igamma(const Vectorized &x) const { + __at_align__ float tmp[size()]; + __at_align__ float tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (const auto i : c10::irange(size())) { + tmp[i] = calc_igamma(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized igammac(const Vectorized &x) const { + __at_align__ float tmp[size()]; + __at_align__ float tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (const auto i : c10::irange(size())) { + tmp[i] = calc_igammac(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized neg() const { + return _mm256_xor_ps(_mm256_set1_ps(-0.f), values); + } + Vectorized nextafter(const Vectorized &b) const { + return Vectorized(Sleef_nextafterf8(values, b)); + } + Vectorized round() const { + return _mm256_round_ps(values, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + } + Vectorized tan() const { + return Vectorized(Sleef_tanf8_u10(values)); + } + Vectorized tanh() const { + return Vectorized(Sleef_tanhf8_u10(values)); + } + Vectorized trunc() const { + return _mm256_round_ps(values, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + } + Vectorized lgamma() const { + return Vectorized(Sleef_lgammaf8_u10(values)); + } + Vectorized sqrt() const { + return _mm256_sqrt_ps(values); + } + Vectorized reciprocal() const { + return _mm256_div_ps(_mm256_set1_ps(1), values); + } + Vectorized rsqrt() const { + return _mm256_div_ps(_mm256_set1_ps(1), _mm256_sqrt_ps(values)); + } + Vectorized pow(const Vectorized &b) const { + return Vectorized(Sleef_powf8_u10(values, b)); + } + float reduce_add() const { + auto v = values; + // 128-bit shuffle + auto v1 = _mm256_permute2f128_ps(v, v, 0x1); + v = _mm256_add_ps(v, v1); + // 64-bit shuffle + v1 = _mm256_shuffle_ps(v, v, 0x4E); + v = _mm256_add_ps(v, v1); + // 32-bit shuffle + v1 = _mm256_shuffle_ps(v, v, 0xB1); + v = _mm256_add_ps(v, v1); + return _mm256_cvtss_f32(v); + } + float reduce_max() const { + auto v = values; + // 128-bit shuffle + auto v1 = _mm256_permute2f128_ps(v, v, 0x1); + v = _mm256_max_ps(v, v1); + // 64-bit shuffle + v1 = _mm256_shuffle_ps(v, v, 0x4E); + v = _mm256_max_ps(v, v1); + // 32-bit shuffle + v1 = _mm256_shuffle_ps(v, v, 0xB1); + v = _mm256_max_ps(v, v1); + return _mm256_cvtss_f32(v); + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized operator==(const Vectorized& other) const { + return _mm256_cmp_ps(values, other.values, _CMP_EQ_OQ); + } + + Vectorized operator!=(const Vectorized& other) const { + return _mm256_cmp_ps(values, other.values, _CMP_NEQ_UQ); + } + + Vectorized operator<(const Vectorized& other) const { + return _mm256_cmp_ps(values, other.values, _CMP_LT_OQ); + } + + Vectorized operator<=(const Vectorized& other) const { + return _mm256_cmp_ps(values, other.values, _CMP_LE_OQ); + } + + Vectorized operator>(const Vectorized& other) const { + return _mm256_cmp_ps(values, other.values, _CMP_GT_OQ); + } + + Vectorized operator>=(const Vectorized& other) const { + return _mm256_cmp_ps(values, other.values, _CMP_GE_OQ); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm256_add_ps(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm256_sub_ps(a, b); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return _mm256_mul_ps(a, b); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return _mm256_div_ps(a, b); +} + +// frac. Implement this here so we can use subtraction +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + Vectorized max = _mm256_max_ps(a, b); + Vectorized isnan = _mm256_cmp_ps(a, b, _CMP_UNORD_Q); + // Exploit the fact that all-ones is a NaN. + return _mm256_or_ps(max, isnan); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + Vectorized min = _mm256_min_ps(a, b); + Vectorized isnan = _mm256_cmp_ps(a, b, _CMP_UNORD_Q); + // Exploit the fact that all-ones is a NaN. + return _mm256_or_ps(min, isnan); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min, const Vectorized& max) { + return _mm256_min_ps(max, _mm256_max_ps(min, a)); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + return _mm256_min_ps(max, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + return _mm256_max_ps(min, a); +} + +template <> +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return _mm256_and_ps(a, b); +} + +template <> +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return _mm256_or_ps(a, b); +} + +template <> +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return _mm256_xor_ps(a, b); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0f); +} + +template <> +inline void convert(const float* src, float* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + _mm256_storeu_ps(dst + i, _mm256_loadu_ps(src + i)); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = src[i]; + } +} + + +template <> +Vectorized inline fmadd(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return _mm256_fmadd_ps(a, b, c); +} + +template <> +Vectorized inline fmsub(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return _mm256_fmsub_ps(a, b, c); +} + +// TODO: rewrite with ATEN vectorized (need to add unpack and shuffle) +// Used by Inductor CPP codegen for micro gemm +inline void transpose_block(at::vec::VectorizedN &input) { + __m256 temp0[8]; + // unpacking and interleaving 32-bit elements + // a0 b0 a1 b1 a4 b4 a5 b5 + // a2 b2 a3 b3 a6 b6 a7 b7 + // c0 d0 c1 d1 ... + // c2 d2 c3 d3 ... + // e0 f0 e1 f1 ... + // e2 f2 e3 f3 ... + // g0 h0 g1 h1 ... + // g2 h2 g3 h3 ... + temp0[0] = _mm256_unpacklo_ps(input[0], input[1]); + temp0[1] = _mm256_unpackhi_ps(input[0], input[1]); + temp0[2] = _mm256_unpacklo_ps(input[2], input[3]); + temp0[3] = _mm256_unpackhi_ps(input[2], input[3]); + temp0[4] = _mm256_unpacklo_ps(input[4], input[5]); + temp0[5] = _mm256_unpackhi_ps(input[4], input[5]); + temp0[6] = _mm256_unpacklo_ps(input[6], input[7]); + temp0[7] = _mm256_unpackhi_ps(input[6], input[7]); + + __m256 temp1[8]; + // unpacking and interleaving 64-bit elements + // a0 b0 c0 d0 a4 b4 c4 d4 + // a1 b1 c1 d1 ... + // a2 b2 c2 d2 ... + // a3 b3 c3 d3 ... + // e0 f0 g0 h0 e4 f4 g4 h4 + // e1 f1 g1 h1 ... + // e2 f2 g2 h2 ... + // e3 f3 g3 h3 ... + temp1[0] = _mm256_castpd_ps( + _mm256_unpacklo_pd(_mm256_castps_pd(temp0[0]), _mm256_castps_pd(temp0[2]))); + temp1[1] = _mm256_castpd_ps( + _mm256_unpackhi_pd(_mm256_castps_pd(temp0[0]), _mm256_castps_pd(temp0[2]))); + temp1[2] = _mm256_castpd_ps( + _mm256_unpacklo_pd(_mm256_castps_pd(temp0[1]), _mm256_castps_pd(temp0[3]))); + temp1[3] = _mm256_castpd_ps( + _mm256_unpackhi_pd(_mm256_castps_pd(temp0[1]), _mm256_castps_pd(temp0[3]))); + temp1[4] = _mm256_castpd_ps( + _mm256_unpacklo_pd(_mm256_castps_pd(temp0[4]), _mm256_castps_pd(temp0[6]))); + temp1[5] = _mm256_castpd_ps( + _mm256_unpackhi_pd(_mm256_castps_pd(temp0[4]), _mm256_castps_pd(temp0[6]))); + temp1[6] = _mm256_castpd_ps( + _mm256_unpacklo_pd(_mm256_castps_pd(temp0[5]), _mm256_castps_pd(temp0[7]))); + temp1[7] = _mm256_castpd_ps( + _mm256_unpackhi_pd(_mm256_castps_pd(temp0[5]), _mm256_castps_pd(temp0[7]))); + + // shuffle 128-bits (composed of 4 32-bit elements) + // a0 b0 c0 d0 e0 f0 g0 h0 + // a1 b1 c1 d1 ... + // a2 b2 c2 d2 ... + // a3 b3 c3 d3 ... + // a4 b4 c4 d4 ... + // a5 b5 c5 d5 ... + // a6 b6 c6 d6 ... + // a7 b7 c7 d7 ... + input[0] = _mm256_permute2f128_ps(temp1[0], temp1[4], 0x20); + input[1] = _mm256_permute2f128_ps(temp1[1], temp1[5], 0x20); + input[2] = _mm256_permute2f128_ps(temp1[2], temp1[6], 0x20); + input[3] = _mm256_permute2f128_ps(temp1[3], temp1[7], 0x20); + input[4] = _mm256_permute2f128_ps(temp1[0], temp1[4], 0x31); + input[5] = _mm256_permute2f128_ps(temp1[1], temp1[5], 0x31); + input[6] = _mm256_permute2f128_ps(temp1[2], temp1[6], 0x31); + input[7] = _mm256_permute2f128_ps(temp1[3], temp1[7], 0x31); +} + +// Used by Inductor CPP codegen +template<> +inline void transpose_mxn( + const float* src, + int64_t ld_src, + float* dst, + int64_t ld_dst) { + // load from src to registers + at::vec::VectorizedN input; + // a: a0 a1 a2 a3 a4 a5 a6 a7 + // b: b0 b1 b2 b3 b4 b5 b6 b7 + // c: c0 c1 c2 c3 c4 c5 c6 c7 + // d: d0 d1 d2 d3 d4 d5 d6 d7 + // e: e0 e1 e2 e3 e4 e5 e6 e7 + // f: f0 f1 f2 f3 f4 f5 f6 f7 + // g: g0 g1 g2 g3 g4 g5 g6 g7 + // h: h0 h1 h2 h3 h4 h5 h6 h7 + int i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i < 8; i++) { + input[i] = _mm256_loadu_ps(&src[i * ld_src]); + } + + transpose_block(input); + + // store from registers to dst +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i < 8; i++) { + _mm256_storeu_ps(&dst[i * ld_dst], input[i]); + } +} + +template<> +inline void transpose_mxn( + const float* src, + int64_t ld_src, + float* dst, + int64_t ld_dst) { + transpose_mxn( + src , ld_src, dst, ld_dst); + transpose_mxn( + src + 8, ld_src, dst + 8 * ld_dst, ld_dst); + transpose_mxn( + src + 8 * ld_src, ld_src, dst + 8, ld_dst); + transpose_mxn( + src + 8 * ld_src + 8, ld_src, dst + 8 * ld_dst + 8, ld_dst); +} +#endif + +}} // namespace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_half.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_half.h new file mode 100644 index 0000000000000000000000000000000000000000..b27f33c8432327191299d914dec2270c66391b37 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_half.h @@ -0,0 +1,230 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#ifdef CPU_CAPABILITY_AVX2 + +template <> +class Vectorized: public Vectorized16 { +public: + using Vectorized16::Vectorized16; + + using value_type = Half; + + Vectorized frac() const; + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m256& x, const __m256& y) { return _mm256_add_ps(x, y); }); +} +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m256& x, const __m256& y) { return _mm256_sub_ps(x, y); }); +} +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m256& x, const __m256& y) { return _mm256_mul_ps(x, y); }); +} +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m256& x, const __m256& y) { return _mm256_div_ps(x, y); }); +} +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return _mm256_and_si256(a, b); +} +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return _mm256_or_si256(a, b); +} +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return _mm256_xor_si256(a, b); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0f); +} +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0f); +} + +// frac. Implement this here so we can use subtraction +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + __m256 a_lo, a_hi; + __m256 b_lo, b_hi; + cvtfp16_fp32(__m256i(a), a_lo, a_hi); + cvtfp16_fp32(__m256i(b), b_lo, b_hi); + auto max_lo = _mm256_max_ps(a_lo, b_lo); + auto max_hi = _mm256_max_ps(a_hi, b_hi); + auto nan_lo = _mm256_cmp_ps(a_lo, b_lo, _CMP_UNORD_Q); + auto nan_hi = _mm256_cmp_ps(a_hi, b_hi, _CMP_UNORD_Q); + // Exploit the fact that all-ones is a NaN. + auto o1 = _mm256_or_ps(max_lo, nan_lo); + auto o2 = _mm256_or_ps(max_hi, nan_hi); + return cvtfp32_fp16(o1, o2); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + __m256 a_lo, a_hi; + __m256 b_lo, b_hi; + cvtfp16_fp32(__m256i(a), a_lo, a_hi); + cvtfp16_fp32(__m256i(b), b_lo, b_hi); + auto min_lo = _mm256_min_ps(a_lo, b_lo); + auto min_hi = _mm256_min_ps(a_hi, b_hi); + auto nan_lo = _mm256_cmp_ps(a_lo, b_lo, _CMP_UNORD_Q); + auto nan_hi = _mm256_cmp_ps(a_hi, b_hi, _CMP_UNORD_Q); + // Exploit the fact that all-ones is a NaN. + auto o1 = _mm256_or_ps(min_lo, nan_lo); + auto o2 = _mm256_or_ps(min_hi, nan_hi); + return cvtfp32_fp16(o1, o2); +} + +template <> +Vectorized inline clamp(const Vectorized& a, + const Vectorized& min, const Vectorized& max) { + __m256 a_lo, a_hi; + __m256 min_lo, min_hi; + __m256 max_lo, max_hi; + cvtfp16_fp32(__m256i(a), a_lo, a_hi); + cvtfp16_fp32(__m256i(min), min_lo, min_hi); + cvtfp16_fp32(__m256i(max), max_lo, max_hi); + auto o1 = _mm256_min_ps(max_lo, _mm256_max_ps(min_lo, a_lo)); + auto o2 = _mm256_min_ps(max_hi, _mm256_max_ps(min_hi, a_hi)); + return cvtfp32_fp16(o1, o2); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + __m256 a_lo, a_hi; + __m256 max_lo, max_hi; + cvtfp16_fp32(__m256i(a), a_lo, a_hi); + cvtfp16_fp32(__m256i(max), max_lo, max_hi); + auto o1 = _mm256_min_ps(max_lo, a_lo); + auto o2 = _mm256_min_ps(max_hi, a_hi); + return cvtfp32_fp16(o1, o2); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + __m256 a_lo, a_hi; + __m256 min_lo, min_hi; + cvtfp16_fp32(__m256i(a), a_lo, a_hi); + cvtfp16_fp32(__m256i(min), min_lo, min_hi); + auto o1 = _mm256_max_ps(min_lo, a_lo); + auto o2 = _mm256_max_ps(min_hi, a_hi); + return cvtfp32_fp16(o1, o2); +} + +template <> +inline void convert(const Half* src, Half* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + auto vsrc = _mm256_loadu_si256(reinterpret_cast<__m256i*>((void*)(src + i))); + _mm256_storeu_si256(reinterpret_cast<__m256i*>((void*)(dst + i)), vsrc); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = src[i]; + } +} + +template <> +inline void convert(const float* src, Half* dst, int64_t n) { + int64_t i; + for (i = 0; i + Vectorized::size() <= n; i += Vectorized::size()) { + __m256 a = _mm256_loadu_ps(&src[i]); + __m256 b = _mm256_loadu_ps(&src[i + 8]); + + __m256i c = cvtfp32_fp16(a, b); + _mm256_storeu_si256(reinterpret_cast<__m256i*>(&dst[i]), c); + } + for (; i < n; i++) { + dst[i] = c10::convert(src[i]); + } +} + +template <> +inline void convert(const double* src, Half* dst, int64_t n) { + auto load_float = [](const double *src) -> __m256 { + // Load one float vector from an array of doubles + __m128 a = _mm256_cvtpd_ps(_mm256_loadu_pd(src)); + __m128 b = _mm256_cvtpd_ps(_mm256_loadu_pd(src + 4)); + return _mm256_insertf128_ps(_mm256_castps128_ps256(a), b, 1); + }; + + int64_t i; + for (i = 0; i + Vectorized::size() <= n; i += Vectorized::size()) { + __m256 a = load_float(&src[i]); + __m256 b = load_float(&src[i + 8]); + + __m256i c = cvtfp32_fp16(a, b); + _mm256_storeu_si256(reinterpret_cast<__m256i*>(&dst[i]), c); + } + for (; i < n; i++) { + dst[i] = c10::convert(src[i]); + } +} + +template <> +Vectorized inline fmadd(const Vectorized& a, + const Vectorized& b, const Vectorized& c) { + __m256 a_lo, a_hi; + __m256 b_lo, b_hi; + __m256 c_lo, c_hi; + cvtfp16_fp32(__m256i(a), a_lo, a_hi); + cvtfp16_fp32(__m256i(b), b_lo, b_hi); + cvtfp16_fp32(__m256i(c), c_lo, c_hi); + auto o1 = _mm256_fmadd_ps(a_lo, b_lo, c_lo); + auto o2 = _mm256_fmadd_ps(a_hi, b_hi, c_hi); + return cvtfp32_fp16(o1, o2); +} + +CONVERT_VECTORIZED_INIT(Half, half) +LOAD_FP32_VECTORIZED_INIT(Half, fp16) + +#else // defined(CPU_CAPABILITY_AVX2) + +#if !(defined(__aarch64__) && !defined(C10_MOBILE) && !defined(__CUDACC__) && !defined(CPU_CAPABILITY_SVE256)) +CONVERT_NON_VECTORIZED_INIT(Half, half) +#endif + +LOAD_FP32_NON_VECTORIZED_INIT(Half, fp16) +#endif // defined(CPU_CAPABILITY_AVX2) +}} // namsepace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_int.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_int.h new file mode 100644 index 0000000000000000000000000000000000000000..03929eecfed36949f403ddbd4b8fccaa7e1d2e36 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_int.h @@ -0,0 +1,1627 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#include + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +#ifdef CPU_CAPABILITY_AVX2 + +struct Vectorizedi { +protected: + __m256i values; + + static inline __m256i invert(const __m256i& v) { + const auto ones = _mm256_set1_epi64x(-1); + return _mm256_xor_si256(ones, v); + } +public: + Vectorizedi() {} + Vectorizedi(__m256i v) : values(v) {} + operator __m256i() const { + return values; + } +}; + +#else + +struct Vectorizedi {}; // dummy definition to make Vectorizedi always defined + +#endif // CPU_CAPABILITY_AVX2 + +#ifdef CPU_CAPABILITY_AVX2 + +template <> +class Vectorized : public Vectorizedi { +private: + static const Vectorized ones; +public: + using value_type = int64_t; + using size_type = int; + static constexpr size_type size() { + return 4; + } + using Vectorizedi::Vectorizedi; + Vectorized() {} + Vectorized(int64_t v) { values = _mm256_set1_epi64x(v); } + Vectorized(int64_t val1, int64_t val2, int64_t val3, int64_t val4) { + values = _mm256_setr_epi64x(val1, val2, val3, val4); + } + template + static Vectorized blend(Vectorized a, Vectorized b) { + __at_align__ int64_t tmp_values[size()]; + a.store(tmp_values); + if (mask & 0x01) + tmp_values[0] = _mm256_extract_epi64(b.values, 0); + if (mask & 0x02) + tmp_values[1] = _mm256_extract_epi64(b.values, 1); + if (mask & 0x04) + tmp_values[2] = _mm256_extract_epi64(b.values, 2); + if (mask & 0x08) + tmp_values[3] = _mm256_extract_epi64(b.values, 3); + return loadu(tmp_values); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + return _mm256_blendv_epi8(a.values, b.values, mask.values); + } + template + static Vectorized arange(int64_t base = 0, step_t step = static_cast(1)) { + return Vectorized(base, base + step, base + 2 * step, base + 3 * step); + } + static Vectorized + set(Vectorized a, Vectorized b, int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr) { + return _mm256_loadu_si256(reinterpret_cast(ptr)); + } + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ int64_t tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, ptr, count * sizeof(int64_t)); + return loadu(tmp_values); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + // ptr need not to be aligned here. See + // https://software.intel.com/content/www/us/en/develop/documentation/cpp-compiler-developer-guide-and-reference/top/compiler-reference/intrinsics/intrinsics-for-intel-advanced-vector-extensions/intrinsics-for-load-and-store-operations-1/mm256-storeu-si256.html + _mm256_storeu_si256(reinterpret_cast<__m256i*>(ptr), values); + } else if (count > 0) { + __at_align__ int64_t tmp_values[size()]; + _mm256_storeu_si256(reinterpret_cast<__m256i*>(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(int64_t)); + } + } + const int64_t& operator[](int idx) const = delete; + int64_t& operator[](int idx) = delete; + Vectorized abs() const { + auto zero = _mm256_set1_epi64x(0); + auto is_larger = _mm256_cmpgt_epi64(zero, values); + auto inverse = _mm256_xor_si256(values, is_larger); + return _mm256_sub_epi64(inverse, is_larger); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm256_set1_epi64x(0); + } + Vectorized conj() const { + return *this; + } + Vectorized neg() const; + Vectorized operator==(const Vectorized& other) const { + return _mm256_cmpeq_epi64(values, other.values); + } + Vectorized operator!=(const Vectorized& other) const { + return invert(_mm256_cmpeq_epi64(values, other.values)); + } + Vectorized operator<(const Vectorized& other) const { + return _mm256_cmpgt_epi64(other.values, values); + } + Vectorized operator<=(const Vectorized& other) const { + return invert(_mm256_cmpgt_epi64(values, other.values)); + } + Vectorized operator>(const Vectorized& other) const { + return _mm256_cmpgt_epi64(values, other.values); + } + Vectorized operator>=(const Vectorized& other) const { + return invert(_mm256_cmpgt_epi64(other.values, values)); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +class Vectorized : public Vectorizedi { +private: + static const Vectorized ones; +public: + using value_type = int32_t; + static constexpr int size() { + return 8; + } + using Vectorizedi::Vectorizedi; + Vectorized() {} + Vectorized(int32_t v) { values = _mm256_set1_epi32(v); } + Vectorized(int32_t val1, int32_t val2, int32_t val3, int32_t val4, + int32_t val5, int32_t val6, int32_t val7, int32_t val8) { + values = _mm256_setr_epi32(val1, val2, val3, val4, val5, val6, val7, val8); + } + template + static Vectorized blend(Vectorized a, Vectorized b) { + return _mm256_blend_epi32(a, b, mask); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + return _mm256_blendv_epi8(a.values, b.values, mask.values); + } + template + static Vectorized arange(int32_t base = 0, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step); + } + static Vectorized + set(Vectorized a, Vectorized b, int32_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr) { + return _mm256_loadu_si256(reinterpret_cast(ptr)); + } + static Vectorized loadu(const void* ptr, int32_t count) { + __at_align__ int32_t tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, ptr, count * sizeof(int32_t)); + return loadu(tmp_values); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + // ptr need not to be aligned here. See + // https://software.intel.com/content/www/us/en/develop/documentation/cpp-compiler-developer-guide-and-reference/top/compiler-reference/intrinsics/intrinsics-for-intel-advanced-vector-extensions/intrinsics-for-load-and-store-operations-1/mm256-storeu-si256.html + _mm256_storeu_si256(reinterpret_cast<__m256i*>(ptr), values); + } else if (count > 0) { + __at_align__ int32_t tmp_values[size()]; + _mm256_storeu_si256(reinterpret_cast<__m256i*>(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(int32_t)); + } + } + const int32_t& operator[](int idx) const = delete; + int32_t& operator[](int idx) = delete; + Vectorized abs() const { + return _mm256_abs_epi32(values); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm256_set1_epi32(0); + } + Vectorized conj() const { + return *this; + } + Vectorized neg() const; + int32_t reduce_add() const { + auto v = values; + // 128-bit shuffle + auto v1 = _mm256_permute2f128_si256(v, v, 0x1); + v = _mm256_add_epi32(v, v1); + // 64-bit shuffle + v1 = _mm256_shuffle_epi32(v, 0x4E); + v = _mm256_add_epi32(v, v1); + // 32-bit shuffle + v1 = _mm256_shuffle_epi32(v, 0xB1); + v = _mm256_add_epi32(v, v1); + __m128i lo = _mm256_castsi256_si128(v); + return _mm_cvtsi128_si32(lo); + } + int32_t reduce_max() const { + auto v = values; + // 128-bit shuffle + auto v1 = _mm256_permute2f128_si256(v, v, 0x1); + v = _mm256_max_epi32(v, v1); + // 64-bit shuffle + v1 = _mm256_shuffle_epi32(v, 0x4E); + v = _mm256_max_epi32(v, v1); + // 32-bit shuffle + v1 = _mm256_shuffle_epi32(v, 0xB1); + v = _mm256_max_epi32(v, v1); + __m128i lo = _mm256_castsi256_si128(v); + return _mm_cvtsi128_si32(lo); + } + Vectorized operator==(const Vectorized& other) const { + return _mm256_cmpeq_epi32(values, other.values); + } + Vectorized operator!=(const Vectorized& other) const { + return invert(_mm256_cmpeq_epi32(values, other.values)); + } + Vectorized operator<(const Vectorized& other) const { + return _mm256_cmpgt_epi32(other.values, values); + } + Vectorized operator<=(const Vectorized& other) const { + return invert(_mm256_cmpgt_epi32(values, other.values)); + } + Vectorized operator>(const Vectorized& other) const { + return _mm256_cmpgt_epi32(values, other.values); + } + Vectorized operator>=(const Vectorized& other) const { + return invert(_mm256_cmpgt_epi32(other.values, values)); + } + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +inline void convert(const int32_t *src, float *dst, int64_t n) { + int64_t i; + // int32_t and float have same size +#ifndef _MSC_VER +# pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + auto input_vec = _mm256_loadu_si256(reinterpret_cast(src + i)); + auto output_vec = _mm256_cvtepi32_ps(input_vec); + _mm256_storeu_ps(reinterpret_cast(dst + i), output_vec); + } +#ifndef _MSC_VER +# pragma unroll +#endif + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +template <> +inline void convert(const int32_t *src, double *dst, int64_t n) { + int64_t i; + // int32_t has half the size of double +#ifndef _MSC_VER +# pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + auto input_128_vec = _mm_loadu_si128(reinterpret_cast(src + i)); + auto output_vec = _mm256_cvtepi32_pd(input_128_vec); + _mm256_storeu_pd(reinterpret_cast(dst + i), output_vec); + } +#ifndef _MSC_VER +# pragma unroll +#endif + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +template <> +class Vectorized : public Vectorizedi { +private: + static const Vectorized ones; +public: + using value_type = int16_t; + static constexpr int size() { + return 16; + } + using Vectorizedi::Vectorizedi; + Vectorized() {} + Vectorized(int16_t v) { values = _mm256_set1_epi16(v); } + Vectorized(int16_t val1, int16_t val2, int16_t val3, int16_t val4, + int16_t val5, int16_t val6, int16_t val7, int16_t val8, + int16_t val9, int16_t val10, int16_t val11, int16_t val12, + int16_t val13, int16_t val14, int16_t val15, int16_t val16) { + values = _mm256_setr_epi16(val1, val2, val3, val4, val5, val6, val7, val8, + val9, val10, val11, val12, val13, val14, val15, val16); + } + template + static Vectorized blend(Vectorized a, Vectorized b) { + __at_align__ int16_t tmp_values[size()]; + a.store(tmp_values); + if (mask & 0x01) + tmp_values[0] = _mm256_extract_epi16(b.values, 0); + if (mask & 0x02) + tmp_values[1] = _mm256_extract_epi16(b.values, 1); + if (mask & 0x04) + tmp_values[2] = _mm256_extract_epi16(b.values, 2); + if (mask & 0x08) + tmp_values[3] = _mm256_extract_epi16(b.values, 3); + if (mask & 0x10) + tmp_values[4] = _mm256_extract_epi16(b.values, 4); + if (mask & 0x20) + tmp_values[5] = _mm256_extract_epi16(b.values, 5); + if (mask & 0x40) + tmp_values[6] = _mm256_extract_epi16(b.values, 6); + if (mask & 0x80) + tmp_values[7] = _mm256_extract_epi16(b.values, 7); + if (mask & 0x100) + tmp_values[8] = _mm256_extract_epi16(b.values, 8); + if (mask & 0x200) + tmp_values[9] = _mm256_extract_epi16(b.values, 9); + if (mask & 0x400) + tmp_values[10] = _mm256_extract_epi16(b.values, 10); + if (mask & 0x800) + tmp_values[11] = _mm256_extract_epi16(b.values, 11); + if (mask & 0x1000) + tmp_values[12] = _mm256_extract_epi16(b.values, 12); + if (mask & 0x2000) + tmp_values[13] = _mm256_extract_epi16(b.values, 13); + if (mask & 0x4000) + tmp_values[14] = _mm256_extract_epi16(b.values, 14); + if (mask & 0x8000) + tmp_values[15] = _mm256_extract_epi16(b.values, 15); + return loadu(tmp_values); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + return _mm256_blendv_epi8(a.values, b.values, mask.values); + } + template + static Vectorized arange(int16_t base = 0, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step, + base + 8 * step, base + 9 * step, base + 10 * step, base + 11 * step, + base + 12 * step, base + 13 * step, base + 14 * step, base + 15 * step); + } + static Vectorized + set(Vectorized a, Vectorized b, int16_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + case 8: + return blend<255>(a, b); + case 9: + return blend<511>(a, b); + case 10: + return blend<1023>(a, b); + case 11: + return blend<2047>(a, b); + case 12: + return blend<4095>(a, b); + case 13: + return blend<8191>(a, b); + case 14: + return blend<16383>(a, b); + case 15: + return blend<32767>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr) { + return _mm256_loadu_si256(reinterpret_cast(ptr)); + } + static Vectorized loadu(const void* ptr, int16_t count) { + __at_align__ int16_t tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, ptr, count * sizeof(int16_t)); + return loadu(tmp_values); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + // ptr need not to be aligned here. See + // https://software.intel.com/content/www/us/en/develop/documentation/cpp-compiler-developer-guide-and-reference/top/compiler-reference/intrinsics/intrinsics-for-intel-advanced-vector-extensions/intrinsics-for-load-and-store-operations-1/mm256-storeu-si256.html + _mm256_storeu_si256(reinterpret_cast<__m256i*>(ptr), values); + } else if (count > 0) { + __at_align__ int16_t tmp_values[size()]; + _mm256_storeu_si256(reinterpret_cast<__m256i*>(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(int16_t)); + } + } + const int16_t& operator[](int idx) const = delete; + int16_t& operator[](int idx) = delete; + Vectorized abs() const { + return _mm256_abs_epi16(values); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm256_set1_epi16(0); + } + Vectorized conj() const { + return *this; + } + Vectorized neg() const; + Vectorized operator==(const Vectorized& other) const { + return _mm256_cmpeq_epi16(values, other.values); + } + Vectorized operator!=(const Vectorized& other) const { + return invert(_mm256_cmpeq_epi16(values, other.values)); + } + Vectorized operator<(const Vectorized& other) const { + return _mm256_cmpgt_epi16(other.values, values); + } + Vectorized operator<=(const Vectorized& other) const { + return invert(_mm256_cmpgt_epi16(values, other.values)); + } + Vectorized operator>(const Vectorized& other) const { + return _mm256_cmpgt_epi16(values, other.values); + } + Vectorized operator>=(const Vectorized& other) const { + return invert(_mm256_cmpgt_epi16(other.values, values)); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template +class Vectorized8 : public Vectorizedi { + static_assert( + std::is_same_v || std::is_same_v, + "Only int8_t/uint8_t are supported"); +protected: + static const Vectorized ones; +public: + using value_type = T; + static constexpr int size() { + return 32; + } + using Vectorizedi::Vectorizedi; + Vectorized8() {} + Vectorized8(T v) { values = _mm256_set1_epi8(v); } + Vectorized8(T val1, T val2, T val3, T val4, + T val5, T val6, T val7, T val8, + T val9, T val10, T val11, T val12, + T val13, T val14, T val15, T val16, + T val17, T val18, T val19, T val20, + T val21, T val22, T val23, T val24, + T val25, T val26, T val27, T val28, + T val29, T val30, T val31, T val32) { + values = _mm256_setr_epi8(val1, val2, val3, val4, val5, val6, val7, val8, + val9, val10, val11, val12, val13, val14, val15, val16, + val17, val18, val19, val20, val21, val22, val23, val24, + val25, val26, val27, val28, val29, val30, val31, val32); + } + template + static Vectorized blend(Vectorized a, Vectorized b) { + __at_align__ T tmp_values[size()]; + a.store(tmp_values); + if (mask & 0x01) + tmp_values[0] = _mm256_extract_epi8(b.values, 0); + if (mask & 0x02) + tmp_values[1] = _mm256_extract_epi8(b.values, 1); + if (mask & 0x04) + tmp_values[2] = _mm256_extract_epi8(b.values, 2); + if (mask & 0x08) + tmp_values[3] = _mm256_extract_epi8(b.values, 3); + if (mask & 0x10) + tmp_values[4] = _mm256_extract_epi8(b.values, 4); + if (mask & 0x20) + tmp_values[5] = _mm256_extract_epi8(b.values, 5); + if (mask & 0x40) + tmp_values[6] = _mm256_extract_epi8(b.values, 6); + if (mask & 0x80) + tmp_values[7] = _mm256_extract_epi8(b.values, 7); + if (mask & 0x100) + tmp_values[8] = _mm256_extract_epi8(b.values, 8); + if (mask & 0x200) + tmp_values[9] = _mm256_extract_epi8(b.values, 9); + if (mask & 0x400) + tmp_values[10] = _mm256_extract_epi8(b.values, 10); + if (mask & 0x800) + tmp_values[11] = _mm256_extract_epi8(b.values, 11); + if (mask & 0x1000) + tmp_values[12] = _mm256_extract_epi8(b.values, 12); + if (mask & 0x2000) + tmp_values[13] = _mm256_extract_epi8(b.values, 13); + if (mask & 0x4000) + tmp_values[14] = _mm256_extract_epi8(b.values, 14); + if (mask & 0x8000) + tmp_values[15] = _mm256_extract_epi8(b.values, 15); + if (mask & 0x010000) + tmp_values[16] = _mm256_extract_epi8(b.values, 16); + if (mask & 0x020000) + tmp_values[17] = _mm256_extract_epi8(b.values, 17); + if (mask & 0x040000) + tmp_values[18] = _mm256_extract_epi8(b.values, 18); + if (mask & 0x080000) + tmp_values[19] = _mm256_extract_epi8(b.values, 19); + if (mask & 0x100000) + tmp_values[20] = _mm256_extract_epi8(b.values, 20); + if (mask & 0x200000) + tmp_values[21] = _mm256_extract_epi8(b.values, 21); + if (mask & 0x400000) + tmp_values[22] = _mm256_extract_epi8(b.values, 22); + if (mask & 0x800000) + tmp_values[23] = _mm256_extract_epi8(b.values, 23); + if (mask & 0x1000000) + tmp_values[24] = _mm256_extract_epi8(b.values, 24); + if (mask & 0x2000000) + tmp_values[25] = _mm256_extract_epi8(b.values, 25); + if (mask & 0x4000000) + tmp_values[26] = _mm256_extract_epi8(b.values, 26); + if (mask & 0x8000000) + tmp_values[27] = _mm256_extract_epi8(b.values, 27); + if (mask & 0x10000000) + tmp_values[28] = _mm256_extract_epi8(b.values, 28); + if (mask & 0x20000000) + tmp_values[29] = _mm256_extract_epi8(b.values, 29); + if (mask & 0x40000000) + tmp_values[30] = _mm256_extract_epi8(b.values, 30); + if (mask & 0x80000000) + tmp_values[31] = _mm256_extract_epi8(b.values, 31); + return loadu(tmp_values); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + return _mm256_blendv_epi8(a.values, b.values, mask.values); + } + template + static Vectorized arange(T base = 0, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step, + base + 8 * step, base + 9 * step, base + 10 * step, base + 11 * step, + base + 12 * step, base + 13 * step, base + 14 * step, base + 15 * step, + base + 16 * step, base + 17 * step, base + 18 * step, base + 19 * step, + base + 20 * step, base + 21 * step, base + 22 * step, base + 23 * step, + base + 24 * step, base + 25 * step, base + 26 * step, base + 27 * step, + base + 28 * step, base + 29 * step, base + 30 * step, base + 31 * step); + } + static Vectorized + set(Vectorized a, Vectorized b, T count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<0x1>(a, b); + case 2: + return blend<0x3>(a, b); + case 3: + return blend<0x7>(a, b); + case 4: + return blend<0xF>(a, b); + case 5: + return blend<0x1F>(a, b); + case 6: + return blend<0x3F>(a, b); + case 7: + return blend<0x7F>(a, b); + case 8: + return blend<0xFF>(a, b); + case 9: + return blend<0x1FF>(a, b); + case 10: + return blend<0x3FF>(a, b); + case 11: + return blend<0x7FF>(a, b); + case 12: + return blend<0xFFF>(a, b); + case 13: + return blend<0x1FFF>(a, b); + case 14: + return blend<0x3FFF>(a, b); + case 15: + return blend<0x7FFF>(a, b); + case 16: + return blend<0xFFFF>(a, b); + case 17: + return blend<0x1FFFF>(a, b); + case 18: + return blend<0x3FFFF>(a, b); + case 19: + return blend<0x7FFFF>(a, b); + case 20: + return blend<0xFFFFF>(a, b); + case 21: + return blend<0x1FFFFF>(a, b); + case 22: + return blend<0x3FFFFF>(a, b); + case 23: + return blend<0x7FFFFF>(a, b); + case 24: + return blend<0xFFFFFF>(a, b); + case 25: + return blend<0x1FFFFFF>(a, b); + case 26: + return blend<0x3FFFFFF>(a, b); + case 27: + return blend<0x7FFFFFF>(a, b); + case 28: + return blend<0xFFFFFFF>(a, b); + case 29: + return blend<0x1FFFFFFF>(a, b); + case 30: + return blend<0x3FFFFFFF>(a, b); + case 31: + return blend<0x7FFFFFFF>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr) { + return _mm256_loadu_si256(reinterpret_cast(ptr)); + } + static Vectorized loadu_one_fourth(const void* ptr) { + // Fast path if only load element number of 8. + // Note: We didn't merge it as fast path of loadu(const void* ptr, T count), + // Because loadu(const void* ptr, T count) requires zero initialization for upper 128 bits. + // However, by using _mm256_castsi128_si256, the upper 128 bits of the result are undefined. + // TODO We can use _mm256_zextsi128_si256 in the furture, + // since gcc 9.3 doesn't support it now. + __m128i input_128 = _mm_loadl_epi64(reinterpret_cast(ptr)); + return _mm256_castsi128_si256(input_128); + } + static Vectorized loadu(const void* ptr, T count) { + __at_align__ T tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, ptr, count * sizeof(T)); + return loadu(tmp_values); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + // ptr need not to be aligned here. See + // https://software.intel.com/content/www/us/en/develop/documentation/cpp-compiler-developer-guide-and-reference/top/compiler-reference/intrinsics/intrinsics-for-intel-advanced-vector-extensions/intrinsics-for-load-and-store-operations-1/mm256-storeu-si256.html + _mm256_storeu_si256(reinterpret_cast<__m256i*>(ptr), values); + } else if (count > 0) { + if (count == 8) { + // Fast path if only store element number of 8 + _mm_storel_epi64(reinterpret_cast<__m128i*>(ptr), _mm256_castsi256_si128(values)); + } else { + __at_align__ T tmp_values[size()]; + _mm256_storeu_si256(reinterpret_cast<__m256i*>(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(T)); + } + } + } + const T& operator[](int idx) const = delete; + T& operator[](int idx) = delete; + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm256_set1_epi8(0); + } + Vectorized conj() const { + return *this; + } +}; + +template<> +class Vectorized: public Vectorized8 { +public: + using Vectorized8::Vectorized8; + + Vectorized neg() const; + + Vectorized abs() const { + return _mm256_abs_epi8(values); + } + + Vectorized operator==(const Vectorized& other) const { + return _mm256_cmpeq_epi8(values, other.values); + } + Vectorized operator!=(const Vectorized& other) const { + return invert(_mm256_cmpeq_epi8(values, other.values)); + } + Vectorized operator<(const Vectorized& other) const { + return _mm256_cmpgt_epi8(other.values, values); + } + Vectorized operator<=(const Vectorized& other) const { + return invert(_mm256_cmpgt_epi8(values, other.values)); + } + Vectorized operator>(const Vectorized& other) const { + return other < *this; + } + Vectorized operator>=(const Vectorized& other) const { + return other <= *this; + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template<> +class Vectorized: public Vectorized8 { +public: + using Vectorized8::Vectorized8; + + Vectorized neg() const; + + Vectorized abs() const { + return *this; + } + + Vectorized operator==(const Vectorized& other) const { + return _mm256_cmpeq_epi8(values, other.values); + } + Vectorized operator!=(const Vectorized& other) const { + return invert(_mm256_cmpeq_epi8(values, other.values)); + } + Vectorized operator<(const Vectorized& other) const { + __m256i max = _mm256_max_epu8(values, other.values); + return invert(_mm256_cmpeq_epi8(max, values)); + } + Vectorized operator<=(const Vectorized& other) const { + __m256i max = _mm256_max_epu8(values, other.values); + return _mm256_cmpeq_epi8(max, other.values); + } + Vectorized operator>(const Vectorized& other) const { + return other < *this; + } + Vectorized operator>=(const Vectorized& other) const { + return other <= *this; + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm256_add_epi64(a, b); +} + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm256_add_epi32(a, b); +} + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm256_add_epi16(a, b); +} + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm256_add_epi8(a, b); +} + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm256_add_epi8(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm256_sub_epi64(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm256_sub_epi32(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm256_sub_epi16(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm256_sub_epi8(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm256_sub_epi8(a, b); +} + +// Negation. Defined here so we can utilize operator- +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +// Emulate operations with no native 64-bit support in avx, +// by extracting each element, performing the operation pointwise, +// then combining the results into a vector. +template +Vectorized inline emulate(const Vectorized& a, const Vectorized& b, const op_t& op) { + int64_t a0 = _mm256_extract_epi64(a, 0); + int64_t a1 = _mm256_extract_epi64(a, 1); + int64_t a2 = _mm256_extract_epi64(a, 2); + int64_t a3 = _mm256_extract_epi64(a, 3); + + int64_t b0 = _mm256_extract_epi64(b, 0); + int64_t b1 = _mm256_extract_epi64(b, 1); + int64_t b2 = _mm256_extract_epi64(b, 2); + int64_t b3 = _mm256_extract_epi64(b, 3); + + int64_t c0 = op(a0, b0); + int64_t c1 = op(a1, b1); + int64_t c2 = op(a2, b2); + int64_t c3 = op(a3, b3); + + return _mm256_set_epi64x(c3, c2, c1, c0); +} + +template +Vectorized inline emulate(const Vectorized& a, const Vectorized& b, const Vectorized& c, const op_t& op) { + int64_t a0 = _mm256_extract_epi64(a, 0); + int64_t a1 = _mm256_extract_epi64(a, 1); + int64_t a2 = _mm256_extract_epi64(a, 2); + int64_t a3 = _mm256_extract_epi64(a, 3); + + int64_t b0 = _mm256_extract_epi64(b, 0); + int64_t b1 = _mm256_extract_epi64(b, 1); + int64_t b2 = _mm256_extract_epi64(b, 2); + int64_t b3 = _mm256_extract_epi64(b, 3); + + int64_t c0 = _mm256_extract_epi64(c, 0); + int64_t c1 = _mm256_extract_epi64(c, 1); + int64_t c2 = _mm256_extract_epi64(c, 2); + int64_t c3 = _mm256_extract_epi64(c, 3); + + int64_t d0 = op(a0, b0, c0); + int64_t d1 = op(a1, b1, c1); + int64_t d2 = op(a2, b2, c2); + int64_t d3 = op(a3, b3, c3); + + return _mm256_set_epi64x(d3, d2, d1, d0); +} + +// AVX2 has no intrinsic for int64_t multiply so it needs to be emulated +// This could be implemented more efficiently using epi32 instructions +// This is also technically avx compatible, but then we'll need AVX +// code for add as well. +// Note: intentionally ignores undefined behavior like (-lowest * -1). +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return emulate(a, b, [](int64_t a_point, int64_t b_point) __ubsan_ignore_undefined__ {return a_point * b_point;}); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return _mm256_mullo_epi32(a, b); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return _mm256_mullo_epi16(a, b); +} + +template +Vectorized inline int_elementwise_binary_256(const Vectorized& a, const Vectorized& b, Op op) { + T values_a[Vectorized::size()]; + T values_b[Vectorized::size()]; + a.store(values_a); + b.store(values_b); + for (int i = 0; i != Vectorized::size(); i++) { + values_a[i] = op(values_a[i], values_b[i]); + } + return Vectorized::loadu(values_a); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + // We don't have an instruction for multiplying int8_t +#ifndef CPU_CAPABILITY_AVX2 + return int_elementwise_binary_256(a, b, std::multiplies()); +#else + __m256i mask00FF = _mm256_set1_epi16(0x00FF); + __m256i a_lo = _mm256_srai_epi16(_mm256_slli_epi16(a, 8), 8); + __m256i b_lo = _mm256_srai_epi16(_mm256_slli_epi16(b, 8), 8); + __m256i a_hi = _mm256_srai_epi16(a, 8); + __m256i b_hi = _mm256_srai_epi16(b, 8); + __m256i res_lo = _mm256_and_si256(_mm256_mullo_epi16(a_lo, b_lo), mask00FF); + __m256i res_hi = _mm256_slli_epi16(_mm256_mullo_epi16(a_hi, b_hi), 8); + __m256i res = _mm256_or_si256(res_hi, res_lo); + return res; +#endif +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + // We don't have an instruction for multiplying uint8_t +#ifndef CPU_CAPABILITY_AVX2 + return int_elementwise_binary_256(a, b, std::multiplies()); +#else + __m256i mask00FF = _mm256_set1_epi16(0x00FF); + __m256i a_lo = _mm256_and_si256 (a, mask00FF); + __m256i b_lo = _mm256_and_si256 (b, mask00FF); + __m256i a_hi = _mm256_srli_epi16(a, 8); + __m256i b_hi = _mm256_srli_epi16(b, 8); + __m256i res_lo = _mm256_and_si256(_mm256_mullo_epi16(a_lo, b_lo), mask00FF); + __m256i res_hi = _mm256_slli_epi16(_mm256_mullo_epi16(a_hi, b_hi), 8); + __m256i res = _mm256_or_si256(res_hi, res_lo); + return res; +#endif +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { +#ifndef CPU_CAPABILITY_AVX2 + return emulate(a, b, [](int64_t a_point, int64_t b_point) {return std::min(a_point, b_point);}); +#else + __m256i cmp = _mm256_cmpgt_epi64(a, b); + return _mm256_blendv_epi8(a, b, cmp); +#endif +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return _mm256_min_epi32(a, b); +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return _mm256_min_epi16(a, b); +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return _mm256_min_epi8(a, b); +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return _mm256_min_epu8(a, b); +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { +#ifndef CPU_CAPABILITY_AVX2 + return emulate(a, b, [](int64_t a_point, int64_t b_point) {return std::max(a_point, b_point);}); +#else + __m256i cmp = _mm256_cmpgt_epi64(a, b); + return _mm256_blendv_epi8(b, a, cmp); +#endif +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return _mm256_max_epi32(a, b); +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return _mm256_max_epi16(a, b); +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return _mm256_max_epi8(a, b); +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return _mm256_max_epu8(a, b); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { +#ifndef CPU_CAPABILITY_AVX2 + return emulate(a, min_val, max_val, [](int64_t a_point, int64_t min_point, int64_t max_point) {return std::min(max_point, std::max(a_point, min_point));}); +#else + return minimum(maximum(a, min_val), max_val); +#endif +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { + return _mm256_min_epi32(max_val, _mm256_max_epi32(a, min_val)); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { + return _mm256_min_epi16(max_val, _mm256_max_epi16(a, min_val)); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { + return _mm256_min_epi8(max_val, _mm256_max_epi8(a, min_val)); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { + return _mm256_min_epu8(max_val, _mm256_max_epu8(a, min_val)); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { +#ifndef CPU_CAPABILITY_AVX2 + return emulate(a, max_val, [](int64_t a_point, int64_t max_point) {return std::min(max_point, a_point);}); +#else + return minimum(max_val, a); +#endif +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { + return _mm256_min_epi32(max_val, a); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { + return _mm256_min_epi16(max_val, a); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { + return _mm256_min_epi8(max_val, a); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { + return _mm256_min_epu8(max_val, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { +#ifndef CPU_CAPABILITY_AVX2 + return emulate(a, min_val, [](int64_t a_point, int64_t min_point) {return std::max(min_point, a_point);}); +#else + return maximum(min_val, a); +#endif +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { + return _mm256_max_epi32(min_val, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { + return _mm256_max_epi16(min_val, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { + return _mm256_max_epi8(min_val, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { + return _mm256_max_epu8(min_val, a); +} + +template +std::enable_if_t || std::is_same_v), Vectorized> +inline convert_to_int32(const T* ptr, int count=Vectorized::size()) { + return Vectorized::loadu(ptr, count); +} + +template +std::enable_if_t, Vectorized> +inline convert_to_int32(const int8_t* ptr, int count=Vectorized::size()) { + if (count == Vectorized::size()) { + return _mm256_cvtepi8_epi32(_mm_loadl_epi64(reinterpret_cast(ptr))); + } else { + auto a = Vectorized::loadu(ptr, count); + return _mm256_cvtepi8_epi32(_mm256_castsi256_si128(a)); + } +} + +template +std::enable_if_t, Vectorized> +inline convert_to_int32(const uint8_t* ptr, int count=Vectorized::size()) { + if (count == Vectorized::size()) { + return _mm256_cvtepu8_epi32(_mm_loadl_epi64(reinterpret_cast(ptr))); + } else { + auto a = Vectorized::loadu(ptr, count); + return _mm256_cvtepu8_epi32(_mm256_castsi256_si128(a)); + } +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_256(a, b, std::divides()); +} +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_256(a, b, std::divides()); +} +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_256(a, b, std::divides()); +} +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_256(a, b, std::divides()); +} +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_256(a, b, std::divides()); +} + +template>::value, int> = 0> +inline Vectorized operator&(const Vectorized& a, const Vectorized& b) { + return _mm256_and_si256(a, b); +} +template>::value, int> = 0> +inline Vectorized operator|(const Vectorized& a, const Vectorized& b) { + return _mm256_or_si256(a, b); +} +template>::value, int> = 0> +inline Vectorized operator^(const Vectorized& a, const Vectorized& b) { + return _mm256_xor_si256(a, b); +} +template>::value, int> = 0> +inline Vectorized operator~(const Vectorized& a) { + return _mm256_xor_si256(a, _mm256_set1_epi32(-1)); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +template +Vectorized inline shift_256_16(const Vectorized& a, const Vectorized& b) { + // No vector instruction for shifting int16_t, so emulating it instead. + + // Control masks for shuffle operation, treating 256 bits as an + // array of 16-bit elements, and considering pairs of neighboring + // elements. Specifially, a mask named "ctl_M_N" (M,N in [0,1], and + // M!=N) is set so that shuffle will move element with index M from + // input pair into element with index N in output pair, and element + // with index M in output pair will be set to all 0s. + __m256i ctl_0_1 = _mm256_set_epi8(29, 28, 0x80, 0x80, 25, 24, 0x80, 0x80, + 21, 20, 0x80, 0x80, 17, 16, 0x80, 0x80, + 13, 12, 0x80, 0x80, 9, 8, 0x80, 0x80, + 5, 4, 0x80, 0x80, 1, 0, 0x80, 0x80); + __m256i ctl_1_0 = _mm256_set_epi8(0x80, 0x80, 31, 30, 0x80, 0x80, 27, 26, + 0x80, 0x80, 23, 22, 0x80, 0x80, 19, 18, + 0x80, 0x80, 15, 14, 0x80, 0x80, 11, 10, + 0x80, 0x80, 7, 6, 0x80, 0x80, 3, 2); + + // Masks for bitwise and operation, treating 256 bits as an array of + // 16-bit elements, and considering them in pairs of neighboring + // elements. A mask named "keep_M" (M in [0,1]) is set so that + // bitwise and will copy element with index M from input pair into + // element with the same index in output pair, while the other + // element in output pair will be set to all 0s. + __m256i keep_0 = _mm256_set1_epi32(0xFFFF); + __m256i keep_1 = _mm256_set1_epi32(0xFFFF0000); + + // Take each 16-bit element with idx%2==0 from input array to be + // shifted and extend it to 32 bits so that 0s are added to the + // right. Then, perform shifting on this 32-bit number. Upper 16 + // bits will be proper result of shifting original 16-bit number, so + // write them to result array, into the same position from which + // corresponding input element is taken. Also, make sure that + // result array elements with idx%2!=0 are set to all 0s. + // + // Note that number of bits to shift for is extended to 32 bits by + // adding 0s to the left. That means this number is not properly + // sign-extended for negative values. However, number of bits to + // shift is treated as an unsigned integer by respective shift + // intrinsics anyway so if negative then either with or without + // proper sign extension, it will be interpreted as a number greater + // than 32, and the shifting result will be the same. + __m256i a0 = _mm256_shuffle_epi8(a, ctl_0_1); + __m256i b0 = _mm256_and_si256(b, keep_0); + __m256i c0; + if (left_shift) + c0 = _mm256_sllv_epi32(a0, b0); + else + c0 = _mm256_srav_epi32(a0, b0); + c0 = _mm256_shuffle_epi8(c0, ctl_1_0); + + // Peform shifting the same way for input array elements with + // idx%2==1. + __m256i a1 = _mm256_and_si256(a, keep_1); + __m256i b1 = _mm256_shuffle_epi8(b, ctl_1_0); + __m256i c1; + if (left_shift) + c1 = _mm256_sllv_epi32(a1, b1); + else + c1 = _mm256_srav_epi32(a1, b1); + c1 = _mm256_and_si256(c1, keep_1); + + // Merge partial results into the final result. + __m256i c = _mm256_or_si256(c0, c1); + + return c; +} + +template || std::is_same_v, int> = 0> +Vectorized inline shift_256_8(const Vectorized& a, const Vectorized& b) { + // No vector instruction for shifting int8_t/uint8_t, so emulating + // it instead. + + // Control masks for shuffle operation, treating 256 bits as an + // array of 8-bit elements, and considering quadruples of + // neighboring elements. Specifially, a mask named "ctl_M_N" (M,N + // in [0,1,2,3], and M!=N) is set so that shuffle will move element + // with index M from input quadruple into element with index N in + // output quadruple, and other elements in output quadruple will be + // set to all 0s. + __m256i ctl_0_3 = _mm256_set_epi8(28, 0x80, 0x80, 0x80, 24, 0x80, 0x80, 0x80, + 20, 0x80, 0x80, 0x80, 16, 0x80, 0x80, 0x80, + 12, 0x80, 0x80, 0x80, 8, 0x80, 0x80, 0x80, + 4, 0x80, 0x80, 0x80, 0, 0x80, 0x80, 0x80); + __m256i ctl_1_0 = _mm256_set_epi8(0x80, 0x80, 0x80, 29, 0x80, 0x80, 0x80, 25, + 0x80, 0x80, 0x80, 21, 0x80, 0x80, 0x80, 17, + 0x80, 0x80, 0x80, 13, 0x80, 0x80, 0x80, 9, + 0x80, 0x80, 0x80, 5, 0x80, 0x80, 0x80, 1); + __m256i ctl_1_3 = _mm256_set_epi8(29, 0x80, 0x80, 0x80, 25, 0x80, 0x80, 0x80, + 21, 0x80, 0x80, 0x80, 17, 0x80, 0x80, 0x80, + 13, 0x80, 0x80, 0x80, 9, 0x80, 0x80, 0x80, + 5, 0x80, 0x80, 0x80, 1, 0x80, 0x80, 0x80); + __m256i ctl_2_0 = _mm256_set_epi8(0x80, 0x80, 0x80, 30, 0x80, 0x80, 0x80, 26, + 0x80, 0x80, 0x80, 22, 0x80, 0x80, 0x80, 18, + 0x80, 0x80, 0x80, 14, 0x80, 0x80, 0x80, 10, + 0x80, 0x80, 0x80, 6, 0x80, 0x80, 0x80, 2); + __m256i ctl_2_3 = _mm256_set_epi8(30, 0x80, 0x80, 0x80, 26, 0x80, 0x80, 0x80, + 22, 0x80, 0x80, 0x80, 18, 0x80, 0x80, 0x80, + 14, 0x80, 0x80, 0x80, 10, 0x80, 0x80, 0x80, + 6, 0x80, 0x80, 0x80, 2, 0x80, 0x80, 0x80); + __m256i ctl_3_0 = _mm256_set_epi8(0x80, 0x80, 0x80, 31, 0x80, 0x80, 0x80, 27, + 0x80, 0x80, 0x80, 23, 0x80, 0x80, 0x80, 19, + 0x80, 0x80, 0x80, 15, 0x80, 0x80, 0x80, 11, + 0x80, 0x80, 0x80, 7, 0x80, 0x80, 0x80, 3); + __m256i ctl_3_1 = _mm256_set_epi8(0x80, 0x80, 31, 0x80, 0x80, 0x80, 27, 0x80, + 0x80, 0x80, 23, 0x80, 0x80, 0x80, 19, 0x80, + 0x80, 0x80, 15, 0x80, 0x80, 0x80, 11, 0x80, + 0x80, 0x80, 7, 0x80, 0x80, 0x80, 3, 0x80); + __m256i ctl_3_2 = _mm256_set_epi8(0x80, 31, 0x80, 0x80, 0x80, 27, 0x80, 0x80, + 0x80, 23, 0x80, 0x80, 0x80, 19, 0x80, 0x80, + 0x80, 15, 0x80, 0x80, 0x80, 11, 0x80, 0x80, + 0x80, 7, 0x80, 0x80, 0x80, 3, 0x80, 0x80); + + // Masks for bitwise and operation, treating 256 bits as an array of + // 8-bit elements, and considering them in quadruples of neighboring + // elements. A mask named "keep_M" (M in [0,1,2,3]) is set so that + // bitwise and will copy element with index M from input quadruple + // into element with the same index in output quadruple, while the + // other elements in output quadruple will be set to all 0s. + __m256i keep_0 = _mm256_set1_epi32(0xFF); + __m256i keep_3 = _mm256_set1_epi32(0xFF000000); + + // Take each 8-bit element with idx%4==0 from input array to be + // shifted and extend it to 32 bits so that 0s are added to the + // right. Then, perform shifting on this 32-bit number. Upper 8 + // bits will be proper result of shifting original 8-bit number, so + // write them to result array, into the same position from which + // corresponding input element is taken. Also, make sure that + // result array elements with idx%4!=0 are set to all 0s. + // + // Note that number of bits to shift for is extended to 32 bits by + // adding 0s to the left. That means this number is not properly + // sign-extended for negative values. However, number of bits to + // shift is treated as an unsigned integer by respective shift + // intrinsics anyway so if negative then either with or without + // proper sign extension, it will be interpreted as a number greater + // than 32, and the shifting result will be the same. + __m256i a0 = _mm256_shuffle_epi8(a, ctl_0_3); + __m256i b0 = _mm256_and_si256(b, keep_0); + __m256i c0; + if (left_shift) + c0 = _mm256_sllv_epi32(a0, b0); + else + if constexpr (std::is_same_v) + c0 = _mm256_srav_epi32(a0, b0); + else + c0 = _mm256_srlv_epi32(a0, b0); + c0 = _mm256_shuffle_epi8(c0, ctl_3_0); + + // Peform shifting the same way for input array elements with + // idx%4==1. + __m256i a1 = _mm256_shuffle_epi8(a, ctl_1_3); + __m256i b1 = _mm256_shuffle_epi8(b, ctl_1_0); + __m256i c1; + if (left_shift) + c1 = _mm256_sllv_epi32(a1, b1); + else + if constexpr (std::is_same_v) + c1 = _mm256_srav_epi32(a1, b1); + else + c1 = _mm256_srlv_epi32(a1, b1); + c1 = _mm256_shuffle_epi8(c1, ctl_3_1); + + // Peform shifting the same way for input array elements with + // idx%4==2. + __m256i a2 = _mm256_shuffle_epi8(a, ctl_2_3); + __m256i b2 = _mm256_shuffle_epi8(b, ctl_2_0); + __m256i c2; + if (left_shift) + c2 = _mm256_sllv_epi32(a2, b2); + else + if constexpr (std::is_same_v) + c2 = _mm256_srav_epi32(a2, b2); + else + c2 = _mm256_srlv_epi32(a2, b2); + c2 = _mm256_shuffle_epi8(c2, ctl_3_2); + + // Peform shifting the same way for input array elements with + // idx%4==3. + __m256i a3 = _mm256_and_si256(a, keep_3); + __m256i b3 = _mm256_shuffle_epi8(b, ctl_3_0); + __m256i c3; + if (left_shift) + c3 = _mm256_sllv_epi32(a3, b3); + else + if constexpr (std::is_same_v) + c3 = _mm256_srav_epi32(a3, b3); + else + c3 = _mm256_srlv_epi32(a3, b3); + c3 = _mm256_and_si256(c3, keep_3); + + // Merge partial results into the final result. + __m256i c01 = _mm256_or_si256(c0, c1); + __m256i c23 = _mm256_or_si256(c2, c3); + __m256i c = _mm256_or_si256(c01, c23); + + return c; +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return _mm256_sllv_epi64(a, b); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return _mm256_sllv_epi32(a, b); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return shift_256_16(a, b); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return shift_256_8(a, b); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return shift_256_8(a, b); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + // No vector instruction for right arithmetic shifting int64_t, so emulating it + // instead. + + // Clamp the shift values such that shift values < 0 and > 64 are changed to 64 + // which results in -1 for negative input and 0 for non-negative input. + __m256i zero = _mm256_set1_epi64x(0); + __m256i max_shift = _mm256_set1_epi64x(64); + __m256i mask = _mm256_or_si256(_mm256_cmpgt_epi64(zero, b), _mm256_cmpgt_epi64(b, max_shift)); + __m256i shift = _mm256_blendv_epi8(b, max_shift, mask); + // Shift the number logically to the right, thus filling the most + // significant bits with 0s. Then, replace these bits with the sign + // bit. + __m256i sign_bits = _mm256_cmpgt_epi64(zero, a); + __m256i sign_shift = _mm256_sub_epi64(max_shift, shift); + __m256i sign_ext = _mm256_sllv_epi64(sign_bits, sign_shift); + __m256i c = _mm256_srlv_epi64(a, shift); + c = _mm256_or_si256(c, sign_ext); + + return c; +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return _mm256_srav_epi32(a, b); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return shift_256_16(a, b); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return shift_256_8(a, b); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return shift_256_8(a, b); +} + +#endif + +}} // namespace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_mask.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_mask.h new file mode 100644 index 0000000000000000000000000000000000000000..3460abe17e159d821d51c421e120117126761434 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_mask.h @@ -0,0 +1,298 @@ +#pragma once + +#include +#include +#include + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX2) && !defined(_MSC_VER) + +template +struct VecMaskLoad< + T, + dst_n, + mask_t, + mask_n, + typename std::enable_if_t< + (mask_n == dst_n * 2 && dst_n >= 1) && + (std::is_same_v || std::is_same_v), + void>> { + static inline VectorizedN apply( + const T* ptr, + const VecMask& vec_mask) { + VectorizedN tmp_vec; + VectorizedN result; + for (int i = 0; i < dst_n; i++) { + tmp_vec[0] = vec_mask[2 * i]; + tmp_vec[1] = vec_mask[2 * i + 1]; + auto int64_mask = VecMask(tmp_vec).template cast(); + auto int_mask = int64_mask.template cast()[0]; + if constexpr (std::is_same_v) { + result[i] = Vectorized( + _mm256_maskload_ps(ptr + i * Vectorized::size(), int_mask)); + } else { + result[i] = Vectorized( + _mm256_maskload_epi32(ptr + i * Vectorized::size(), int_mask)); + } + } + return result; + } +}; + +template +struct VecMaskLoad< + T, + dst_n, + mask_t, + dst_n, + typename std::enable_if_t< + std::is_same_v || std::is_same_v, + void>> { + static inline VectorizedN apply( + const T* ptr, + const VecMask& vec_mask) { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < dst_n; i++) { + auto tmp_mask = VecMask(vec_mask[i]); + auto int_mask = tmp_mask.template cast()[0]; + if constexpr (std::is_same_v) { + result[i] = Vectorized( + _mm256_maskload_ps(ptr + i * Vectorized::size(), int_mask)); + } else { + result[i] = Vectorized( + _mm256_maskload_epi32(ptr + i * Vectorized::size(), int_mask)); + } + } + return result; + } +}; + +template +struct VecMaskLoad< + T, + 2, + mask_t, + 1, + typename std::enable_if_t< + std::is_same_v || std::is_same_v>> { + static inline VectorizedN apply( + const T* ptr, + const VecMask& vec_mask) { + auto int64_mask = vec_mask.template cast(); + auto result = at::vec::VectorizedN(); + if constexpr (std::is_same_v) { + result[0] = _mm256_maskload_pd(ptr, int64_mask[0]); + result[1] = _mm256_maskload_pd( + ptr + at::vec::Vectorized::size(), int64_mask[1]); + } else { + result[0] = _mm256_maskload_epi64( + reinterpret_cast(ptr), int64_mask[0]); + result[1] = _mm256_maskload_epi64( + reinterpret_cast( + ptr + at::vec::Vectorized::size()), + int64_mask[1]); + } + return result; + } +}; + +// TODO: add specialization of VecMaskLoad for bfloat16/half and int8/uint8 + +template +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result[i] = _mm256_castsi256_ps(vec_mask[i]); + } + return result; + } +}; + +template +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result[i] = _mm256_castps_si256(vec_mask[i]); + } + return result; + } +}; + +template +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result[i] = _mm256_castpd_si256(vec_mask[i]); + } + return result; + } +}; + +template +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result[i] = _mm256_castsi256_pd(vec_mask[i]); + } + return result; + } +}; + +template +struct VecMaskCast< + int64_t, + dst_n, + mask_t, + mask_n, + typename std::enable_if_t< + (dst_n == 2 * mask_n) && + (std::is_same_v || std::is_same_v), + void>> { + static inline VecMask apply( + const VecMask& vec_mask) { + VectorizedN result; + auto int_mask = vec_mask.template cast(); +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < mask_n; ++i) { + auto int64_vec = + convert(VectorizedN(int_mask[i])); + result[2 * i] = int64_vec[0]; + result[2 * i + 1] = int64_vec[1]; + } + return VecMask(result); + } +}; + +template +struct VecMaskCast< + dst_t, + dst_n, + int64_t, + mask_n, + typename std::enable_if_t< + (mask_n == 2 * dst_n) && + (std::is_same_v || std::is_same_v), + void>> { + static inline VecMask apply( + const VecMask& vec_mask) { + VectorizedN result; + VectorizedN int64_vec; + for (int i = 0; i < dst_n; ++i) { + int64_vec[0] = vec_mask[2 * i]; + int64_vec[1] = vec_mask[2 * i + 1]; + result[i] = convert(int64_vec); + } + return VecMask(result).template cast(); + } +}; + +template <> +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + auto int64_mask = VecMaskCast::apply(vec_mask); + return VecMaskCast::apply(int64_mask); + } +}; +template <> +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + auto int64_mask = VecMaskCast::apply(vec_mask); + return VecMaskCast::apply(int64_mask); + } +}; + +template <> +inline bool VecMask::all_zero() const { + return _mm256_testz_si256(mask_[0], mask_[0]); +} + +template <> +inline bool VecMask::is_masked(int i) const { + return _mm256_movemask_ps(_mm256_castsi256_ps(mask_[0])) & (1 << i); +} + +template <> +inline bool VecMask::all_masked() const { + int mask = _mm256_movemask_ps(_mm256_castsi256_ps(mask_[0])); + return mask == 0xff; +} + +template +struct VecMaskCheck { + static inline bool all_zero(const VectorizedN& vec_mask) { + bool all_zero = true; + for (int i = 0; i < N; ++i) { + all_zero = all_zero && (_mm256_testz_si256(vec_mask[i], vec_mask[i]) > 0); + if (!all_zero) { + return all_zero; + } + } + return all_zero; + } + + static inline bool is_masked(const VectorizedN& vec_mask, int i) { + for (int j = 0; j < N; ++j) { + if (i < (j + 1) * 4) { + return _mm256_movemask_pd(_mm256_castsi256_pd(vec_mask[j])) & + (1 << (i - j * 4)); + } + } + return false; + } + + static inline bool all_masked(const VectorizedN& vec_mask) { + bool all_masked = true; + for (int i = 0; i < N; ++i) { + all_masked = all_masked && + (_mm256_movemask_pd(_mm256_castsi256_pd(vec_mask[i])) == 0x0f); + if (!all_masked) { + return all_masked; + } + } + return all_masked; + } +}; + +#define VEC_MASK_METHOD_WITH_CAST_TO_INT( \ + T, N, return_type, method, args_def, args) \ + template <> \ + inline return_type VecMask::method args_def const { \ + return cast().method args; \ + } + +VEC_MASK_METHOD_WITH_CAST_TO_INT(float, 1, bool, all_zero, (), ()) +VEC_MASK_METHOD_WITH_CAST_TO_INT(int64_t, 2, bool, all_zero, (), ()) +VEC_MASK_METHOD_WITH_CAST_TO_INT(float, 1, bool, is_masked, (int i), (i)) +VEC_MASK_METHOD_WITH_CAST_TO_INT(int64_t, 2, bool, is_masked, (int i), (i)) +VEC_MASK_METHOD_WITH_CAST_TO_INT(float, 1, bool, all_masked, (), ()) +VEC_MASK_METHOD_WITH_CAST_TO_INT(int64_t, 2, bool, all_masked, (), ()) + +#undef VEC_MASK_DEFINE_METHOD_WITH_CAST_TO_INT + +#endif + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_qint.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_qint.h new file mode 100644 index 0000000000000000000000000000000000000000..9b900cd0f63ee8e91c1da717cd654be7077c819e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vec256_qint.h @@ -0,0 +1,1334 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include + +#include +#include +#include +#include + +#include +#include + +// This file defines Vectorized<> for the quantized types. +// +// +// Currently, we simply use these classes as efficient converters between +// the quantized types and Vectorized, usually in bandwidth-bound cases +// where doing the arithmetic in full-precision is acceptable (e.g. +// elementwise operators). +// +// +// Conversions are as follows: +// Vectorized -> 4x Vectorized +// Vectorized -> 4x Vectorized +// Vectorized -> 1x Vectorized +// +// The size of the returned float vector is specified by the special +// constexpr function float_num_vecs. The type of the value returned +// from dequantize (and expected as an argument to quantize) is +// specified by float_vec_return_type. +// +// When writing kernels with these vectors, it is expected that floating- +// point operations will be carried out in a loop over Vectorized::float_num_vecs +// iterations. + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX2) + +#ifdef _MSC_VER +__declspec(align(64)) struct Vectorizedqi { + protected: + __m256i vals; +#else +struct Vectorizedqi { + protected: + __m256i vals __attribute__((aligned(64))); +#endif + + public: + Vectorizedqi() {} + Vectorizedqi(__m256i v) : vals(v) {} + operator __m256i() const { + return vals; + } +}; + +template +__m256i pack_saturate_and_clamp( + __m256i first, + __m256i second, + T min_val, + T max_val); + +template <> +inline __m256i pack_saturate_and_clamp( + __m256i /*first*/, + __m256i /*second*/, + int32_t /*min_val*/, + int32_t /*max_val*/) { + // This function is for linkage only, will not be used + TORCH_CHECK(false, "pack_saturate_and_clamp is not supported"); +} + +template <> +inline __m256i pack_saturate_and_clamp( + __m256i first, + __m256i second, + int8_t min_val, + int8_t max_val) { + __m256i packed_and_sat = _mm256_packs_epi16(first, second); + return _mm256_max_epi8( + _mm256_set1_epi8(min_val), + _mm256_min_epi8(packed_and_sat, _mm256_set1_epi8(max_val))); +} + +template <> +inline __m256i pack_saturate_and_clamp( + __m256i first, + __m256i second, + uint8_t min_val, + uint8_t max_val) { + __m256i packed_and_sat = _mm256_packus_epi16(first, second); + return _mm256_max_epu8( + _mm256_set1_epi8(min_val), + _mm256_min_epu8(packed_and_sat, _mm256_set1_epi8(max_val))); +} + +template +typename std::enable_if_t || std::is_same_v, at::vec::Vectorized> +inline convert_int8_to_float(at::vec::Vectorized src) { + // Note: this function only convert inputs number of elements equal to at::vec::Vectorized.size() + // Only handle first 8*8 bits + __m128i input_128 = _mm256_castsi256_si128(src); + // Convert from 8*uint8/int8 to 8*int32 + __m256i input_256_int32; + if constexpr (std::is_same_v) + input_256_int32 = _mm256_cvtepu8_epi32(input_128); + else + input_256_int32 = _mm256_cvtepi8_epi32(input_128); + // Convert from 8*int32 to 8*float + return _mm256_cvtepi32_ps(input_256_int32); +} + +template +typename std::enable_if_t || std::is_same_v, at::vec::Vectorized> +inline convert_float_to_int8(at::vec::Vectorized src) { + // Convert from float32 to int32 with truncation + __m256i x_values_int32 = _mm256_cvttps_epi32(src); + + // Convert from int32 to int16 using signed saturation + __m256i xy_packed_v = _mm256_packs_epi32(x_values_int32, x_values_int32); + + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + + // Convert from int16 to uint8/int8 using unsigned saturation + __m256i xyzw_clamped_v = pack_saturate_and_clamp( + xy_packed_v, xy_packed_v, min_val, max_val); + __m256i permute_mask_v = + _mm256_set_epi32(0x07, 0x03, 0x06, 0x02, 0x05, 0x01, 0x04, 0x00); + return _mm256_permutevar8x32_epi32(xyzw_clamped_v, permute_mask_v); +} + +template +__FORCE_INLINE void QuantizeAvx2( + const float* src, + T* dst, + int len, + float inverse_scale, + int64_t zero_point) { + constexpr int VLEN = 8; + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + const __m256i min_v = _mm256_set1_epi32(min_val); + const __m256i max_v = _mm256_set1_epi32(max_val); + // This is the largest int32 value < int32_max exactly representable in float + constexpr int32_t int32_float_max_val = + std::numeric_limits::max() - 127; + int i = 0; + __m256 inverse_scale_v = _mm256_set1_ps(inverse_scale); + // clang-format off + static const __m256i shuffle_mask_v = _mm256_set_epi8( + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0x0c, 0x08, 0x04, 0x00, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0x0c, 0x08, 0x04, 0x00); + // clang-format on + __m256i permute_mask_v = + _mm256_set_epi32(0x07, 0x03, 0x06, 0x02, 0x05, 0x01, 0x04, 0x00); + __m256i permute_mask_l8_v = + _mm256_set_epi32(0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x04, 0x00); + int len_aligned = len / (VLEN * 4) * (VLEN * 4); + for (; i < len_aligned; i += 4 * VLEN) { + // x + __m256 x_vals = _mm256_load_ps(src + i); + __m256 x_transformed_v = _mm256_mul_ps(x_vals, inverse_scale_v); + // If the floating point value is greater than int32_max, + // _mm256_cvtps_epi32 converts them to -ve. Clip at int32_float_max_val to + // Clip at int32_float_max_val to avoid this. + x_transformed_v = + _mm256_min_ps(x_transformed_v, _mm256_set1_ps(int32_float_max_val)); + // y + __m256 y_vals = _mm256_load_ps(src + i + VLEN); + __m256 y_transformed_v = _mm256_mul_ps(y_vals, inverse_scale_v); + y_transformed_v = + _mm256_min_ps(y_transformed_v, _mm256_set1_ps(int32_float_max_val)); + // z + __m256 z_vals = _mm256_load_ps(src + i + 2 * VLEN); + __m256 z_transformed_v = _mm256_mul_ps(z_vals, inverse_scale_v); + z_transformed_v = + _mm256_min_ps(z_transformed_v, _mm256_set1_ps(int32_float_max_val)); + // w + __m256 w_vals = _mm256_load_ps(src + i + 3 * VLEN); + __m256 w_transformed_v = _mm256_mul_ps(w_vals, inverse_scale_v); + w_transformed_v = + _mm256_min_ps(w_transformed_v, _mm256_set1_ps(int32_float_max_val)); + + __m256i x_rounded_v = _mm256_cvtps_epi32(x_transformed_v); + __m256i y_rounded_v = _mm256_cvtps_epi32(y_transformed_v); + __m256i z_rounded_v = _mm256_cvtps_epi32(z_transformed_v); + __m256i w_rounded_v = _mm256_cvtps_epi32(w_transformed_v); + + // add zero point + x_rounded_v = _mm256_add_epi32(x_rounded_v, _mm256_set1_epi32(zero_point)); + y_rounded_v = _mm256_add_epi32(y_rounded_v, _mm256_set1_epi32(zero_point)); + z_rounded_v = _mm256_add_epi32(z_rounded_v, _mm256_set1_epi32(zero_point)); + w_rounded_v = _mm256_add_epi32(w_rounded_v, _mm256_set1_epi32(zero_point)); + + __m256i xy_packed_v = _mm256_packs_epi32(x_rounded_v, y_rounded_v); + __m256i zw_packed_v = _mm256_packs_epi32(z_rounded_v, w_rounded_v); + __m256i xyzw_clamped_v = + pack_saturate_and_clamp(xy_packed_v, zw_packed_v, min_val, max_val); + + xyzw_clamped_v = + _mm256_permutevar8x32_epi32(xyzw_clamped_v, permute_mask_v); + _mm256_storeu_si256(reinterpret_cast<__m256i*>(dst + i), xyzw_clamped_v); + } + + // Additional 8-lane AVX2 version to take advantage when len is smaller + // based on fbgemm::QuantizeAvx2 (https://github.com/pytorch/FBGEMM) + for (; i < len / VLEN * VLEN; i += VLEN) { + __m256 x_vals = _mm256_load_ps(src + i); + __m256 x_transformed_v = _mm256_mul_ps(x_vals, inverse_scale_v); + x_transformed_v = + _mm256_min_ps(x_transformed_v, _mm256_set1_ps(int32_float_max_val)); + __m256i x_rounded_v = _mm256_cvtps_epi32(x_transformed_v); + x_rounded_v = _mm256_add_epi32(x_rounded_v, _mm256_set1_epi32(zero_point)); + __m256i x_clipped_v = + _mm256_max_epi32(min_v, _mm256_min_epi32(max_v, x_rounded_v)); + + x_clipped_v = _mm256_shuffle_epi8(x_clipped_v, shuffle_mask_v); + x_clipped_v = _mm256_permutevar8x32_epi32(x_clipped_v, permute_mask_l8_v); + _mm_storel_epi64( + reinterpret_cast<__m128i*>(dst + i), + _mm256_castsi256_si128(x_clipped_v)); + } + + for (; i < len; ++i) { + float transformed = src[i] * inverse_scale; + + // Not exactly the same behavior as the vectorized code. + // The vectorized code above always rounds to even in halfway cases + // (https://software.intel.com/en-us/node/523819), but std::nearbyint + // does the same only when the current rounding mode is FE_TONEAREST. + // However, in practice, this should not be a problem because most cases + // use the default rounding mode FE_TONEAREST. + // Note that we cannot implement the same behavior as the vectorized code + // using std::round because it does rounding away from zero in halfway + // cases. + transformed = zero_point + std::nearbyint(transformed); + float clipped = + std::min(std::max(transformed, float(min_val)), float(max_val)); + dst[i] = clipped; + } +} + +template<> +struct Vectorized : public Vectorizedqi { + using size_type = int; + static constexpr size_type kSize = Vectorized::size(); + static constexpr size_type size() { + return kSize; + } + + static constexpr int kFloatNumVecs = kSize / Vectorized::size(); + static constexpr int float_num_vecs() { + return kFloatNumVecs; + } + + static constexpr int int_num_vecs() { + return 1; + } + + using float_vec_return_type = std::array, kFloatNumVecs>; + using int_vec_return_type = std::array, 1>; + using value_type = c10::qint32::underlying; + + public: + using Vectorizedqi::Vectorizedqi; + Vectorized() {} + + Vectorized(__m256i vals_) { vals = vals_;} + + // Broadcast constructor + Vectorized(const c10::qint32& val) { + value_type uw = val.val_; + vals = _mm256_set1_epi32(uw); + } + + void store(void* ptr, int count = size()) const { + if (count != size()) { + memcpy(ptr, &vals, count * sizeof(value_type)); + } else { + _mm256_storeu_si256((__m256i*)ptr, vals); + } + } + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy( + tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return _mm256_loadu_si256((const __m256i*)tmp_values); + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized /*zero_point*/, + Vectorized scale_zp_premul) const { + __m256 float_vals = _mm256_cvtepi32_ps(vals); + return {vec::fmadd(scale, Vectorized(float_vals), scale_zp_premul)}; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + __m256 float_vals = _mm256_cvtepi32_ps(vals); + return {(Vectorized(float_vals) - zero_point) * scale}; + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float /*inverse_scale*/) { + Vectorized retval; + auto rhs_data = (__m256)rhs[0]; + at::native::quantize_vec( + scale, zero_point, (float*)&rhs_data, (c10::qint32*)&retval.vals, size()); + return retval; + } + + Vectorized maximum(Vectorized b) const { + return _mm256_max_epi32(vals, b.vals); + } + + Vectorized minimum(Vectorized b) const { + return _mm256_min_epi32(vals, b.vals); + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + return _mm256_min_epi32( + _mm256_max_epi32(vals, zero_point.vals), q_six.vals); + } + + int_vec_return_type widening_subtract(Vectorized b) const { + return {_mm256_sub_epi32(vals, b)}; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + __m256 multiplier_v = _mm256_set1_ps(multiplier); + __m256i zero_point_v = _mm256_set1_epi32(zero_point); + + __m256 scaled = _mm256_mul_ps(_mm256_cvtepi32_ps(inp[0]), multiplier_v); + __m256i rounded = _mm256_cvtps_epi32(scaled); + return _mm256_add_epi32(rounded, zero_point_v); + } + + private: + // Load from memory constructor + Vectorized(const void* ptr) { + vals = _mm256_loadu_si256((const __m256i*)ptr); + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline operator*( + const Vectorized& a, + const Vectorized& b) { + return _mm256_mullo_epi32(a, b); +} + +template <> +Vectorized inline operator+( + const Vectorized& a, + const Vectorized& b) { + return _mm256_add_epi32(a, b); +} + +/* + * Convert values from int32 back to int8/uint8 + */ +template +__m256i RequantizeAvx2( + const std::array, 4>& inp, + __m256 multiplier, + __m256i zp) { + static_assert( + std::is_same_v || std::is_same_v, + "Only int8_t/uint8_t are supported"); + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + __m256i permute_mask_v = + _mm256_set_epi32(0x07, 0x03, 0x06, 0x02, 0x05, 0x01, 0x04, 0x00); + __m256 x_scaled_v = _mm256_mul_ps(_mm256_cvtepi32_ps(inp[0]), multiplier); + __m256 y_scaled_v = _mm256_mul_ps(_mm256_cvtepi32_ps(inp[1]), multiplier); + __m256 z_scaled_v = _mm256_mul_ps(_mm256_cvtepi32_ps(inp[2]), multiplier); + __m256 w_scaled_v = _mm256_mul_ps(_mm256_cvtepi32_ps(inp[3]), multiplier); + + __m256i x_rounded_v = _mm256_cvtps_epi32(x_scaled_v); + __m256i y_rounded_v = _mm256_cvtps_epi32(y_scaled_v); + __m256i z_rounded_v = _mm256_cvtps_epi32(z_scaled_v); + __m256i w_rounded_v = _mm256_cvtps_epi32(w_scaled_v); + + /* Add zero point */ + __m256i x_v = _mm256_add_epi32(x_rounded_v, zp); + __m256i y_v = _mm256_add_epi32(y_rounded_v, zp); + __m256i z_v = _mm256_add_epi32(z_rounded_v, zp); + __m256i w_v = _mm256_add_epi32(w_rounded_v, zp); + + /* Pack to int16_t and saturate */ + __m256i xy_packed_v = _mm256_packs_epi32(x_v, y_v); + __m256i zw_packed_v = _mm256_packs_epi32(z_v, w_v); + + __m256i xyzw_clamped_v = + pack_saturate_and_clamp(xy_packed_v, zw_packed_v, min_val, max_val); + + /* + * xyzw_clamped_v has results in the following layout so we need to + * permute: x0-3 y0-3 z0-3 w0-3 x4-7 y4-7 z4-7 w4-7 + */ + xyzw_clamped_v = _mm256_permutevar8x32_epi32(xyzw_clamped_v, permute_mask_v); + return xyzw_clamped_v; +} + +template<> +struct Vectorized : public Vectorizedqi { + static constexpr int kSize = VECTOR_WIDTH; + static constexpr int size() { + return kSize; + } + + static constexpr int kFloatNumVecs = kSize / Vectorized::size(); + static constexpr int float_num_vecs() { + return kFloatNumVecs; + } + + static constexpr int kIntNumVecs = kSize / Vectorized::size(); + static constexpr int int_num_vecs() { + return kIntNumVecs; + } + + using float_vec_return_type = std::array, kFloatNumVecs>; + using int_vec_return_type = std::array, kIntNumVecs>; + using value_type = typename c10::qint8::underlying; + + public: + using Vectorizedqi::Vectorizedqi; + + Vectorized() {} + Vectorized(__m256i vals_) { vals = vals_;} + + // Broadcast constructor + Vectorized(const c10::qint8& val) { + value_type uw = val.val_; + vals = _mm256_set1_epi8(uw); + } + + // This is needed because the compiler emits awful code for the default + // constructor for moving the enum + // NOLINTNEXTLINE(clang-diagnostic-deprecated-copy) + C10_CLANG_DIAGNOSTIC_PUSH() + #if C10_CLANG_HAS_WARNING("-Wdeprecated-copy") + C10_CLANG_DIAGNOSTIC_IGNORE("-Wdeprecated-copy") + #endif + Vectorized(const Vectorized& other) : Vectorizedqi(other.vals) { } + C10_CLANG_DIAGNOSTIC_POP() + + void store(void* ptr, int count = size()) const { + if (count != size()) { + memcpy(ptr, &vals, count * sizeof(value_type)); + } else { + _mm256_storeu_si256((__m256i*)ptr, vals); + } + } + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy( + tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return _mm256_loadu_si256((const __m256i*)tmp_values); + } + + private: + __m256i cvtepi8_epi32(__m128i epi8_vals) const { + return _mm256_cvtepi8_epi32(epi8_vals); + } + + public: + float_vec_return_type dequantize( + Vectorized scale, + Vectorized /*zero_point*/, + Vectorized scale_neg_zp_premul) const { + __m128i int_val0 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 0)); + __m128i int_val1 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 1)); + __m128i int_val2 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 2)); + __m128i int_val3 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 3)); + + __m256 float_val0 = _mm256_cvtepi32_ps(cvtepi8_epi32(int_val0)); + __m256 float_val1 = _mm256_cvtepi32_ps(cvtepi8_epi32(int_val1)); + __m256 float_val2 = _mm256_cvtepi32_ps(cvtepi8_epi32(int_val2)); + __m256 float_val3 = _mm256_cvtepi32_ps(cvtepi8_epi32(int_val3)); + + auto val0 = + vec::fmadd(scale, Vectorized(float_val0), scale_neg_zp_premul); + auto val1 = + vec::fmadd(scale, Vectorized(float_val1), scale_neg_zp_premul); + auto val2 = + vec::fmadd(scale, Vectorized(float_val2), scale_neg_zp_premul); + auto val3 = + vec::fmadd(scale, Vectorized(float_val3), scale_neg_zp_premul); + return {val0, val1, val2, val3}; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + __m128i int_val0 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 0)); + __m128i int_val1 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 1)); + __m128i int_val2 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 2)); + __m128i int_val3 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 3)); + + __m256 float_val0 = _mm256_cvtepi32_ps(cvtepi8_epi32(int_val0)); + __m256 float_val1 = _mm256_cvtepi32_ps(cvtepi8_epi32(int_val1)); + __m256 float_val2 = _mm256_cvtepi32_ps(cvtepi8_epi32(int_val2)); + __m256 float_val3 = _mm256_cvtepi32_ps(cvtepi8_epi32(int_val3)); + + auto val0 = (Vectorized(float_val0) - zero_point) * scale; + auto val1 = (Vectorized(float_val1) - zero_point) * scale; + auto val2 = (Vectorized(float_val2) - zero_point) * scale; + auto val3 = (Vectorized(float_val3) - zero_point) * scale; + return {val0, val1, val2, val3}; + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float /*scale*/, + int32_t zero_point, + float inverse_scale) { + auto* rhs_data = (float*)rhs.data(); + int8_t quantized_values[32]; + QuantizeAvx2( + rhs_data, quantized_values, 32, inverse_scale, zero_point); + return Vectorized::loadu(quantized_values); + } + + Vectorized maximum(Vectorized b) const { + return _mm256_max_epi8(vals, b.vals); + } + + Vectorized minimum(Vectorized b) const { + return _mm256_min_epi8(vals, b.vals); + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + return _mm256_min_epi8( + _mm256_max_epi8(vals, zero_point.vals), q_six.vals); + } + + int_vec_return_type widening_subtract(Vectorized b) const { + __m128i int_val0 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 0)); + __m128i int_val1 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 1)); + __m128i int_val2 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 2)); + __m128i int_val3 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 3)); + + __m256i int32_val0 = cvtepi8_epi32(int_val0); + __m256i int32_val1 = cvtepi8_epi32(int_val1); + __m256i int32_val2 = cvtepi8_epi32(int_val2); + __m256i int32_val3 = cvtepi8_epi32(int_val3); + + __m128i int_b0 = _mm_set1_epi64x(_mm256_extract_epi64(b, 0)); + __m128i int_b1 = _mm_set1_epi64x(_mm256_extract_epi64(b, 1)); + __m128i int_b2 = _mm_set1_epi64x(_mm256_extract_epi64(b, 2)); + __m128i int_b3 = _mm_set1_epi64x(_mm256_extract_epi64(b, 3)); + + __m256i int32_b0 = cvtepi8_epi32(int_b0); + __m256i int32_b1 = cvtepi8_epi32(int_b1); + __m256i int32_b2 = cvtepi8_epi32(int_b2); + __m256i int32_b3 = cvtepi8_epi32(int_b3); + + __m256i res_0 = _mm256_sub_epi32(int32_val0, int32_b0); + __m256i res_1 = _mm256_sub_epi32(int32_val1, int32_b1); + __m256i res_2 = _mm256_sub_epi32(int32_val2, int32_b2); + __m256i res_3 = _mm256_sub_epi32(int32_val3, int32_b3); + + return {Vectorized(res_0), + Vectorized(res_1), + Vectorized(res_2), + Vectorized(res_3)}; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + __m256 multiplier_v = _mm256_set1_ps(multiplier); + __m256i zero_point_v = _mm256_set1_epi32(zero_point); + return RequantizeAvx2(inp, multiplier_v, zero_point_v); + } + + private: + // Load from memory constructor + Vectorized(const void* ptr) { + vals = _mm256_loadu_si256((const __m256i*)ptr); + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template<> +struct Vectorized : public Vectorizedqi { + static constexpr int kSize = VECTOR_WIDTH; + static constexpr int size() { + return kSize; + } + + static constexpr int kFloatNumVecs = kSize / Vectorized::size(); + static constexpr int float_num_vecs() { + return kFloatNumVecs; + } + + static constexpr int kIntNumVecs = kSize / Vectorized::size(); + static constexpr int int_num_vecs() { + return kIntNumVecs; + } + + using float_vec_return_type = std::array, kFloatNumVecs>; + using int_vec_return_type = std::array, kIntNumVecs>; + using value_type = typename c10::quint8::underlying; + + public: + using Vectorizedqi::Vectorizedqi; + Vectorized() {} + + Vectorized(__m256i vals_) { vals = vals_;} + + // Broadcast constructor + Vectorized(const c10::quint8& val) { + value_type uw = val.val_; + vals = _mm256_set1_epi8(uw); + } + + // NOLINTNEXTLINE(clang-diagnostic-deprecated-copy) + C10_CLANG_DIAGNOSTIC_PUSH() + #if C10_CLANG_HAS_WARNING("-Wdeprecated-copy") + C10_CLANG_DIAGNOSTIC_IGNORE("-Wdeprecated-copy") + #endif + Vectorized(const Vectorized& other) : Vectorizedqi(other.vals) { } + C10_CLANG_DIAGNOSTIC_POP() + + void store(void* ptr, int count = size()) const { + if (count != size()) { + memcpy(ptr, &vals, count * sizeof(value_type)); + } else { + _mm256_storeu_si256((__m256i*)ptr, vals); + } + } + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy( + tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return _mm256_loadu_si256((const __m256i*)tmp_values); + } + + private: + __m256i cvtepu8_epi32(__m128i epu8_vals) const { + return _mm256_cvtepu8_epi32(epu8_vals); + } + + public: + float_vec_return_type dequantize( + Vectorized scale, + Vectorized /*zero_point*/, + Vectorized scale_zp_premul) const { + __m128i int_val0 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 0)); + __m128i int_val1 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 1)); + __m128i int_val2 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 2)); + __m128i int_val3 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 3)); + + __m256 float_val0 = _mm256_cvtepi32_ps(cvtepu8_epi32(int_val0)); + __m256 float_val1 = _mm256_cvtepi32_ps(cvtepu8_epi32(int_val1)); + __m256 float_val2 = _mm256_cvtepi32_ps(cvtepu8_epi32(int_val2)); + __m256 float_val3 = _mm256_cvtepi32_ps(cvtepu8_epi32(int_val3)); + + auto val0 = + vec::fmadd(scale, Vectorized(float_val0), scale_zp_premul); + auto val1 = + vec::fmadd(scale, Vectorized(float_val1), scale_zp_premul); + auto val2 = + vec::fmadd(scale, Vectorized(float_val2), scale_zp_premul); + auto val3 = + vec::fmadd(scale, Vectorized(float_val3), scale_zp_premul); + return {val0, val1, val2, val3}; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + __m128i int_val0 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 0)); + __m128i int_val1 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 1)); + __m128i int_val2 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 2)); + __m128i int_val3 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 3)); + + __m256 float_val0 = _mm256_cvtepi32_ps(cvtepu8_epi32(int_val0)); + __m256 float_val1 = _mm256_cvtepi32_ps(cvtepu8_epi32(int_val1)); + __m256 float_val2 = _mm256_cvtepi32_ps(cvtepu8_epi32(int_val2)); + __m256 float_val3 = _mm256_cvtepi32_ps(cvtepu8_epi32(int_val3)); + + auto val0 = (Vectorized(float_val0) - zero_point) * scale; + auto val1 = (Vectorized(float_val1) - zero_point) * scale; + auto val2 = (Vectorized(float_val2) - zero_point) * scale; + auto val3 = (Vectorized(float_val3) - zero_point) * scale; + return {val0, val1, val2, val3}; + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float /*scale*/, + int32_t zero_point, + float inverse_scale) { + auto* rhs_data = (float*)rhs.data(); + uint8_t quantized_values[32]; + QuantizeAvx2( + rhs_data, quantized_values, 32, inverse_scale, zero_point); + return Vectorized::loadu(quantized_values); + } + + Vectorized maximum(Vectorized b) const { + return _mm256_max_epu8(vals, b.vals); + } + + Vectorized minimum(Vectorized b) const { + return _mm256_min_epu8(vals, b.vals); + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + return _mm256_min_epu8( + _mm256_max_epu8(vals, zero_point.vals), q_six.vals); + } + + int_vec_return_type widening_subtract(Vectorized b) const { + __m128i int_val0 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 0)); + __m128i int_val1 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 1)); + __m128i int_val2 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 2)); + __m128i int_val3 = _mm_set1_epi64x(_mm256_extract_epi64(vals, 3)); + + __m256i int32_val0 = cvtepu8_epi32(int_val0); + __m256i int32_val1 = cvtepu8_epi32(int_val1); + __m256i int32_val2 = cvtepu8_epi32(int_val2); + __m256i int32_val3 = cvtepu8_epi32(int_val3); + + __m128i int_b0 = _mm_set1_epi64x(_mm256_extract_epi64(b, 0)); + __m128i int_b1 = _mm_set1_epi64x(_mm256_extract_epi64(b, 1)); + __m128i int_b2 = _mm_set1_epi64x(_mm256_extract_epi64(b, 2)); + __m128i int_b3 = _mm_set1_epi64x(_mm256_extract_epi64(b, 3)); + + __m256i int32_b0 = cvtepu8_epi32(int_b0); + __m256i int32_b1 = cvtepu8_epi32(int_b1); + __m256i int32_b2 = cvtepu8_epi32(int_b2); + __m256i int32_b3 = cvtepu8_epi32(int_b3); + + __m256i res_0 = _mm256_sub_epi32(int32_val0, int32_b0); + __m256i res_1 = _mm256_sub_epi32(int32_val1, int32_b1); + __m256i res_2 = _mm256_sub_epi32(int32_val2, int32_b2); + __m256i res_3 = _mm256_sub_epi32(int32_val3, int32_b3); + return {Vectorized(res_0), + Vectorized(res_1), + Vectorized(res_2), + Vectorized(res_3)}; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + __m256 multiplier_v = _mm256_set1_ps(multiplier); + __m256i zero_point_v = _mm256_set1_epi32(zero_point); + return RequantizeAvx2(inp, multiplier_v, zero_point_v); + } + + private: + + // Load from memory constructor + Vectorized(const void* ptr) { + vals = _mm256_loadu_si256((const __m256i*)ptr); + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +#elif !defined(CPU_CAPABILITY_SVE256) + +// NOTE: These are low-performance implementations that we fall back on +// if we are not building with AVX2. This may not be an issue, because +// currently for quantization we assume the user has at least AVX512 +// installed, so these can simply act as a reference implementation. +// +// If in the future we relax this requirement (AVX2+), we should probably +// revisit these implementations + +template < + typename T, + typename float_vec_return_type_, + typename int_vec_return_type_, + int size_> +struct VectorizedQuantizedConverter { + static constexpr int size() { + return size_; + } + + static constexpr int float_num_vecs() { + return size_ / Vectorized::size(); + } + + static constexpr int int_num_vecs() { + return size_ / Vectorized::size(); + } + + using float_vec_return_type = float_vec_return_type_; + using int_vec_return_type = int_vec_return_type_; + + using value_type = typename T::underlying; + std::array vals; + + VectorizedQuantizedConverter(T val) { + for (const auto i : c10::irange(size())) { + vals[i] = val.val_; + } + } + + VectorizedQuantizedConverter(const void* ptr) { + memcpy(vals.data(), ptr, sizeof(value_type) * size()); + } + + void store(void* ptr, int count = size()) const { + memcpy(ptr, vals.data(), count * sizeof(value_type)); + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized /*scale_zp_premul*/) const { + float_vec_return_type rv; + for (const auto i : c10::irange(float_num_vecs())) { + float tmp_vals[Vectorized::size()]; + for (const auto j : c10::irange(Vectorized::size())) { + tmp_vals[j] = at::native::dequantize_val( + scale[j], zero_point[j], T(vals[Vectorized::size() * i + j])); + } + rv[i] = Vectorized(tmp_vals); + } + return rv; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + Vectorized scale_zp_premul; + return dequantize(scale, zero_point, scale_zp_premul); + } + + protected: + VectorizedQuantizedConverter() {} +}; + +template <> +struct Vectorized : public VectorizedQuantizedConverter< + c10::qint32, + std::array, 1>, + std::array, 1>, + Vectorized::size()> { + using VectorizedQuantizedConverter::VectorizedQuantizedConverter; + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy( + tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return Vectorized(tmp_values); + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float /*inverse_scale*/) { + std::array qvals; + std::array::size()> float_vals; + + for (const auto i : c10::irange(float_num_vecs())) { + rhs[i].store(&float_vals[i * Vectorized::size()]); + } + + at::native::quantize_vec( + scale, + zero_point, + float_vals.data(), + (c10::qint32*)qvals.data(), + float_vals.size()); + + return Vectorized::loadu(qvals.data()); + } + + Vectorized maximum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::max(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized minimum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min( + std::max(vals[i], zero_point.vals[i]), q_six.vals[i]); + } + return retval; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + int_vec_return_type retval; + for (const auto i : c10::irange(size())) { + retval[0].vals[i] = vals[i] - b.vals[i]; + } + return retval; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = + std::nearbyint(static_cast(inp[0].vals[i]) * multiplier) + + zero_point; + } + return retval; + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline operator*( + const Vectorized& a, + const Vectorized& b) { + Vectorized retval; + for (const auto i : c10::irange(std::decay_t::size())) { + retval.vals[i] = a.vals[i] * b.vals[i]; + } + return retval; +} + +template <> +Vectorized inline operator+( + const Vectorized& a, + const Vectorized& b) { + Vectorized retval; + for (const auto i : c10::irange(std::decay_t::size())) { + retval.vals[i] = a.vals[i] + b.vals[i]; + } + return retval; +} + +template <> +struct Vectorized : public VectorizedQuantizedConverter< + c10::qint8, + std::array, 4>, + std::array, 4>, + 4 * Vectorized::size()> { + using VectorizedQuantizedConverter::VectorizedQuantizedConverter; + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy( + tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return Vectorized(tmp_values); + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float /*inverse_scale*/) { + std::array qvals; + std::array::size()> float_vals; + + for (const auto i : c10::irange(float_num_vecs())) { + rhs[i].store(&float_vals[i * Vectorized::size()]); + } + + at::native::quantize_vec( + scale, + zero_point, + float_vals.data(), + (c10::qint8*)qvals.data(), + float_vals.size()); + + return Vectorized::loadu(qvals.data()); + } + + Vectorized maximum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::max(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized minimum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min( + std::max(vals[i], zero_point.vals[i]), q_six.vals[i]); + } + return retval; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + int_vec_return_type retval; + constexpr int elem_per_int_vec = size() / int_num_vecs(); + for (const auto i : c10::irange(int_num_vecs())) { + for (const auto j : c10::irange(elem_per_int_vec)) { + retval[i].vals[j] = + static_cast(vals[i * elem_per_int_vec + j]) - + static_cast(b.vals[i * elem_per_int_vec + j]); + } + } + return retval; + } + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + constexpr int elem_per_int_vec = size() / int_num_vecs(); + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + Vectorized retval; + for (const auto i : c10::irange(int_num_vecs())) { + for (const auto j : c10::irange(elem_per_int_vec)) { + int32_t rounded = + std::nearbyint(static_cast(inp[i].vals[j]) * multiplier) + + zero_point; + retval.vals[i * elem_per_int_vec + j] = + std::min(std::max(rounded, min_val), max_val); + } + } + return retval; + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template <> +struct Vectorized : public VectorizedQuantizedConverter< + c10::quint8, + std::array, 4>, + std::array, 4>, + 4 * Vectorized::size()> { + using VectorizedQuantizedConverter::VectorizedQuantizedConverter; + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy( + tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return Vectorized(tmp_values); + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float /*inverse_scale*/) { + std::array qvals; + std::array::size()> float_vals; + + for (const auto i : c10::irange(float_num_vecs())) { + rhs[i].store(&float_vals[i * Vectorized::size()]); + } + + at::native::quantize_vec( + scale, + zero_point, + float_vals.data(), + (c10::quint8*)qvals.data(), + float_vals.size()); + + return Vectorized::loadu(qvals.data()); + } + + Vectorized maximum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::max(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized minimum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min( + std::max(vals[i], zero_point.vals[i]), q_six.vals[i]); + } + return retval; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + int_vec_return_type retval; + constexpr int elem_per_int_vec = size() / int_num_vecs(); + for (const auto i : c10::irange(int_num_vecs())) { + for (const auto j : c10::irange(elem_per_int_vec)) { + retval[i].vals[j] = + static_cast(vals[i * elem_per_int_vec + j]) - + static_cast(b.vals[i * elem_per_int_vec + j]); + } + } + return retval; + } + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + constexpr int elem_per_int_vec = size() / int_num_vecs(); + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + Vectorized retval; + for (const auto i : c10::irange(int_num_vecs())) { + for (const auto j : c10::irange(elem_per_int_vec)) { + int32_t rounded = + std::nearbyint(static_cast(inp[i].vals[j]) * multiplier) + + zero_point; + retval.vals[i * elem_per_int_vec + j] = + std::min(std::max(rounded, min_val), max_val); + } + } + return retval; + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +#endif // if defined(CPU_CAPABILITY_AVX2) + +#if (defined(__aarch64__) && !defined(CPU_CAPABILITY_SVE256)) +std::pair, Vectorized> +inline convert_int8_to_float(at::vec::Vectorized src) { + auto s8x8 = vld1_s8(src.operator const int8_t*()); + auto s16x8 = vmovl_s8(s8x8); + + auto s32x4_hi = vmovl_s16(vget_high_s16(s16x8)); + auto s32x4_lo = vmovl_s16(vget_low_s16(s16x8)); + + return std::make_pair(Vectorized(vcvtq_f32_s32(s32x4_lo)), Vectorized(vcvtq_f32_s32(s32x4_hi))); +} + +std::pair, Vectorized> +inline convert_int8_to_float(at::vec::Vectorized src) { + auto u8x8 = vld1_u8(src.operator const uint8_t*()); + auto u16x8 = vmovl_u8(u8x8); + auto u32x4_hi = vmovl_u16(vget_high_u16(u16x8)); + auto u32x4_lo = vmovl_u16(vget_low_u16(u16x8)); + + return std::make_pair(Vectorized(vcvtq_f32_u32(u32x4_lo)), Vectorized(vcvtq_f32_u32(u32x4_hi))); +} + +Vectorized +inline convert_int8_half_register_to_float(at::vec::Vectorized src) { + auto s8x8 = vld1_s8(src.operator const int8_t*()); + auto s16x8 = vmovl_s8(s8x8); + + auto s32x4_lo = vmovl_s16(vget_low_s16(s16x8)); + + return Vectorized(vcvtq_f32_s32(s32x4_lo)); +} + +Vectorized +inline convert_int8_half_register_to_float(at::vec::Vectorized src) { + auto u8x8 = vld1_u8(src.operator const uint8_t*()); + auto u16x8 = vmovl_u8(u8x8); + auto u32x4_lo = vmovl_u16(vget_low_u16(u16x8)); + + return Vectorized(vcvtq_f32_u32(u32x4_lo)); +} + +#endif +}} // namespace at::vec::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_bfloat16_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_bfloat16_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..2d8afd9ef29525e1acedd10f35cb3e7c21e646af --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_bfloat16_vsx.h @@ -0,0 +1,73 @@ +#pragma once + +#include +#include +#include +#include + +namespace at { +namespace vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +inline std::tuple, Vectorized> convert_bfloat16_float( + const Vectorized& a) { + constexpr int64_t K = Vectorized::size(); + __at_align__ float arr[K]; + __at_align__ BFloat16 arr2[K]; + a.store(arr2); + convert(arr2, arr, K); + return std::make_tuple( + Vectorized::loadu(arr), + Vectorized::loadu(arr + Vectorized::size())); +} + +inline Vectorized convert_float_bfloat16( + const Vectorized& a, + const Vectorized& b) { + constexpr int64_t K = Vectorized::size(); + __at_align__ float arr[K]; + __at_align__ BFloat16 arr2[K]; + a.store(arr); + b.store(arr + Vectorized::size()); + convert(arr, arr2, K); + return Vectorized::loadu(arr2); +} + +inline void load_fp32_from_bf16(const c10::BFloat16* data, Vectorized& out) { + __at_align__ float values[Vectorized::size()]; + for (const auto k : c10::irange(Vectorized::size())) { + values[k] = data[k]; + } + out = Vectorized::loadu(values); +} + +inline void load_fp32_from_bf16( + const c10::BFloat16* data, + Vectorized& out1, + Vectorized& out2) { + load_fp32_from_bf16(data, out1); + data += Vectorized::size(); + load_fp32_from_bf16(data, out2); +} + +inline void load_fp32_from_fp16(const c10::Half* data, Vectorized& out) { + __at_align__ float values[Vectorized::size()]; + for (const auto k : c10::irange(Vectorized::size())) { + values[k] = data[k]; + } + out = Vectorized::loadu(values); +} + +inline void load_fp32_from_fp16( + const c10::Half* data, + Vectorized& out1, + Vectorized& out2) { + load_fp32_from_fp16(data, out1); + data += Vectorized::size(); + load_fp32_from_fp16(data, out2); +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_common_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_common_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..98ac8396317943c3e98d8a0be207493dc66e3155 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_common_vsx.h @@ -0,0 +1,246 @@ +#pragma once + +#include +#include +#include + +// Note: header order is important here +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include + +#include + +namespace at { +namespace vec { + +inline namespace CPU_CAPABILITY { + +DEFINE_CLAMP_FUNCS(c10::quint8) +DEFINE_CLAMP_FUNCS(c10::qint8) +DEFINE_CLAMP_FUNCS(c10::qint32) +DEFINE_CLAMP_FUNCS(int16_t) +DEFINE_CLAMP_FUNCS(int32_t) +DEFINE_CLAMP_FUNCS(int64_t) +DEFINE_CLAMP_FUNCS(float) +DEFINE_CLAMP_FUNCS(double) + +template <> +Vectorized C10_ALWAYS_INLINE fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + return Vectorized{ + vec_madd(a.vec0(), b.vec0(), c.vec0()), + vec_madd(a.vec1(), b.vec1(), c.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + return Vectorized{ + a.vec0() * b.vec0() + c.vec0(), a.vec1() * b.vec1() + c.vec1()}; +} +template <> +Vectorized C10_ALWAYS_INLINE fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + return Vectorized{ + a.vec0() * b.vec0() + c.vec0(), a.vec1() * b.vec1() + c.vec1()}; +} +template <> +Vectorized C10_ALWAYS_INLINE fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + return Vectorized{ + a.vec0() * b.vec0() + c.vec0(), a.vec1() * b.vec1() + c.vec1()}; +} + +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(float) +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(double) +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(int64_t) +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(int32_t) +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(int16_t) + +template <> +Vectorized C10_ALWAYS_INLINE +convert_to_int_of_same_size(const Vectorized& src) { + return Vectorized{vec_signed(src.vec0()), vec_signed(src.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE +convert_to_int_of_same_size( + const Vectorized& src) { + return Vectorized{vec_signed(src.vec0()), vec_signed(src.vec1())}; +} + +template <> +inline void convert(const int32_t* src, float* dst, int64_t n) { + // int32_t and float have same size + int64_t i; + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + const int32_t* src_a = src + i; + float* dst_a = dst + i; + vint32 input_vec0 = vec_vsx_ld(offset0, reinterpret_cast(src_a)); + vint32 input_vec1 = + vec_vsx_ld(offset16, reinterpret_cast(src_a)); + vfloat32 c0 = vec_float(input_vec0); + vfloat32 c1 = vec_float(input_vec1); + vec_vsx_st(c0, offset0, dst_a); + vec_vsx_st(c1, offset16, dst_a); + } + + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +template <> +inline void convert(const int64_t* src, double* dst, int64_t n) { + int64_t i; + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + const int64_t* src_a = src + i; + double* dst_a = dst + i; + vint64 input_vec0 = + vec_vsx_ld(offset0, reinterpret_cast(src_a)); + vint64 input_vec1 = + vec_vsx_ld(offset16, reinterpret_cast(src_a)); + vfloat64 c0 = vec_double(input_vec0); + vfloat64 c1 = vec_double(input_vec1); + vec_vsx_st(c0, offset0, reinterpret_cast(dst_a)); + vec_vsx_st(c1, offset16, reinterpret_cast(dst_a)); + } + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} +//Generic implementation to fix compiler error +//TO-DO : Add optimized version for ppc64 +inline std::tuple, Vectorized> convert_half_float( + const Vectorized& a) { + constexpr int64_t K = Vectorized::size(); + __at_align__ float arr[K]; + __at_align__ Half arr2[K]; + a.store(arr2); + convert(arr2, arr, K); + return std::make_tuple( + Vectorized::loadu(arr), + Vectorized::loadu(arr + Vectorized::size())); +} + +inline Vectorized convert_float_half( + const Vectorized& a, const Vectorized& b) { + constexpr int64_t K = Vectorized::size(); + __at_align__ float arr[K]; + __at_align__ Half arr2[K]; + a.store(arr); + b.store(arr + Vectorized::size()); + convert(arr, arr2, K); + return Vectorized::loadu(arr2); +}; + +template <> +std::pair, Vectorized> inline interleave2( + const Vectorized& a, + const Vectorized& b) { + // inputs: + // a = {a0, a1, a2, a3} + // b = {b0, b1, b2, b3} + + vfloat64 ab00 = vec_xxpermdi(a.vec0(), b.vec0(), 0); + vfloat64 ab11 = vec_xxpermdi(a.vec0(), b.vec0(), 3); + vfloat64 ab2_00 = vec_xxpermdi(a.vec1(), b.vec1(), 0); + vfloat64 ab2_11 = vec_xxpermdi(a.vec1(), b.vec1(), 3); + // return {a0, b0, a1, b1} + // {a2, b2, a3, b3} + return std::make_pair( + Vectorized{ab00, ab11}, Vectorized{ab2_00, ab2_11}); +} + +template <> +std::pair, Vectorized> inline deinterleave2( + const Vectorized& a, + const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1} + // b = {a2, b2, a3, b3} + vfloat64 aa01 = vec_xxpermdi(a.vec0(), a.vec1(), 0); + vfloat64 aa23 = vec_xxpermdi(b.vec0(), b.vec1(), 0); + + vfloat64 bb_01 = vec_xxpermdi(a.vec0(), a.vec1(), 3); + vfloat64 bb_23 = vec_xxpermdi(b.vec0(), b.vec1(), 3); + + // swap lanes: + // return {a0, a1, a2, a3} + // {b0, b1, b2, b3} + return std::make_pair( + Vectorized{aa01, aa23}, Vectorized{bb_01, bb_23}); +} + +template <> +std::pair, Vectorized> inline interleave2( + const Vectorized& a, + const Vectorized& b) { + // inputs: + // a = {a0, a1, a2, a3,, a4, a5, a6, a7} + // b = {b0, b1, b2, b3,, b4, b5, b6, b7} + + vfloat32 ab0011 = vec_mergeh(a.vec0(), b.vec0()); + vfloat32 ab2233 = vec_mergel(a.vec0(), b.vec0()); + + vfloat32 ab2_0011 = vec_mergeh(a.vec1(), b.vec1()); + vfloat32 ab2_2233 = vec_mergel(a.vec1(), b.vec1()); + // group cols crossing lanes: + // return {a0, b0, a1, b1,, a2, b2, a3, b3} + // {a4, b4, a5, b5,, a6, b6, a7, b7} + + return std::make_pair( + Vectorized{ab0011, ab2233}, Vectorized{ab2_0011, ab2_2233}); +} + +template <> +std::pair, Vectorized> inline deinterleave2( + const Vectorized& a, + const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1,, a2, b2, a3, b3} + // b = {a4, b4, a5, b5,, a6, b6, a7, b7} + + // {a0,a2,b0,b2} {a1,a3,b1,b3} + vfloat32 a0a2b0b2 = vec_mergeh(a.vec0(), a.vec1()); + vfloat32 a1a3b1b3 = vec_mergel(a.vec0(), a.vec1()); + + vfloat32 aa0123 = vec_mergeh(a0a2b0b2, a1a3b1b3); + vfloat32 bb0123 = vec_mergel(a0a2b0b2, a1a3b1b3); + + vfloat32 a0a2b0b2_2 = vec_mergeh(b.vec0(), b.vec1()); + vfloat32 a1a3b1b3_2 = vec_mergel(b.vec0(), b.vec1()); + + vfloat32 aa0123_2 = vec_mergeh(a0a2b0b2_2, a1a3b1b3_2); + vfloat32 bb0123_2 = vec_mergel(a0a2b0b2_2, a1a3b1b3_2); + + // it could be done with vec_perm ,too + // swap lanes: + // return {a0, a1, a2, a3,, a4, a5, a6, a7} + // {b0, b1, b2, b3,, b4, b5, b6, b7} + + return std::make_pair( + Vectorized{aa0123, aa0123_2}, Vectorized{bb0123, bb0123_2}); +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_complex_double_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_complex_double_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..2c74847758d84e866df7e1c3cc802a6e61cea8d1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_complex_double_vsx.h @@ -0,0 +1,584 @@ +#pragma once +#include +#include +#include +#include +#include + +namespace at { +namespace vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { +using ComplexDbl = c10::complex; + +template <> +class Vectorized { + union { + struct { + vfloat64 _vec0; + vfloat64 _vec1; + }; + struct { + vbool64 _vecb0; + vbool64 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + using value_type = ComplexDbl; + using vec_internal_type = vfloat64; + using vec_internal_mask_type = vbool64; + using size_type = int; + static constexpr size_type size() { + return 2; + } + Vectorized() {} + C10_ALWAYS_INLINE Vectorized(vfloat64 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool64 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vfloat64 v1, vfloat64 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool64 v1, vbool64 v2) : _vecb0{v1}, _vecb1{v2} {} + + Vectorized(ComplexDbl val) { + double real_value = val.real(); + double imag_value = val.imag(); + _vec0 = vfloat64{real_value, imag_value}; + _vec1 = vfloat64{real_value, imag_value}; + } + Vectorized(ComplexDbl val1, ComplexDbl val2) { + _vec0 = vfloat64{val1.real(), val1.imag()}; + _vec1 = vfloat64{val2.real(), val2.imag()}; + } + + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return a; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return b; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return {b._vec0, a._vec1}; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return {a._vec0, b._vec1}; + } + + template + static Vectorized C10_ALWAYS_INLINE + el_blend(const Vectorized& a, const Vectorized& b) { + const vbool64 mask_1st = VsxDblMask1(mask); + const vbool64 mask_2nd = VsxDblMask2(mask); + return { + (vfloat64)vec_sel(a._vec0, b._vec0, mask_1st), + (vfloat64)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + static Vectorized blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // convert std::complex index mask to V index mask: xy -> xxyy + auto mask_complex = + Vectorized(vec_splat(mask._vec0, 0), vec_splat(mask._vec1, 0)); + return { + vec_sel(a._vec0, b._vec0, mask_complex._vecb0), + vec_sel(a._vec1, b._vec1, mask_complex._vecb1)}; + } + + static Vectorized C10_ALWAYS_INLINE elwise_blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + return { + vec_sel(a._vec0, b._vec0, mask._vecb0), + vec_sel(a._vec1, b._vec1, mask._vecb1)}; + } + template + static Vectorized arange( + ComplexDbl base = 0., + step_t step = static_cast(1)) { + return Vectorized(base, base + step); + } + static Vectorized set( + const Vectorized& a, + const Vectorized& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + } + return b; + } + + static Vectorized C10_ALWAYS_INLINE + loadu(const void* ptr, int count = size()) { + if (count == size()) { + return { + vec_vsx_ld(offset0, reinterpret_cast(ptr)), + vec_vsx_ld(offset16, reinterpret_cast(ptr))}; + } + + __at_align__ value_type tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + + return { + vec_vsx_ld(offset0, reinterpret_cast(tmp_values)), + vec_vsx_ld(offset16, reinterpret_cast(tmp_values))}; + } + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + vec_vsx_st(_vec0, offset0, reinterpret_cast(ptr)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(ptr)); + } else if (count > 0) { + __at_align__ value_type tmp_values[size()]; + vec_vsx_st(_vec0, offset0, reinterpret_cast(tmp_values)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(tmp_values)); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + + const ComplexDbl& operator[](int idx) const = delete; + ComplexDbl& operator[](int idx) = delete; + + Vectorized map(ComplexDbl (*const f)(ComplexDbl)) const { + __at_align__ ComplexDbl tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + + Vectorized map(ComplexDbl (*const f)(const ComplexDbl&)) const { + __at_align__ ComplexDbl tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + + Vectorized el_swapped() const { + vfloat64 v0 = vec_xxpermdi(_vec0, _vec0, 2); + vfloat64 v1 = vec_xxpermdi(_vec1, _vec1, 2); + return {v0, v1}; + } + + Vectorized el_madd( + const Vectorized& multiplier, + const Vectorized& val) const { + return { + vec_madd(_vec0, multiplier._vec0, val._vec0), + vec_madd(_vec1, multiplier._vec1, val._vec1)}; + } + + Vectorized el_mergeo() const { + vfloat64 v0 = vec_splat(_vec0, 1); + vfloat64 v1 = vec_splat(_vec1, 1); + return {v0, v1}; + } + + Vectorized el_mergee() const { + vfloat64 v0 = vec_splat(_vec0, 0); + vfloat64 v1 = vec_splat(_vec1, 0); + return {v0, v1}; + } + + static Vectorized el_mergee( + Vectorized& first, + Vectorized& second) { + return { + vec_mergeh(first._vec0, second._vec0), + vec_mergeh(first._vec1, second._vec1)}; + } + + static Vectorized el_mergeo( + Vectorized& first, + Vectorized& second) { + return { + vec_mergel(first._vec0, second._vec0), + vec_mergel(first._vec1, second._vec1)}; + } + + Vectorized abs_2_() const { + auto a = (*this).elwise_mult(*this); + auto permuted = a.el_swapped(); + a = a + permuted; + return a; + } + + Vectorized abs_() const { + auto vi = el_mergeo(); + auto vr = el_mergee(); + return {Sleef_hypotd2_u05vsx(vr._vec0, vi._vec0), Sleef_hypotd2_u05vsx(vr._vec1, vi._vec1)}; + } + + Vectorized abs() const { + return abs_() & vd_real_mask; + } + + Vectorized angle_() const { + // angle = atan2(b/a) + // auto b_a = _mm256_permute_pd(values, 0x05); // b a + // return Sleef_atan2d4_u10(values, b_a); // 90-angle angle + Vectorized ret; + ret._vec0[0] = std::atan2(_vec0[1], _vec0[0]); + ret._vec1[0] = std::atan2(_vec1[1], _vec1[0]); + return ret; + } + + Vectorized angle() const { + return angle_() & vd_real_mask; + } + + Vectorized real_() const { + return *this & vd_real_mask; + } + Vectorized real() const { + return *this & vd_real_mask; + } + Vectorized imag_() const { + return *this & vd_imag_mask; + } + Vectorized imag() const { + return imag_().el_swapped(); + } + + Vectorized conj_() const { + return *this ^ vd_isign_mask; + } + Vectorized conj() const { + return *this ^ vd_isign_mask; + } + + Vectorized log() const { + // Most trigonomic ops use the log() op to improve complex number + // performance. + return map(std::log); + } + + Vectorized log2() const { + // log2eB_inv + auto ret = log(); + return ret.elwise_mult(vd_log2e_inv); + } + Vectorized log10() const { + auto ret = log(); + return ret.elwise_mult(vd_log10e_inv); + } + + Vectorized log1p() const { + return map(std::log1p); + } + + Vectorized asin() const { + // asin(x) + // = -i*ln(iz + sqrt(1 -z^2)) + // = -i*ln((ai - b) + sqrt(1 - (a + bi)*(a + bi))) + // = -i*ln((-b + ai) + sqrt(1 - (a**2 - b**2) - 2*abi)) + auto conj = conj_(); + auto b_a = conj.el_swapped(); + auto ab = conj.elwise_mult(b_a); + auto im = ab + ab; + auto val_2 = (*this).elwise_mult(*this); + auto val_2_swapped = val_2.el_swapped(); + auto re = horizontal_sub(val_2, val_2_swapped); + re = Vectorized(vd_one) - re; + auto root = el_blend<0x0A>(re, im).sqrt(); + auto ln = (b_a + root).log(); + return ln.el_swapped().conj(); + } + + Vectorized acos() const { + // acos(x) = pi/2 - asin(x) + return Vectorized(vd_pi_2) - asin(); + } + + Vectorized atan() const { + // atan(x) = i/2 * ln((i + z)/(i - z)) + auto ione = Vectorized(vd_imag_one); + auto sum = ione + *this; + auto sub = ione - *this; + auto ln = (sum / sub).log(); // ln((i + z)/(i - z)) + return ln * vd_imag_half; // i/2*ln() + } + Vectorized atanh() const { + return map(std::atanh); + } + + Vectorized sin() const { + return map(std::sin); + } + Vectorized sinh() const { + return map(std::sinh); + } + Vectorized cos() const { + return map(std::cos); + } + Vectorized cosh() const { + return map(std::cosh); + } + + Vectorized tan() const { + return map(std::tan); + } + Vectorized tanh() const { + return map(std::tanh); + } + Vectorized ceil() const { + return {vec_ceil(_vec0), vec_ceil(_vec1)}; + } + Vectorized floor() const { + return {vec_floor(_vec0), vec_floor(_vec1)}; + } + Vectorized neg() const { + auto z = Vectorized(vd_zero); + return z - *this; + } + Vectorized round() const { + return {vec_rint(_vec0), vec_rint(_vec1)}; + } + + Vectorized trunc() const { + return {vec_trunc(_vec0), vec_trunc(_vec1)}; + } + + Vectorized elwise_sqrt() const { + return {vec_sqrt(_vec0), vec_sqrt(_vec1)}; + } + + Vectorized sqrt() const { + return map(std::sqrt); + } + + Vectorized reciprocal() const { + // re + im*i = (a + bi) / (c + di) + // re = (ac + bd)/abs_2() = c/abs_2() + // im = (bc - ad)/abs_2() = d/abs_2() + auto c_d = *this ^ vd_isign_mask; // c -d + auto abs = abs_2_(); + return c_d.elwise_div(abs); + } + + Vectorized rsqrt() const { + return sqrt().reciprocal(); + } + + static Vectorized horizontal_add( + Vectorized& first, + Vectorized& second) { + // Operates on individual floats, see _mm_hadd_ps + // {f0+f1, s0+s1, f2+f3, s2+s3, ...} + // i.e. it sums the re and im of each value and interleaves first and second: + // {f_re0 + f_im0, s_re0 + s_im0, f_re1 + f_im1, s_re1 + s_im1, ...} + return el_mergee(first, second) + el_mergeo(first, second); + } + + static Vectorized horizontal_sub( + Vectorized& first, + Vectorized& second) { + // we will simulate it differently with 6 instructions total + // lets permute second so that we can add it getting horizontal sums + auto first_perm = first.el_swapped(); // 2perm + auto second_perm = second.el_swapped(); // 2perm + // summ + auto first_ret = first - first_perm; // 2sub + auto second_ret = second - second_perm; // 2 sub + // now lets choose evens + return el_mergee(first_ret, second_ret); // 2 mergee's + } + + Vectorized inline operator*(const Vectorized& b) const { + //(a + bi) * (c + di) = (ac - bd) + (ad + bc)i +#if 1 + // this is more vsx friendly than simulating horizontal from x86 + auto vi = b.el_mergeo(); + auto vr = b.el_mergee(); + vi = vi ^ vd_rsign_mask; + auto ret = elwise_mult(vr); + auto vx_swapped = el_swapped(); + ret = vx_swapped.el_madd(vi, ret); +#else + auto ac_bd = elwise_mult(b); + auto d_c = b.el_swapped(); + d_c = d_c ^ vd_isign_mask; + auto ad_bc = elwise_mult(d_c); + auto ret = horizontal_sub(ac_bd, ad_bc); +#endif + return ret; + } + + Vectorized inline operator/(const Vectorized& b) const { + // re + im*i = (a + bi) / (c + di) + // re = (ac + bd)/abs_2() + // im = (bc - ad)/abs_2() + auto fabs_cd = Vectorized{ + vec_andc(b._vec0, vd_sign_mask), + vec_andc(b._vec1, vd_sign_mask)}; // |c| |d| + auto fabs_dc = fabs_cd.el_swapped(); // |d| |c| + auto scale = fabs_cd.elwise_max(fabs_dc); // sc = max(|c|, |d|) + auto a2 = elwise_div(scale); // a/sc b/sc + auto b2 = b.elwise_div(scale); // c/sc d/sc + auto acbd2 = a2.elwise_mult(b2); // ac/sc^2 bd/sc^2 + auto dc2 = b2.el_swapped(); // d/sc c/sc + dc2 = dc2 ^ vd_rsign_mask; // -d/sc c/sc + auto adbc2 = a2.elwise_mult(dc2); // -ad/sc^2 bc/sc^2 + auto ret = horizontal_add(acbd2, adbc2); // (ac+bd)/sc^2 (bc-ad)/sc^2 + auto denom2 = b2.abs_2_(); // (c^2+d^2)/sc^2 (c^2+d^2)/sc^2 + ret = ret.elwise_div(denom2); + return ret; + } + + Vectorized exp() const { + return map(std::exp); + } + Vectorized exp2() const { + return map(exp2_impl); + } + Vectorized expm1() const { + return map(std::expm1); + } + + Vectorized pow(const Vectorized& exp) const { + __at_align__ ComplexDbl x_tmp[size()]; + __at_align__ ComplexDbl y_tmp[size()]; + store(x_tmp); + exp.store(y_tmp); + for (const auto i : c10::irange(size())) { + x_tmp[i] = std::pow(x_tmp[i], y_tmp[i]); + } + return loadu(x_tmp); + } + + Vectorized sgn() const { + return map(at::native::sgn_impl); + } + + Vectorized operator<(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized operator<=(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized operator>(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized operator>=(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized eq(const Vectorized& other) const { + auto eq = (*this == other); // compares real and imag individually + // If both real numbers and imag numbers are equal, then the complex numbers are equal + return (eq.real() & eq.imag()) & vd_one; + } + Vectorized ne(const Vectorized& other) const { + auto ne = (*this != other); // compares real and imag individually + // If either real numbers or imag numbers are not equal, then the complex numbers are not equal + return (ne.real() | ne.imag()) & vd_one; + } + + DEFINE_MEMBER_OP(operator==, ComplexDbl, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, ComplexDbl, vec_cmpne) + + DEFINE_MEMBER_OP(operator+, ComplexDbl, vec_add) + DEFINE_MEMBER_OP(operator-, ComplexDbl, vec_sub) + DEFINE_MEMBER_OP(operator&, ComplexDbl, vec_and) + DEFINE_MEMBER_OP(operator|, ComplexDbl, vec_or) + DEFINE_MEMBER_OP(operator^, ComplexDbl, vec_xor) + // elementwise helpers + DEFINE_MEMBER_OP(elwise_mult, ComplexDbl, vec_mul) + DEFINE_MEMBER_OP(elwise_div, ComplexDbl, vec_div) + DEFINE_MEMBER_OP(elwise_gt, ComplexDbl, vec_cmpgt) + DEFINE_MEMBER_OP(elwise_ge, ComplexDbl, vec_cmpge) + DEFINE_MEMBER_OP(elwise_lt, ComplexDbl, vec_cmplt) + DEFINE_MEMBER_OP(elwise_le, ComplexDbl, vec_cmple) + DEFINE_MEMBER_OP(elwise_max, ComplexDbl, vec_max) +}; + +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + // auto mask = _mm256_cmp_ps(abs_a, abs_b, _CMP_LT_OQ); + // auto max = _mm256_blendv_ps(a, b, mask); + auto mask = abs_a.elwise_lt(abs_b); + auto max = Vectorized::elwise_blendv(a, b, mask); + + return max; + // Exploit the fact that all-ones is a NaN. + // auto isnan = _mm256_cmp_ps(abs_a, abs_b, _CMP_UNORD_Q); + // return _mm256_or_ps(max, isnan); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + // auto mask = _mm256_cmp_ps(abs_a, abs_b, _CMP_GT_OQ); + // auto min = _mm256_blendv_ps(a, b, mask); + auto mask = abs_a.elwise_gt(abs_b); + auto min = Vectorized::elwise_blendv(a, b, mask); + return min; + // Exploit the fact that all-ones is a NaN. + // auto isnan = _mm256_cmp_ps(abs_a, abs_b, _CMP_UNORD_Q); + // return _mm256_or_ps(min, isnan); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_complex_float_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_complex_float_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..58fdd34b18d862e843473a684de070167e8a662e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_complex_float_vsx.h @@ -0,0 +1,660 @@ + +#pragma once +#include +#include +#include +#include +#include + +namespace at { +namespace vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { +using ComplexFlt = c10::complex; + +template <> +class Vectorized { + private: + union { + struct { + vfloat32 _vec0; + vfloat32 _vec1; + }; + struct { + vbool32 _vecb0; + vbool32 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + using value_type = ComplexFlt; + using vec_internal_type = vfloat32; + using vec_internal_mask_type = vbool32; + using size_type = int; + + static constexpr size_type size() { + return 4; + } + Vectorized() {} + + C10_ALWAYS_INLINE Vectorized(vfloat32 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool32 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vfloat32 v1, vfloat32 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool32 v1, vbool32 v2) : _vecb0{v1}, _vecb1{v2} {} + + Vectorized(ComplexFlt val) { + float real_value = val.real(); + float imag_value = val.imag(); + _vec0 = vfloat32{real_value, imag_value, real_value, imag_value}; + _vec1 = vfloat32{real_value, imag_value, real_value, imag_value}; + } + + Vectorized(ComplexFlt val1, ComplexFlt val2, ComplexFlt val3, ComplexFlt val4) { + _vec0 = vfloat32{val1.real(), val1.imag(), val2.real(), val2.imag()}; + _vec1 = vfloat32{val3.real(), val3.imag(), val4.real(), val4.imag()}; + } + + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return a; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return b; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return {b._vec0, a._vec1}; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return {a._vec0, b._vec1}; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_1st = VsxComplexMask1(mask); + return {(vfloat32)vec_sel(a._vec0, b._vec0, mask_1st), a._vec1}; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_1st = VsxComplexMask1(mask); + return {(vfloat32)vec_sel(a._vec0, b._vec0, mask_1st), b._vec1}; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_2nd = VsxComplexMask2(mask); + // generated masks + return {a._vec0, (vfloat32)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_2nd = VsxComplexMask2(mask); + // generated masks + return {b._vec0, (vfloat32)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_1st = VsxComplexMask1(mask); + const vbool32 mask_2nd = VsxComplexMask2(mask); + return { + (vfloat32)vec_sel(a._vec0, b._vec0, mask_1st), + (vfloat32)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + template + static Vectorized C10_ALWAYS_INLINE + el_blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_1st = VsxMask1(mask); + const vbool32 mask_2nd = VsxMask2(mask); + return { + (vfloat32)vec_sel(a._vec0, b._vec0, mask_1st), + (vfloat32)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + static Vectorized blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // convert std::complex index mask to V index mask: xy -> xxyy + auto mask_complex = Vectorized( + vec_mergeh(mask._vec0, mask._vec0), vec_mergeh(mask._vec1, mask._vec1)); + return { + vec_sel(a._vec0, b._vec0, reinterpret_cast(mask_complex._vec0)), + vec_sel(a._vec1, b._vec1, reinterpret_cast(mask_complex._vec1)), + }; + } + + static Vectorized elwise_blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + return { + vec_sel(a._vec0, b._vec0, reinterpret_cast(mask._vec0)), + vec_sel(a._vec1, b._vec1, reinterpret_cast(mask._vec1)), + }; + } + + template + static Vectorized arange( + ComplexFlt base = 0., + step_t step = static_cast(1)) { + return Vectorized( + base, + base + step, + base + ComplexFlt(2) * step, + base + ComplexFlt(3) * step); + } + static Vectorized set( + const Vectorized& a, + const Vectorized& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + } + return b; + } + + static Vectorized C10_ALWAYS_INLINE + loadu(const void* ptr, int count = size()) { + if (count == size()) { + return { + vec_vsx_ld(offset0, reinterpret_cast(ptr)), + vec_vsx_ld(offset16, reinterpret_cast(ptr))}; + } + + __at_align__ value_type tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + + return { + vec_vsx_ld(offset0, reinterpret_cast(tmp_values)), + vec_vsx_ld(offset16, reinterpret_cast(tmp_values))}; + } + + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + vec_vsx_st(_vec0, offset0, reinterpret_cast(ptr)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(ptr)); + } else if (count > 0) { + __at_align__ value_type tmp_values[size()]; + vec_vsx_st(_vec0, offset0, reinterpret_cast(tmp_values)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(tmp_values)); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + + const ComplexFlt& operator[](int idx) const = delete; + ComplexFlt& operator[](int idx) = delete; + + Vectorized map(ComplexFlt (*const f)(ComplexFlt)) const { + __at_align__ ComplexFlt tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + + Vectorized map(ComplexFlt (*const f)(const ComplexFlt&)) const { + __at_align__ ComplexFlt tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + + static Vectorized horizontal_add( + Vectorized& first, + Vectorized& second) { + // Operates on individual floats, see _mm_hadd_ps + // {f0+f1, s0+s1, f2+f3, s2+s3, ...} + // i.e. it sums the re and im of each value and interleaves first and second: + // {f_re0 + f_im0, s_re0 + s_im0, f_re1 + f_im1, s_re1 + s_im1, ...} + return el_mergee(first, second) + el_mergeo(first, second); + } + + static Vectorized horizontal_sub_permD8( + Vectorized& first, + Vectorized& second) { + // we will simulate it differently with 6 instructions total + // lets permute second so that we can add it getting horizontal sums + auto first_perm = first.el_swapped(); // 2perm + auto second_perm = second.el_swapped(); // 2perm + // sum + auto first_ret = first - first_perm; // 2sub + auto second_ret = second - second_perm; // 2 sub + // now lets choose evens + return el_mergee(first_ret, second_ret); // 2 mergee's + } + + Vectorized abs_2_() const { + auto a = (*this).elwise_mult(*this); + auto permuted = a.el_swapped(); + a = a + permuted; + return a.el_mergee(); + } + + Vectorized abs_() const { + auto vi = el_mergeo(); + auto vr = el_mergee(); + return {Sleef_hypotf4_u05vsx(vr._vec0, vi._vec0), Sleef_hypotf4_u05vsx(vr._vec1, vi._vec1)}; + } + + Vectorized abs() const { + return abs_() & real_mask; + } + + Vectorized real_() const { + return *this & real_mask; + } + Vectorized real() const { + return *this & real_mask; + } + Vectorized imag_() const { + return *this & imag_mask; + } + Vectorized imag() const { + // we can use swap_mask or sldwi + auto ret = imag_(); + return { + vec_sldw(ret._vec0, ret._vec0, 3), vec_sldw(ret._vec1, ret._vec1, 3)}; + } + + Vectorized conj_() const { + return *this ^ isign_mask; + } + Vectorized conj() const { + return *this ^ isign_mask; + } + + Vectorized log() const { + // Most trigonomic ops use the log() op to improve complex number + // performance. + return map(std::log); + } + + Vectorized log2() const { + // log2eB_inv + auto ret = log(); + return ret.elwise_mult(log2e_inv); + } + Vectorized log10() const { + auto ret = log(); + return ret.elwise_mult(log10e_inv); + } + + Vectorized log1p() const { + return map(std::log1p); + } + + Vectorized el_swapped() const { + vfloat32 v0 = vec_perm(_vec0, _vec0, swap_mask); + vfloat32 v1 = vec_perm(_vec1, _vec1, swap_mask); + return {v0, v1}; + } + + Vectorized el_mergee() const { + // as mergee phased in , we can use vec_perm with mask + return {vec_mergee(_vecb0, _vecb0), vec_mergee(_vecb1, _vecb1)}; + } + + Vectorized el_mergeo() const { + // as mergeo phased in , we can use vec_perm with mask + return {vec_mergeo(_vecb0, _vecb0), vec_mergeo(_vecb1, _vecb1)}; + } + + Vectorized el_madd( + const Vectorized& multiplier, + const Vectorized& val) const { + return { + vec_madd(_vec0, multiplier._vec0, val._vec0), + vec_madd(_vec1, multiplier._vec1, val._vec1)}; + } + + static Vectorized el_mergee( + Vectorized& first, + Vectorized& second) { + return { + vec_mergee(first._vecb0, second._vecb0), + vec_mergee(first._vecb1, second._vecb1)}; + } + + static Vectorized el_mergeo( + Vectorized& first, + Vectorized& second) { + return { + vec_mergeo(first._vecb0, second._vecb0), + vec_mergeo(first._vecb1, second._vecb1)}; + } + + Vectorized angle_() const { + // angle = atan2(b/a) + // auto b_a = _mm256_permute_ps(values, 0xB1); // b a + // return Sleef_atan2f8_u10(values, b_a); // 90-angle angle + Vectorized ret; + for (int i = 0; i < 4; i += 2) { + ret._vec0[i] = std::atan2(_vec0[i + 1], _vec0[i]); + ret._vec1[i] = std::atan2(_vec1[i + 1], _vec1[i]); + } + return ret; + } + + Vectorized angle() const { + return angle_() & real_mask; + } + + Vectorized sin() const { + return map(std::sin); + } + Vectorized sinh() const { + return map(std::sinh); + } + Vectorized cos() const { + return map(std::cos); + } + Vectorized cosh() const { + return map(std::cosh); + } + Vectorized ceil() const { + return {vec_ceil(_vec0), vec_ceil(_vec1)}; + } + Vectorized floor() const { + return {vec_floor(_vec0), vec_floor(_vec1)}; + } + Vectorized neg() const { + auto z = Vectorized(zero); + return z - *this; + } + Vectorized round() const { + return {vec_round(_vec0), vec_round(_vec1)}; + } + Vectorized tan() const { + return map(std::tan); + } + Vectorized tanh() const { + return map(std::tanh); + } + Vectorized trunc() const { + return {vec_trunc(_vec0), vec_trunc(_vec1)}; + } + + Vectorized elwise_sqrt() const { + return {vec_sqrt(_vec0), vec_sqrt(_vec1)}; + } + + Vectorized sqrt() const { + return map(std::sqrt); + } + + Vectorized reciprocal() const { + // re + im*i = (a + bi) / (c + di) + // re = (ac + bd)/abs_2() = c/abs_2() + // im = (bc - ad)/abs_2() = d/abs_2() + auto c_d = *this ^ isign_mask; // c -d + auto abs = abs_2_(); + return c_d.elwise_div(abs); + } + + Vectorized rsqrt() const { + return sqrt().reciprocal(); + } + + Vectorized pow(const Vectorized& exp) const { + __at_align__ ComplexFlt x_tmp[size()]; + __at_align__ ComplexFlt y_tmp[size()]; + store(x_tmp); + exp.store(y_tmp); + for (const auto i : c10::irange(size())) { + x_tmp[i] = std::pow(x_tmp[i], y_tmp[i]); + } + return loadu(x_tmp); + } + + Vectorized atan() const { + // atan(x) = i/2 * ln((i + z)/(i - z)) + auto ione = Vectorized(imag_one); + auto sum = ione + *this; + auto sub = ione - *this; + auto ln = (sum / sub).log(); // ln((i + z)/(i - z)) + return ln * imag_half; // i/2*ln() + } + Vectorized atanh() const { + return map(std::atanh); + } + + Vectorized acos() const { + // acos(x) = pi/2 - asin(x) + return Vectorized(pi_2) - asin(); + } + + Vectorized inline operator*(const Vectorized& b) const { + //(a + bi) * (c + di) = (ac - bd) + (ad + bc)i + +#if 1 + // this is more vsx friendly than simulating horizontal from x86 + + auto vi = b.el_mergeo(); + auto vr = b.el_mergee(); + vi = vi ^ rsign_mask; + auto ret = elwise_mult(vr); + auto vx_swapped = el_swapped(); + ret = vx_swapped.el_madd(vi, ret); + return ret; + +#else + + auto ac_bd = elwise_mult(b); + auto d_c = b.el_swapped(); + d_c = d_c ^ isign_mask; + auto ad_bc = elwise_mult(d_c); + auto ret = horizontal_sub_permD8(ac_bd, ad_bc); + return ret; +#endif + } + + Vectorized inline operator/(const Vectorized& b) const { + // re + im*i = (a + bi) / (c + di) + // re = (ac + bd)/abs_2() + // im = (bc - ad)/abs_2() + auto fabs_cd = Vectorized{ + vec_andc(b._vec0, sign_mask), + vec_andc(b._vec1, sign_mask)}; // |c| |d| + auto fabs_dc = fabs_cd.el_swapped(); // |d| |c| + auto scale = fabs_cd.elwise_max(fabs_dc); // sc = max(|c|, |d|) + auto a2 = elwise_div(scale); // a/sc b/sc + auto b2 = b.elwise_div(scale); // c/sc d/sc + auto acbd2 = a2.elwise_mult(b2); // ac/sc^2 bd/sc^2 + auto dc2 = b2.el_swapped(); // d/sc c/sc + dc2 = dc2 ^ rsign_mask; // -d/sc c/sc + auto adbc2 = a2.elwise_mult(dc2); // -ad/sc^2 bc/sc^2 + auto ret = horizontal_add(acbd2, adbc2); // (ac+bd)/sc^2 (bc-ad)/sc^2 + auto denom2 = b2.abs_2_(); // (c^2+d^2)/sc^2 (c^2+d^2)/sc^2 + ret = ret.elwise_div(denom2); + return ret; + } + + Vectorized asin() const { + // asin(x) + // = -i*ln(iz + sqrt(1 -z^2)) + // = -i*ln((ai - b) + sqrt(1 - (a + bi)*(a + bi))) + // = -i*ln((-b + ai) + sqrt(1 - (a**2 - b**2) - 2*abi)) + +#if 1 + auto conj = conj_(); + auto b_a = conj.el_swapped(); + auto ab = conj.elwise_mult(b_a); + auto im = ab + ab; + auto val_2 = (*this).elwise_mult(*this); + auto val_2_swapped = val_2.el_swapped(); + auto re = horizontal_sub_permD8(val_2, val_2_swapped); + re = Vectorized(one) - re; + auto root = el_blend<0xAA>(re, im).sqrt(); + auto ln = (b_a + root).log(); + return ln.el_swapped().conj(); +#else + return map(std::asin); +#endif + } + + Vectorized exp() const { + return map(std::exp); + } + Vectorized exp2() const { + return map(exp2_impl); + } + Vectorized expm1() const { + return map(std::expm1); + } + + Vectorized eq(const Vectorized& other) const { + auto eq = (*this == other); // compares real and imag individually + // If both real numbers and imag numbers are equal, then the complex numbers are equal + return (eq.real() & eq.imag()) & one; + } + Vectorized ne(const Vectorized& other) const { + auto ne = (*this != other); // compares real and imag individually + // If either real numbers or imag numbers are not equal, then the complex numbers are not equal + return (ne.real() | ne.imag()) & one; + } + + Vectorized sgn() const { + return map(at::native::sgn_impl); + } + + Vectorized operator<(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized operator<=(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized operator>(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized operator>=(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + DEFINE_MEMBER_OP(operator==, ComplexFlt, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, ComplexFlt, vec_cmpne) + + DEFINE_MEMBER_OP(operator+, ComplexFlt, vec_add) + DEFINE_MEMBER_OP(operator-, ComplexFlt, vec_sub) + DEFINE_MEMBER_OP(operator&, ComplexFlt, vec_and) + DEFINE_MEMBER_OP(operator|, ComplexFlt, vec_or) + DEFINE_MEMBER_OP(operator^, ComplexFlt, vec_xor) + // elementwise helpers + DEFINE_MEMBER_OP(elwise_mult, ComplexFlt, vec_mul) + DEFINE_MEMBER_OP(elwise_div, ComplexFlt, vec_div) + DEFINE_MEMBER_OP(elwise_gt, ComplexFlt, vec_cmpgt) + DEFINE_MEMBER_OP(elwise_ge, ComplexFlt, vec_cmpge) + DEFINE_MEMBER_OP(elwise_lt, ComplexFlt, vec_cmplt) + DEFINE_MEMBER_OP(elwise_le, ComplexFlt, vec_cmple) + DEFINE_MEMBER_OP(elwise_max, ComplexFlt, vec_max) +}; + +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + // auto mask = _mm256_cmp_ps(abs_a, abs_b, _CMP_LT_OQ); + // auto max = _mm256_blendv_ps(a, b, mask); + auto mask = abs_a.elwise_lt(abs_b); + auto max = Vectorized::elwise_blendv(a, b, mask); + + return max; + // Exploit the fact that all-ones is a NaN. + // auto isnan = _mm256_cmp_ps(abs_a, abs_b, _CMP_UNORD_Q); + // return _mm256_or_ps(max, isnan); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + // auto mask = _mm256_cmp_ps(abs_a, abs_b, _CMP_GT_OQ); + // auto min = _mm256_blendv_ps(a, b, mask); + auto mask = abs_a.elwise_gt(abs_b); + auto min = Vectorized::elwise_blendv(a, b, mask); + return min; + // Exploit the fact that all-ones is a NaN. + // auto isnan = _mm256_cmp_ps(abs_a, abs_b, _CMP_UNORD_Q); + // return _mm256_or_ps(min, isnan); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_double_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_double_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..ff10618611f9e5ad0c7c8728856b2ffc595d2774 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_double_vsx.h @@ -0,0 +1,480 @@ +#pragma once + +#include +#include +#include +#include + +#include + +namespace at { +namespace vec { + +inline namespace CPU_CAPABILITY { + + +template <> +class Vectorized { + private: + union { + struct { + vfloat64 _vec0; + vfloat64 _vec1; + }; + struct { + vbool64 _vecb0; + vbool64 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + using value_type = double; + using vec_internal_type = vfloat64; + using vec_internal_mask_type = vbool64; + using size_type = int; + static constexpr size_type size() { + return 4; + } + Vectorized() {} + C10_ALWAYS_INLINE Vectorized(vfloat64 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool64 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vfloat64 v1, vfloat64 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool64 v1, vbool64 v2) : _vecb0{v1}, _vecb1{v2} {} + C10_ALWAYS_INLINE Vectorized(double scalar) + : _vec0{vec_splats(scalar)}, _vec1{vec_splats(scalar)} {} + C10_ALWAYS_INLINE Vectorized( + double scalar1, + double scalar2, + double scalar3, + double scalar4) + : _vec0{vfloat64{scalar1, scalar2}}, _vec1{vfloat64{scalar3, scalar4}} {} + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + int zero_mask() const { + auto cmp = (*this == vd_zero); + return (cmp._vecb0[0] & 1) | (cmp._vecb0[1] & 2) | (cmp._vecb1[0] & 4) | + (cmp._vecb1[1] & 8); + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return a; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return b; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return { b._vec0, a._vec1 }; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return { a._vec0, b._vec1 }; + } + + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool64 mask_1st = VsxDblMask1(mask); + return { (vfloat64)vec_sel(a._vec0, b._vec0, mask_1st), a._vec1 }; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool64 mask_1st = VsxDblMask1(mask); + return { (vfloat64)vec_sel(a._vec0, b._vec0, mask_1st), b._vec1 }; + } + + + template + static std::enable_if_t> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + const vbool64 mask_2nd = VsxDblMask2(mask); + // generated masks + return { a._vec0, + (vfloat64)vec_sel(a._vec1, b._vec1, mask_2nd) }; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + const vbool64 mask_2nd = VsxDblMask2(mask); + // generated masks + return { b._vec0, + (vfloat64)vec_sel(a._vec1, b._vec1, mask_2nd) }; + } + + template + static std::enable_if_t> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + const vbool64 mask_1st = VsxDblMask1(mask); + const vbool64 mask_2nd = VsxDblMask2(mask); + return { + (vfloat64)vec_sel(a._vec0, b._vec0, mask_1st), + (vfloat64)vec_sel(a._vec1, b._vec1, mask_2nd) }; + } + + + static Vectorized C10_ALWAYS_INLINE blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // the mask used here returned by comparision of vec256 + + return { + vec_sel(a._vec0, b._vec0, mask._vecb0), + vec_sel(a._vec1, b._vec1, mask._vecb1)}; + } + template + static Vectorized arange(double base = 0., step_t step = static_cast(1)) { + return Vectorized(base, base + step, base + 2 * step, base + 3 * step); + } + + static Vectorized C10_ALWAYS_INLINE + set(const Vectorized& a, const Vectorized& b, size_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + } + + return b; + } + static Vectorized C10_ALWAYS_INLINE + loadu(const void* ptr, int count = size()) { + if (count == size()) { + return { + vec_vsx_ld(offset0, reinterpret_cast(ptr)), + vec_vsx_ld(offset16, reinterpret_cast(ptr))}; + } + + __at_align__ value_type tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + + return {vec_vsx_ld(offset0, tmp_values), vec_vsx_ld(offset16, tmp_values)}; + } + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + vec_vsx_st(_vec0, offset0, reinterpret_cast(ptr)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(ptr)); + } else if (count > 0) { + __at_align__ value_type tmp_values[size()]; + vec_vsx_st(_vec0, offset0, tmp_values); + vec_vsx_st(_vec1, offset16, tmp_values); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + const double& operator[](int idx) const = delete; + double& operator[](int idx) = delete; + Vectorized map(double (*const f)(double)) const { + Vectorized ret; + for (const auto i : c10::irange(size()/2)) { + ret._vec0[i] = f(_vec0[i]); + } + for (const auto i : c10::irange(size()/2)) { + ret._vec1[i] = f(_vec1[i]); + } + return ret; + } + + Vectorized mapbi(double (*const f)(double, double), const Vectorized& other) + const { + Vectorized ret; + for (const auto i : c10::irange(size()/2)) { + ret._vec0[i] = f(_vec0[i], other._vec0[i]); + } + for (const auto i : c10::irange(size()/2)) { + ret._vec1[i] = f(_vec1[i], other._vec1[i]); + } + return ret; + } + Vectorized C10_ALWAYS_INLINE abs() const { + return {vec_abs(_vec0), vec_abs(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE acos() const { + return {Sleef_acosd2_u10(_vec0), Sleef_acosd2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE acosh() const { + return {Sleef_acoshd2_u10(_vec0), Sleef_acoshd2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE asin() const { + return {Sleef_asind2_u10(_vec0), Sleef_asind2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE asinh() const { + return {Sleef_asinhd2_u10(_vec0), Sleef_asinhd2_u10(_vec1)}; + } + Vectorized atan() const { + return {Sleef_atand2_u10(_vec0), Sleef_atand2_u10(_vec1)}; + } + Vectorized atanh() const { + return {Sleef_atanhd2_u10(_vec0), Sleef_atanhd2_u10(_vec1)}; + } + Vectorized atan2(const Vectorized& b) const { + return {Sleef_atan2d2_u10(_vec0, b._vec0), Sleef_atan2d2_u10(_vec1, b._vec1)}; + } + Vectorized copysign(const Vectorized &sign) const { + return {Sleef_copysignd2(_vec0, sign._vec0), Sleef_copysignd2(_vec1, sign._vec1)}; + } + Vectorized erf() const { + return {Sleef_erfd2_u10(_vec0), Sleef_erfd2_u10(_vec1)}; + } + Vectorized erfc() const { + return {Sleef_erfcd2_u15(_vec0), Sleef_erfcd2_u15(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE exp() const { + return {Sleef_expd2_u10(_vec0), Sleef_expd2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE exp2() const { + return {Sleef_exp2d2_u10(_vec0), Sleef_exp2d2_u10(_vec1)}; + } + Vectorized expm1() const { + return {Sleef_expm1d2_u10(_vec0), Sleef_expm1d2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE exp_u20() const { + return exp(); + } + + Vectorized lgamma() const __ubsan_ignore_undefined__ { + return {Sleef_lgammad2_u10(_vec0), Sleef_lgammad2_u10(_vec1)}; + } + + Vectorized erfinv() const { + return map(calc_erfinv); + } + + Vectorized angle() const { + auto tmp = blendv( + Vectorized(0), Vectorized(c10::pi), *this < Vectorized(0)); + return blendv(tmp, *this, isnan()); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return Vectorized{0}; + } + Vectorized conj() const { + return *this; + } + + Vectorized C10_ALWAYS_INLINE log() const { + return {Sleef_logd2_u10(_vec0), Sleef_logd2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE log10() const { + return {Sleef_log10d2_u10(_vec0), Sleef_log10d2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE log1p() const { + return {Sleef_log1pd2_u10(_vec0), Sleef_log1pd2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE log2() const { + return {Sleef_log2d2_u10(_vec0), Sleef_log2d2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE ceil() const { + return {vec_ceil(_vec0), vec_ceil(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE cos() const { + return {Sleef_cosd2_u10(_vec0), Sleef_cosd2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE cosh() const { + return {Sleef_coshd2_u10(_vec0), Sleef_coshd2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE floor() const { + return {vec_floor(_vec0), vec_floor(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE neg() const { + return {vec_neg(_vec0), vec_neg(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE round() const { + return {vec_rint(_vec0), vec_rint(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE sin() const { + return {Sleef_sind2_u10(_vec0), Sleef_sind2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE sinh() const { + return {Sleef_sinhd2_u10(_vec0), Sleef_sinhd2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE tan() const { + return {Sleef_tand2_u10(_vec0), Sleef_tand2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE tanh() const { + return {Sleef_tanhd2_u10(_vec0), Sleef_tanhd2_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE trunc() const { + return {vec_trunc(_vec0), vec_trunc(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE frac() const { + return *this - trunc(); + } + + Vectorized C10_ALWAYS_INLINE sqrt() const { + return {vec_sqrt(_vec0), vec_sqrt(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE reciprocal() const { + return { + vec_div(vd_one, _vec0), // vec_re(_vec0) is estimated one. + vec_div(vd_one, _vec1)}; + } + Vectorized C10_ALWAYS_INLINE rsqrt() const { + return sqrt().reciprocal(); + } + + Vectorized C10_ALWAYS_INLINE pow(const Vectorized& b) const { + return {Sleef_powd2_u10(_vec0, b._vec0), Sleef_powd2_u10(_vec1, b._vec1)}; + } + Vectorized C10_ALWAYS_INLINE fmod(const Vectorized& b) const { + return {Sleef_fmodd2(_vec0, b._vec0),Sleef_fmodd2(_vec1, b._vec1)}; + } + + Vectorized hypot(const Vectorized& b) const { + return {Sleef_hypotd2_u05(_vec0, b._vec0), Sleef_hypotd2_u05(_vec1, b._vec1)}; + } + + Vectorized nextafter(const Vectorized& b) const { + return {Sleef_nextafterd2(_vec0, b._vec0), Sleef_nextafterd2(_vec1, b._vec1)}; + } + + Vectorized igamma(const Vectorized& x) const { + return mapbi(calc_igamma, x); + } + + Vectorized igammac(const Vectorized& x) const { + return mapbi(calc_igammac, x); + } + + + Vectorized i0() const { + return map(calc_i0); + } + + Vectorized i0e() const { + return map(calc_i0e); + } + + Vectorized digamma() const { + return map(calc_digamma); + } + + Vectorized _nor() const { + return {vec_nor(_vec0, _vec0), vec_nor(_vec1, _vec1)}; + } + + Vectorized isnan() const { + auto x = *this; + auto ret = (x == x); + return ret._nor(); + } + bool has_inf_nan() const { + for (const auto i : c10::irange(size()/2)) { + if(_isnan(_vec0[i]) || _isinf(_vec0[i])) { + return true; + } + } + for (const auto i : c10::irange(size()/2)) { + if(_isnan(_vec1[i]) || _isinf(_vec1[i])) { + return true; + } + } + return false; + } + + DEFINE_MEMBER_OP(operator==, double, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, double, vec_cmpne) + DEFINE_MEMBER_OP(operator<, double, vec_cmplt) + DEFINE_MEMBER_OP(operator<=, double, vec_cmple) + DEFINE_MEMBER_OP(operator>, double, vec_cmpgt) + DEFINE_MEMBER_OP(operator>=, double, vec_cmpge) + DEFINE_MEMBER_OP_AND_ONE(eq, double, vec_cmpeq) + DEFINE_MEMBER_OP_AND_ONE(ne, double, vec_cmpne) + DEFINE_MEMBER_OP_AND_ONE(lt, double, vec_cmplt) + DEFINE_MEMBER_OP_AND_ONE(le, double, vec_cmple) + DEFINE_MEMBER_OP_AND_ONE(gt, double, vec_cmpgt) + DEFINE_MEMBER_OP_AND_ONE(ge, double, vec_cmpge) + DEFINE_MEMBER_OP(operator+, double, vec_add) + DEFINE_MEMBER_OP(operator-, double, vec_sub) + DEFINE_MEMBER_OP(operator*, double, vec_mul) + DEFINE_MEMBER_OP(operator/, double, vec_div) + DEFINE_MEMBER_OP(maximum, double, vec_max_nan2) + DEFINE_MEMBER_OP(minimum, double, vec_min_nan2) + DEFINE_MEMBER_OP(operator&, double, vec_and) + DEFINE_MEMBER_OP(operator|, double, vec_or) + DEFINE_MEMBER_OP(operator^, double, vec_xor) + DEFINE_MEMBER_TERNARY_OP(madd, double, vec_madd) +}; +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + return a.minimum(b); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_mul(a.vec0(), b.vec0()), vec_mul(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_div(a.vec0(), b.vec0()), vec_div(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_float_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_float_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..246f0e8a7f1e86eddfec5d3a5f4c2071a197ff47 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_float_vsx.h @@ -0,0 +1,502 @@ +#pragma once + +#include +#include +#include +#include +namespace at { +namespace vec { +// See Note [CPU_CAPABILITY namespace] + +inline namespace CPU_CAPABILITY { + +template <> +class Vectorized { + private: + union { + struct { + vfloat32 _vec0; + vfloat32 _vec1; + }; + struct { + vbool32 _vecb0; + vbool32 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + using value_type = float; + using vec_internal_type = vfloat32; + using vec_internal_mask_type = vbool32; + using size_type = int; + + static constexpr size_type size() { + return 8; + } + Vectorized() {} + + C10_ALWAYS_INLINE Vectorized(vfloat32 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool32 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vfloat32 v1, vfloat32 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool32 v1, vbool32 v2) : _vecb0{v1}, _vecb1{v2} {} + C10_ALWAYS_INLINE Vectorized(float scalar) + : _vec0{vec_splats(scalar)}, _vec1{vec_splats(scalar)} {} + C10_ALWAYS_INLINE Vectorized( + float scalar1, + float scalar2, + float scalar3, + float scalar4, + float scalar5, + float scalar6, + float scalar7, + float scalar8) + : _vec0{vfloat32{scalar1, scalar2, scalar3, scalar4}}, + _vec1{vfloat32{scalar5, scalar6, scalar7, scalar8}} {} + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return a; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return b; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return {b._vec0, a._vec1}; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return {a._vec0, b._vec1}; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_1st = VsxMask1(mask); + return {(vfloat32)vec_sel(a._vec0, b._vec0, mask_1st), a._vec1}; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_1st = VsxMask1(mask); + return {(vfloat32)vec_sel(a._vec0, b._vec0, mask_1st), b._vec1}; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_2nd = VsxMask2(mask); + // generated masks + return {a._vec0, (vfloat32)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_2nd = VsxMask2(mask); + // generated masks + return {b._vec0, (vfloat32)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + const vbool32 mask_1st = VsxMask1(mask); + const vbool32 mask_2nd = VsxMask2(mask); + return { + (vfloat32)vec_sel(a._vec0, b._vec0, mask_1st), + (vfloat32)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + static Vectorized C10_ALWAYS_INLINE blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // the mask used here returned by comparision of vec256 + // assuming this we can use the same mask directly with vec_sel + return { + vec_sel(a._vec0, b._vec0, mask._vecb0), + vec_sel(a._vec1, b._vec1, mask._vecb1)}; + } + + template + static Vectorized arange(float base = 0.f, step_t step = static_cast(1)) { + return Vectorized( + base, + base + step, + base + 2 * step, + base + 3 * step, + base + 4 * step, + base + 5 * step, + base + 6 * step, + base + 7 * step); + } + static Vectorized set( + const Vectorized& a, + const Vectorized& b, + size_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + } + + return b; + } + static Vectorized C10_ALWAYS_INLINE + loadu(const void* ptr, int count = size()) { + if (count == size()) { + return { + vec_vsx_ld(offset0, reinterpret_cast(ptr)), + vec_vsx_ld(offset16, reinterpret_cast(ptr))}; + } + + __at_align__ value_type tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + + return {vec_vsx_ld(offset0, tmp_values), vec_vsx_ld(offset16, tmp_values)}; + } + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + vec_vsx_st(_vec0, offset0, reinterpret_cast(ptr)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(ptr)); + } else if (count > 0) { + __at_align__ value_type tmp_values[size()]; + vec_vsx_st(_vec0, offset0, tmp_values); + vec_vsx_st(_vec1, offset16, tmp_values); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + + const float& operator[](int idx) const = delete; + float& operator[](int idx) = delete; + + Vectorized map(float (*const f)(float)) const { + Vectorized ret; + for (int i = 0; i < size() / 2; i++) { + ret._vec0[i] = f(_vec0[i]); + } + for (int i = 0; i < size() / 2; i++) { + ret._vec1[i] = f(_vec1[i]); + } + return ret; + } + + Vectorized mapbi(float (*const f)(float, float), const Vectorized& other) + const { + Vectorized ret; + for (int i = 0; i < size() / 2; i++) { + ret._vec0[i] = f(_vec0[i], other._vec0[i]); + } + for (int i = 0; i < size() / 2; i++) { + ret._vec1[i] = f(_vec1[i], other._vec1[i]); + } + return ret; + } + + Vectorized _nor() const { + return {vec_nor(_vec0, _vec0), vec_nor(_vec1, _vec1)}; + } + + Vectorized isnan() const { + auto x = *this; + auto ret = (x == x); + return ret._nor(); + } + + bool has_inf_nan() const { + for (const auto i : c10::irange(size()/2)) { + if(_isnan(_vec0[i]) || _isinf(_vec0[i])) { + return true; + } + } + for (const auto i : c10::irange(size()/2)) { + if(_isnan(_vec1[i]) || _isinf(_vec1[i])) { + return true; + } + } + return false; + } + + int zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit + // and others are translated to 0-bit + //__m256 cmp = _mm256_cmp_ps(values, _mm256_set1_ps(0.0f), _CMP_EQ_OQ); + auto cmp = (*this == zero); + // return _mm256_movemask_ps(cmp); + // possible simulation //mask= lvsl ( 0 ) vbpermq( vec, mask <<5) + vuint64 result0 = vec_vbpermq((vuint8)cmp._vecb0, mask_zero_bits); + vuint64 result1 = vec_vbpermq((vuint8)cmp._vecb1, mask_zero_bits); + return (result0[1] >> 12 | (result1[1] >> 8)); + } + + Vectorized C10_ALWAYS_INLINE abs() const { + return {vec_abs(_vec0), vec_abs(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE acos() const { + return {Sleef_acosf4_u10(_vec0), Sleef_acosf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE acosh() const { + return {Sleef_acoshf4_u10(_vec0), Sleef_acoshf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE asin() const { + return {Sleef_asinf4_u10(_vec0), Sleef_asinf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE asinh() const { + return {Sleef_asinhf4_u10(_vec0), Sleef_asinhf4_u10(_vec1)}; + } + Vectorized atan() const { + return {Sleef_atanf4_u10(_vec0), Sleef_atanf4_u10(_vec1)}; + } + Vectorized atanh() const { + return {Sleef_atanhf4_u10(_vec0), Sleef_atanhf4_u10(_vec1)}; + } + Vectorized atan2(const Vectorized& b) const { + return {Sleef_atan2f4_u10(_vec0, b._vec0), Sleef_atan2f4_u10(_vec1, b._vec1)}; + } + Vectorized copysign(const Vectorized &sign) const { + return {Sleef_copysignf4(_vec0, sign._vec0), Sleef_copysignf4(_vec1, sign._vec1)}; + } + Vectorized lgamma() const { + return {Sleef_lgammaf4_u10(_vec0), Sleef_lgammaf4_u10(_vec1)}; + } + Vectorized erf() const { + return {Sleef_erff4_u10(_vec0), Sleef_erff4_u10(_vec1)}; + } + + Vectorized erfc() const { + return {Sleef_erfcf4_u15(_vec0), Sleef_erfcf4_u15(_vec1)}; + } + + Vectorized erfinv() const { + return map(calc_erfinv); + } + + Vectorized angle() const { + auto tmp = blendv( + Vectorized(0), Vectorized(c10::pi), *this < Vectorized(0)); + return blendv(tmp, *this, isnan()); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return Vectorized{0}; + } + Vectorized conj() const { + return *this; + } + + Vectorized C10_ALWAYS_INLINE exp() const { + return {Sleef_expf4_u10(_vec0), Sleef_expf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE exp2() const { + return {Sleef_exp2f4_u10(_vec0), Sleef_exp2f4_u10(_vec1)}; + } + Vectorized expm1() const { + return {Sleef_expm1f4_u10(_vec0), Sleef_expm1f4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE exp_u20() const { + return exp(); + } + + Vectorized C10_ALWAYS_INLINE log() const { + return {Sleef_logf4_u10(_vec0), Sleef_logf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE log10() const { + return {Sleef_log10f4_u10(_vec0), Sleef_log10f4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE log1p() const { + return {Sleef_log1pf4_u10(_vec0), Sleef_log1pf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE log2() const { + return {Sleef_log2f4_u10(_vec0), Sleef_log2f4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE ceil() const { + return {vec_ceil(_vec0), vec_ceil(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE cos() const { + return {Sleef_cosf4_u10(_vec0), Sleef_cosf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE cosh() const { + return {Sleef_coshf4_u10(_vec0), Sleef_coshf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE floor() const { + return {vec_floor(_vec0), vec_floor(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE neg() const { + return {vec_neg(_vec0), vec_neg(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE round() const { + return {vec_round(_vec0), vec_round(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE sin() const { + return {Sleef_sinf4_u10(_vec0), Sleef_sinf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE sinh() const { + return {Sleef_sinhf4_u10(_vec0), Sleef_sinhf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE tan() const { + return {Sleef_tanf4_u10(_vec0), Sleef_tanf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE tanh() const { + return {Sleef_tanhf4_u10(_vec0), Sleef_tanhf4_u10(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE trunc() const { + return {vec_trunc(_vec0), vec_trunc(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE frac() const { + return *this - trunc(); + } + + Vectorized C10_ALWAYS_INLINE sqrt() const { + return {vec_sqrt(_vec0), vec_sqrt(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE reciprocal() const { + return Vectorized(one) / (*this); + } + Vectorized C10_ALWAYS_INLINE rsqrt() const { + return sqrt().reciprocal(); + } + + Vectorized C10_ALWAYS_INLINE pow(const Vectorized& exp) const { + return {Sleef_powf4_u10(_vec0, exp._vec0), Sleef_powf4_u10(_vec1, exp._vec1)}; + } + + Vectorized fmod(const Vectorized& b) const { + return {Sleef_fmodf4(_vec0, b._vec0),Sleef_fmodf4(_vec1, b._vec1)}; + } + + Vectorized hypot(const Vectorized& b) const { + return {Sleef_hypotf4_u05(_vec0, b._vec0), Sleef_hypotf4_u05(_vec1, b._vec1)}; + } + + Vectorized nextafter(const Vectorized& b) const { + return {Sleef_nextafterf4(_vec0, b._vec0), Sleef_nextafterf4(_vec1, b._vec1)}; + } + + Vectorized igamma(const Vectorized& x) const { + return mapbi(calc_igamma, x); + } + + Vectorized igammac(const Vectorized& x) const { + return mapbi(calc_igammac, x); + } + + Vectorized i0() const { + return map(calc_i0); + } + + Vectorized i0e() const { + return map(calc_i0e); + } + + Vectorized digamma() const { + return map(calc_digamma); + } + + DEFINE_MEMBER_OP(operator==, float, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, float, vec_cmpne) + DEFINE_MEMBER_OP(operator<, float, vec_cmplt) + DEFINE_MEMBER_OP(operator<=, float, vec_cmple) + DEFINE_MEMBER_OP(operator>, float, vec_cmpgt) + DEFINE_MEMBER_OP(operator>=, float, vec_cmpge) + DEFINE_MEMBER_OP_AND_ONE(eq, float, vec_cmpeq) + DEFINE_MEMBER_OP_AND_ONE(ne, float, vec_cmpne) + DEFINE_MEMBER_OP_AND_ONE(lt, float, vec_cmplt) + DEFINE_MEMBER_OP_AND_ONE(le, float, vec_cmple) + DEFINE_MEMBER_OP_AND_ONE(gt, float, vec_cmpgt) + DEFINE_MEMBER_OP_AND_ONE(ge, float, vec_cmpge) + DEFINE_MEMBER_OP(operator+, float, vec_add) + DEFINE_MEMBER_OP(operator-, float, vec_sub) + DEFINE_MEMBER_OP(operator*, float, vec_mul) + DEFINE_MEMBER_OP(operator/, float, vec_div) + DEFINE_MEMBER_OP(maximum, float, vec_max_nan2) + DEFINE_MEMBER_OP(minimum, float, vec_min_nan2) + DEFINE_MEMBER_OP(operator&, float, vec_and) + DEFINE_MEMBER_OP(operator|, float, vec_or) + DEFINE_MEMBER_OP(operator^, float, vec_xor) + DEFINE_MEMBER_TERNARY_OP(madd, float, vec_madd) +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return a.minimum(b); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_mul(a.vec0(), b.vec0()), vec_mul(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_div(a.vec0(), b.vec0()), vec_div(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_int16_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_int16_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..ae146dae4d42a50bbe733ee22b0c88c0a13569eb --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_int16_vsx.h @@ -0,0 +1,402 @@ +#pragma once + +#include +#include +#include +namespace at { +namespace vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +template <> +class Vectorized { + private: + union { + struct { + vint16 _vec0; + vint16 _vec1; + }; + struct { + vbool16 _vecb0; + vbool16 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + using value_type = int16_t; + using vec_internal_type = vint16; + using vec_internal_mask_type = vbool16; + using size_type = int; + static constexpr size_type size() { + return 16; + } + Vectorized() {} + C10_ALWAYS_INLINE Vectorized(vint16 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool16 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vint16 v1, vint16 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool16 v1, vbool16 v2) : _vecb0{v1}, _vecb1{v2} {} + C10_ALWAYS_INLINE Vectorized(int16_t scalar) + : _vec0{vec_splats(scalar)}, _vec1{vec_splats(scalar)} {} + + C10_ALWAYS_INLINE Vectorized( + int16_t scalar1, + int16_t scalar2, + int16_t scalar3, + int16_t scalar4, + int16_t scalar5, + int16_t scalar6, + int16_t scalar7, + int16_t scalar8, + int16_t scalar9, + int16_t scalar10, + int16_t scalar11, + int16_t scalar12, + int16_t scalar13, + int16_t scalar14, + int16_t scalar15, + int16_t scalar16) + : _vec0{vint16{ + scalar1, + scalar2, + scalar3, + scalar4, + scalar5, + scalar6, + scalar7, + scalar8}}, + _vec1{vint16{ + scalar9, + scalar10, + scalar11, + scalar12, + scalar13, + scalar14, + scalar15, + scalar16}} {} + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return a; + } + + template + static std::enable_if_t<(mask & 65535) == 65535, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + return b; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return {b._vec0, a._vec1}; + } + + template + static std::enable_if_t<(mask > 0 && mask < 255), Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr int16_t g0 = (mask & 1) * 0xffff; + constexpr int16_t g1 = ((mask & 2) >> 1) * 0xffff; + constexpr int16_t g2 = ((mask & 4) >> 2) * 0xffff; + constexpr int16_t g3 = ((mask & 8) >> 3) * 0xffff; + constexpr int16_t g4 = ((mask & 16) >> 4) * 0xffff; + constexpr int16_t g5 = ((mask & 32) >> 5) * 0xffff; + constexpr int16_t g6 = ((mask & 64) >> 6) * 0xffff; + constexpr int16_t g7 = ((mask & 128) >> 7) * 0xffff; + const vint16 mask_1st = vint16{g0, g1, g2, g3, g4, g5, g6, g7}; + + return {(vint16)vec_sel(a._vec0, b._vec0, (vbool16)mask_1st), a._vec1}; + } + + template + static std::enable_if_t< + (mask > 255 && (mask & 65535) != 65535 && ((mask & 255) == 255)), + Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr int16_t g0_2 = (mask & 1) * 0xffff; + constexpr int16_t g1_2 = ((mask & 2) >> 1) * 0xffff; + constexpr int16_t g2_2 = ((mask & 4) >> 2) * 0xffff; + constexpr int16_t g3_2 = ((mask & 8) >> 3) * 0xffff; + constexpr int16_t g4_2 = ((mask & 16) >> 4) * 0xffff; + constexpr int16_t g5_2 = ((mask & 32) >> 5) * 0xffff; + constexpr int16_t g6_2 = ((mask & 64) >> 6) * 0xffff; + constexpr int16_t g7_2 = ((mask & 128) >> 7) * 0xffff; + + const vint16 mask_2nd = + vint16{g0_2, g1_2, g2_2, g3_2, g4_2, g5_2, g6_2, g7_2}; + // generated masks + return {b._vec0, (vint16)vec_sel(a._vec1, b._vec1, (vbool16)mask_2nd)}; + } + + template + static std::enable_if_t< + (mask > 255 && ((mask & 65535) != 65535) && ((mask & 255) == 0)), + Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr int16_t mask2 = (mask & 65535) >> 16; + constexpr int16_t g0_2 = (mask & 1) * 0xffff; + constexpr int16_t g1_2 = ((mask & 2) >> 1) * 0xffff; + constexpr int16_t g2_2 = ((mask & 4) >> 2) * 0xffff; + constexpr int16_t g3_2 = ((mask & 8) >> 3) * 0xffff; + constexpr int16_t g4_2 = ((mask & 16) >> 4) * 0xffff; + constexpr int16_t g5_2 = ((mask & 32) >> 5) * 0xffff; + constexpr int16_t g6_2 = ((mask & 64) >> 6) * 0xffff; + constexpr int16_t g7_2 = ((mask & 128) >> 7) * 0xffff; + + const vint16 mask_2nd = + vint16{g0_2, g1_2, g2_2, g3_2, g4_2, g5_2, g6_2, g7_2}; + // generated masks + return {a, (vint16)vec_sel(a._vec1, b._vec1, (vbool16)mask_2nd)}; + } + + template + static std::enable_if_t< + (mask > 255 && ((mask & 65535) != 65535) && ((mask & 255) != 0) && + ((mask & 255) != 255)), + Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr int16_t g0 = (mask & 1) * 0xffff; + constexpr int16_t g1 = ((mask & 2) >> 1) * 0xffff; + constexpr int16_t g2 = ((mask & 4) >> 2) * 0xffff; + constexpr int16_t g3 = ((mask & 8) >> 3) * 0xffff; + constexpr int16_t g4 = ((mask & 16) >> 4) * 0xffff; + constexpr int16_t g5 = ((mask & 32) >> 5) * 0xffff; + constexpr int16_t g6 = ((mask & 64) >> 6) * 0xffff; + constexpr int16_t g7 = ((mask & 128) >> 7) * 0xffff; + constexpr int16_t mask2 = (mask & 65535) >> 16; + constexpr int16_t g0_2 = (mask & 1) * 0xffff; + constexpr int16_t g1_2 = ((mask & 2) >> 1) * 0xffff; + constexpr int16_t g2_2 = ((mask & 4) >> 2) * 0xffff; + constexpr int16_t g3_2 = ((mask & 8) >> 3) * 0xffff; + constexpr int16_t g4_2 = ((mask & 16) >> 4) * 0xffff; + constexpr int16_t g5_2 = ((mask & 32) >> 5) * 0xffff; + constexpr int16_t g6_2 = ((mask & 64) >> 6) * 0xffff; + constexpr int16_t g7_2 = ((mask & 128) >> 7) * 0xffff; + + const vint16 mask_1st = vint16{g0, g1, g2, g3, g4, g5, g6, g7}; + const vint16 mask_2nd = + vint16{g0_2, g1_2, g2_2, g3_2, g4_2, g5_2, g6_2, g7_2}; + // generated masks + return { + (vint16)vec_sel(a._vec0, b._vec0, (vbool16)mask_1st), + (vint16)vec_sel(a._vec1, b._vec1, (vbool16)mask_2nd)}; + } + + static Vectorized C10_ALWAYS_INLINE blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // the mask used here returned by comparision of vec256 + // assuming this we can use the same mask directly with vec_sel + // warning intel style mask will not work properly + return { + vec_sel(a._vec0, b._vec0, mask._vecb0), + vec_sel(a._vec1, b._vec1, mask._vecb1)}; + } + + template + static Vectorized arange(int16_t base = 0, step_t step = static_cast(1)) { + return Vectorized( + base, + base + step, + base + 2 * step, + base + 3 * step, + base + 4 * step, + base + 5 * step, + base + 6 * step, + base + 7 * step, + base + 8 * step, + base + 9 * step, + base + 10 * step, + base + 11 * step, + base + 12 * step, + base + 13 * step, + base + 14 * step, + base + 15 * step); + } + static Vectorized set( + const Vectorized& a, + const Vectorized& b, + size_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + case 8: + return blend<255>(a, b); + case 9: + return blend<511>(a, b); + case 10: + return blend<1023>(a, b); + case 11: + return blend<2047>(a, b); + case 12: + return blend<4095>(a, b); + case 13: + return blend<8191>(a, b); + case 14: + return blend<16383>(a, b); + case 15: + return blend<32767>(a, b); + } + return b; + } + static Vectorized C10_ALWAYS_INLINE + loadu(const void* ptr, int count = size()) { + if (count == size()) { + return { + vec_vsx_ld(offset0, reinterpret_cast(ptr)), + vec_vsx_ld(offset16, reinterpret_cast(ptr))}; + } + + __at_align__ value_type tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + + return {vec_vsx_ld(offset0, tmp_values), vec_vsx_ld(offset16, tmp_values)}; + } + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + vec_vsx_st(_vec0, offset0, reinterpret_cast(ptr)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(ptr)); + } else if (count > 0) { + __at_align__ value_type tmp_values[size()]; + vec_vsx_st(_vec0, offset0, tmp_values); + vec_vsx_st(_vec1, offset16, tmp_values); + std::memcpy(ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + const int16_t& operator[](int idx) const = delete; + int16_t& operator[](int idx) = delete; + + Vectorized angle() const { + return blendv( + Vectorized(0), Vectorized(c10::pi), *this < Vectorized(0)); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return Vectorized{0}; + } + Vectorized conj() const { + return *this; + } + + Vectorized C10_ALWAYS_INLINE abs() const { + return {vec_abs(_vec0), vec_abs(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE neg() const { + return {vec_neg(_vec0), vec_neg(_vec1)}; + } + + DEFINE_MEMBER_UNARY_OP(operator~, int16_t, vec_not) + DEFINE_MEMBER_OP(operator==, int16_t, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, int16_t, vec_cmpne) + DEFINE_MEMBER_OP(operator<, int16_t, vec_cmplt) + DEFINE_MEMBER_OP(operator<=, int16_t, vec_cmple) + DEFINE_MEMBER_OP(operator>, int16_t, vec_cmpgt) + DEFINE_MEMBER_OP(operator>=, int16_t, vec_cmpge) + DEFINE_MEMBER_OP_AND_ONE(eq, int16_t, vec_cmpeq) + DEFINE_MEMBER_OP_AND_ONE(ne, int16_t, vec_cmpne) + DEFINE_MEMBER_OP_AND_ONE(lt, int16_t, vec_cmplt) + DEFINE_MEMBER_OP_AND_ONE(le, int16_t, vec_cmple) + DEFINE_MEMBER_OP_AND_ONE(gt, int16_t, vec_cmpgt) + DEFINE_MEMBER_OP_AND_ONE(ge, int16_t, vec_cmpge) + DEFINE_MEMBER_OP(operator+, int16_t, vec_add) + DEFINE_MEMBER_OP(operator-, int16_t, vec_sub) + DEFINE_MEMBER_OP(operator*, int16_t, vec_mul) + DEFINE_MEMBER_EMULATE_BINARY_OP(operator/, int16_t, /) + DEFINE_MEMBER_OP(maximum, int16_t, vec_max) + DEFINE_MEMBER_OP(minimum, int16_t, vec_min) + DEFINE_MEMBER_OP(operator&, int16_t, vec_and) + DEFINE_MEMBER_OP(operator|, int16_t, vec_or) + DEFINE_MEMBER_OP(operator^, int16_t, vec_xor) +}; + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + vuint16 shift_vec0 = reinterpret_cast(b.vec0()); + vuint16 shift_vec1 = reinterpret_cast(b.vec1()); + return Vectorized{vec_sl(a.vec0(), shift_vec0), vec_sl(a.vec1(), shift_vec1)}; +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + vuint16 shift_vec0 = reinterpret_cast(b.vec0()); + vuint16 shift_vec1 = reinterpret_cast(b.vec1()) ; + return Vectorized{vec_sr(a.vec0(), shift_vec0), vec_sr(a.vec1(), shift_vec1)}; +} + +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + return a.minimum(b); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_mul(a.vec0(), b.vec0()), vec_mul(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { + return Vectorized{a.vec0()/b.vec0(), a.vec1()/b.vec1()}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_int32_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_int32_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..98401381c6e822ff571949bb602e501240114e18 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_int32_vsx.h @@ -0,0 +1,333 @@ +#pragma once + +#include +#include +#include +namespace at { +namespace vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +template <> +class Vectorized { + private: + union { + struct { + vint32 _vec0; + vint32 _vec1; + }; + struct { + vbool32 _vecb0; + vbool32 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + using value_type = int32_t; + using vec_internal_type = vint32; + using vec_internal_mask_type = vbool32; + using size_type = int; + static constexpr size_type size() { + return 8; + } + Vectorized() {} + C10_ALWAYS_INLINE Vectorized(vint32 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool32 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vint32 v1, vint32 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool32 v1, vbool32 v2) : _vecb0{v1}, _vecb1{v2} {} + C10_ALWAYS_INLINE Vectorized(int32_t scalar) + : _vec0{vec_splats(scalar)}, _vec1{vec_splats(scalar)} {} + C10_ALWAYS_INLINE Vectorized( + int32_t scalar1, + int32_t scalar2, + int32_t scalar3, + int32_t scalar4, + int32_t scalar5, + int32_t scalar6, + int32_t scalar7, + int32_t scalar8) + : _vec0{vint32{scalar1, scalar2, scalar3, scalar4}}, + _vec1{vint32{scalar5, scalar6, scalar7, scalar8}} {} + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return a; + } + + template + static std::enable_if_t<(mask & 255) == 255, Vectorized> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return b; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return {b._vec0, a._vec1}; + } + + template + static std::enable_if_t<(mask > 0 && mask < 15), Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr uint32_t g0 = (mask & 1) * 0xffffffff; + constexpr uint32_t g1 = ((mask & 2) >> 1) * 0xffffffff; + constexpr uint32_t g2 = ((mask & 4) >> 2) * 0xffffffff; + constexpr uint32_t g3 = ((mask & 8) >> 3) * 0xffffffff; + const vbool32 mask_1st = (vbool32){g0, g1, g2, g3}; + + return {(vint32)vec_sel(a._vec0, b._vec0, (vbool32)mask_1st), a._vec1}; + } + + template + static std::enable_if_t< + (mask > 15 && (mask & 255) != 255 && ((mask & 15) == 15)), + Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr uint32_t mask2 = (mask & 255) >> 4; + constexpr uint32_t g0_2 = (mask2 & 1) * 0xffffffff; + constexpr uint32_t g1_2 = ((mask2 & 2) >> 1) * 0xffffffff; + constexpr uint32_t g2_2 = ((mask2 & 4) >> 2) * 0xffffffff; + constexpr uint32_t g3_2 = ((mask2 & 8) >> 3) * 0xffffffff; + + const vbool32 mask_2nd = (vbool32){g0_2, g1_2, g2_2, g3_2}; + // generated masks + return {b._vec0, (vint32)vec_sel(a._vec1, b._vec1, (vbool32)mask_2nd)}; + } + + template + static std::enable_if_t< + (mask > 15 && ((mask & 255) != 255) && ((mask & 15) == 0)), + Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr uint32_t mask2 = (mask & 255) >> 4; + constexpr uint32_t g0_2 = (mask2 & 1) * 0xffffffff; + constexpr uint32_t g1_2 = ((mask2 & 2) >> 1) * 0xffffffff; + constexpr uint32_t g2_2 = ((mask2 & 4) >> 2) * 0xffffffff; + constexpr uint32_t g3_2 = ((mask2 & 8) >> 3) * 0xffffffff; + + const vbool32 mask_2nd = (vbool32){g0_2, g1_2, g2_2, g3_2}; + // generated masks + return {a, (vint32)vec_sel(a._vec1, b._vec1, (vbool32)mask_2nd)}; + } + + template + static std::enable_if_t< + (mask > 15 && ((mask & 255) != 255) && ((mask & 15) != 0) && + ((mask & 15) != 15)), + Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr uint32_t g0 = (mask & 1) * 0xffffffff; + constexpr uint32_t g1 = ((mask & 2) >> 1) * 0xffffffff; + constexpr uint32_t g2 = ((mask & 4) >> 2) * 0xffffffff; + constexpr uint32_t g3 = ((mask & 8) >> 3) * 0xffffffff; + constexpr uint32_t mask2 = (mask & 255) >> 4; + constexpr uint32_t g0_2 = (mask2 & 1) * 0xffffffff; + constexpr uint32_t g1_2 = ((mask2 & 2) >> 1) * 0xffffffff; + constexpr uint32_t g2_2 = ((mask2 & 4) >> 2) * 0xffffffff; + constexpr uint32_t g3_2 = ((mask2 & 8) >> 3) * 0xffffffff; + + const vbool32 mask_1st = (vbool32){g0, g1, g2, g3}; + const vbool32 mask_2nd = (vbool32){g0_2, g1_2, g2_2, g3_2}; + // generated masks + return { + (vint32)vec_sel(a._vec0, b._vec0, (vbool32)mask_1st), + (vint32)vec_sel(a._vec1, b._vec1, (vbool32)mask_2nd)}; + } + + static Vectorized C10_ALWAYS_INLINE blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // the mask used here returned by comparision of vec256 + // assuming this we can use the same mask directly with vec_sel + // warning intel style mask will not work properly + return { + vec_sel(a._vec0, b._vec0, mask._vecb0), + vec_sel(a._vec1, b._vec1, mask._vecb1)}; + } + + template + static Vectorized arange(int32_t base = 0.f, step_t step = static_cast(1)) { + return Vectorized( + base, + base + step, + base + 2 * step, + base + 3 * step, + base + 4 * step, + base + 5 * step, + base + 6 * step, + base + 7 * step); + } + static Vectorized set( + const Vectorized& a, + const Vectorized& b, + size_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + } + + return b; + } + static Vectorized C10_ALWAYS_INLINE + loadu(const void* ptr, int count = size()) { + if (count == size()) { + return { + vec_vsx_ld(offset0, reinterpret_cast(ptr)), + vec_vsx_ld(offset16, reinterpret_cast(ptr))}; + } + + __at_align__ value_type tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + + return {vec_vsx_ld(offset0, tmp_values), vec_vsx_ld(offset16, tmp_values)}; + } + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + vec_vsx_st(_vec0, offset0, reinterpret_cast(ptr)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(ptr)); + } else if (count > 0) { + __at_align__ value_type tmp_values[size()]; + vec_vsx_st(_vec0, offset0, tmp_values); + vec_vsx_st(_vec1, offset16, tmp_values); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + const int32_t& operator[](int idx) const = delete; + int32_t& operator[](int idx) = delete; + + Vectorized angle() const { + return blendv( + Vectorized(0), Vectorized(c10::pi), *this < Vectorized(0)); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return Vectorized{0}; + } + Vectorized conj() const { + return *this; + } + + Vectorized C10_ALWAYS_INLINE abs() const { + return {vec_abs(_vec0), vec_abs(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE neg() const { + return {vec_neg(_vec0), vec_neg(_vec1)}; + } + + DEFINE_MEMBER_UNARY_OP(operator~, int32_t, vec_not) + DEFINE_MEMBER_OP(operator==, int32_t, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, int32_t, vec_cmpne) + DEFINE_MEMBER_OP(operator<, int32_t, vec_cmplt) + DEFINE_MEMBER_OP(operator<=, int32_t, vec_cmple) + DEFINE_MEMBER_OP(operator>, int32_t, vec_cmpgt) + DEFINE_MEMBER_OP(operator>=, int32_t, vec_cmpge) + DEFINE_MEMBER_OP_AND_ONE(eq, int32_t, vec_cmpeq) + DEFINE_MEMBER_OP_AND_ONE(ne, int32_t, vec_cmpne) + DEFINE_MEMBER_OP_AND_ONE(lt, int32_t, vec_cmplt) + DEFINE_MEMBER_OP_AND_ONE(le, int32_t, vec_cmple) + DEFINE_MEMBER_OP_AND_ONE(gt, int32_t, vec_cmpgt) + DEFINE_MEMBER_OP_AND_ONE(ge, int32_t, vec_cmpge) + DEFINE_MEMBER_OP(operator+, int32_t, vec_add) + DEFINE_MEMBER_OP(operator-, int32_t, vec_sub) + DEFINE_MEMBER_OP(operator*, int32_t, vec_mul) + DEFINE_MEMBER_EMULATE_BINARY_OP(operator/, int32_t, /) + DEFINE_MEMBER_OP(maximum, int32_t, vec_max) + DEFINE_MEMBER_OP(minimum, int32_t, vec_min) + DEFINE_MEMBER_OP(operator&, int32_t, vec_and) + DEFINE_MEMBER_OP(operator|, int32_t, vec_or) + DEFINE_MEMBER_OP(operator^, int32_t, vec_xor) +}; + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + vuint32 shift_vec0 = reinterpret_cast(b.vec0()); + vuint32 shift_vec1 = reinterpret_cast(b.vec1()) ; + return Vectorized{vec_sl(a.vec0(), shift_vec0), vec_sl(a.vec1(), shift_vec1)}; +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + vuint32 shift_vec0 = reinterpret_cast(b.vec0()); + vuint32 shift_vec1 = reinterpret_cast(b.vec1()) ; + return Vectorized{vec_sr(a.vec0(), shift_vec0), vec_sr(a.vec1(), shift_vec1)}; +} + +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + return a.minimum(b); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_mul(a.vec0(), b.vec0()), vec_mul(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { + return Vectorized{a.vec0()/b.vec0(), a.vec1()/b.vec1()}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_int64_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_int64_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..f8217930fa4989586ed134eb42dd2afe9ce7746c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_int64_vsx.h @@ -0,0 +1,286 @@ +#pragma once + +#include +#include +#include +namespace at { +namespace vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +template <> +class Vectorized { + private: + union { + struct { + vint64 _vec0; + vint64 _vec1; + }; + struct { + vbool64 _vecb0; + vbool64 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + using value_type = int64_t; + using vec_internal_type = vint64; + using vec_internal_mask_type = vbool64; + using size_type = int; + using ElementType = signed long long; + static constexpr size_type size() { + return 4; + } + Vectorized() {} + C10_ALWAYS_INLINE Vectorized(vint64 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool64 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vint64 v1, vint64 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool64 v1, vbool64 v2) : _vecb0{v1}, _vecb1{v2} {} + C10_ALWAYS_INLINE Vectorized(int64_t scalar) + : _vec0{vec_splats(scalar)}, _vec1{vec_splats(scalar)} {} + C10_ALWAYS_INLINE Vectorized( + int64_t scalar1, + int64_t scalar2, + int64_t scalar3, + int64_t scalar4) + : _vec0{vint64{scalar1, scalar2}}, _vec1{vint64{scalar3, scalar4}} {} + + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return a; + } + + template + static std::enable_if_t> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return {b._vec0, a._vec1}; + } + + template + static std::enable_if_t<(mask & 15) == 15, Vectorized> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + return b; + } + + template + static std::enable_if_t<(mask > 0 && mask < 3), Vectorized> C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + constexpr uint64_t g0 = (mask & 1) * 0xffffffffffffffff; + constexpr uint64_t g1 = ((mask & 2) >> 1) * 0xffffffffffffffff; + const vbool64 mask_1st = (vbool64){g0, g1}; + return {(vint64)vec_sel(a._vec0, b._vec0, (vbool64)mask_1st), a._vec1}; + } + + template + static std::enable_if_t<(mask > 3) && (mask & 3) == 0, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr uint64_t g0_2 = ((mask & 4) >> 2) * 0xffffffffffffffff; + constexpr uint64_t g1_2 = ((mask & 8) >> 3) * 0xffffffffffffffff; + + const vbool64 mask_2nd = (vbool64){g0_2, g1_2}; + return {a._vec0, (vint64)vec_sel(a._vec1, b._vec1, (vbool64)mask_2nd)}; + } + + template + static std::enable_if_t< + (mask > 3) && (mask & 3) != 0 && (mask & 15) != 15, + Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + constexpr uint64_t g0 = (mask & 1) * 0xffffffffffffffff; + constexpr uint64_t g1 = ((mask & 2) >> 1) * 0xffffffffffffffff; + constexpr uint64_t g0_2 = ((mask & 4) >> 2) * 0xffffffffffffffff; + constexpr uint64_t g1_2 = ((mask & 8) >> 3) * 0xffffffffffffffff; + + const vbool64 mask_1st = (vbool64){g0, g1}; + const vbool64 mask_2nd = (vbool64){g0_2, g1_2}; + return { + (vint64)vec_sel(a._vec0, b._vec0, (vbool64)mask_1st), + (vint64)vec_sel(a._vec1, b._vec1, (vbool64)mask_2nd)}; + } + + static Vectorized C10_ALWAYS_INLINE blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // the mask used here returned by comparision of vec256 + + return { + vec_sel(a._vec0, b._vec0, mask._vecb0), + vec_sel(a._vec1, b._vec1, mask._vecb1)}; + } + template + static Vectorized arange(int64_t base = 0., step_t step = static_cast(1)) { + return Vectorized(base, base + step, base + 2 * step, base + 3 * step); + } + + static Vectorized C10_ALWAYS_INLINE + set(const Vectorized& a, + const Vectorized& b, + size_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + } + + return b; + } + static Vectorized C10_ALWAYS_INLINE + loadu(const void* ptr, int count = size()) { + if (count == size()) { + static_assert(sizeof(double) == sizeof(value_type)); + const double* dptr = reinterpret_cast(ptr); + return {// treat it as double load + (vint64)vec_vsx_ld(offset0, dptr), + (vint64)vec_vsx_ld(offset16, dptr)}; + } + + __at_align__ double tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + + return { + (vint64)vec_vsx_ld(offset0, tmp_values), + (vint64)vec_vsx_ld(offset16, tmp_values)}; + } + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + double* dptr = reinterpret_cast(ptr); + vec_vsx_st((vfloat64)_vec0, offset0, dptr); + vec_vsx_st((vfloat64)_vec1, offset16, dptr); + } else if (count > 0) { + __at_align__ double tmp_values[size()]; + vec_vsx_st((vfloat64)_vec0, offset0, tmp_values); + vec_vsx_st((vfloat64)_vec1, offset16, tmp_values); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + const int64_t& operator[](int idx) const = delete; + int64_t& operator[](int idx) = delete; + + Vectorized angle() const { + return blendv( + Vectorized(0), Vectorized(c10::pi), *this < Vectorized(0)); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return Vectorized{0}; + } + Vectorized conj() const { + return *this; + } + + Vectorized C10_ALWAYS_INLINE abs() const { + return {vec_abs(_vec0), vec_abs(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE neg() const { + return {vec_neg(_vec0), vec_neg(_vec1)}; + } + + DEFINE_MEMBER_UNARY_OP(operator~, int64_t, vec_not) + DEFINE_MEMBER_OP(operator==, int64_t, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, int64_t, vec_cmpne) + DEFINE_MEMBER_OP(operator<, int64_t, vec_cmplt) + DEFINE_MEMBER_OP(operator<=, int64_t, vec_cmple) + DEFINE_MEMBER_OP(operator>, int64_t, vec_cmpgt) + DEFINE_MEMBER_OP(operator>=, int64_t, vec_cmpge) + DEFINE_MEMBER_OP_AND_ONE(eq, int64_t, vec_cmpeq) + DEFINE_MEMBER_OP_AND_ONE(ne, int64_t, vec_cmpne) + DEFINE_MEMBER_OP_AND_ONE(lt, int64_t, vec_cmplt) + DEFINE_MEMBER_OP_AND_ONE(le, int64_t, vec_cmple) + DEFINE_MEMBER_OP_AND_ONE(gt, int64_t, vec_cmpgt) + DEFINE_MEMBER_OP_AND_ONE(ge, int64_t, vec_cmpge) + DEFINE_MEMBER_OP(operator+, int64_t, vec_add) + DEFINE_MEMBER_OP(operator-, int64_t, vec_sub) + DEFINE_MEMBER_OP(operator*, int64_t, vec_mul) + DEFINE_MEMBER_OP(operator/, int64_t, vec_div) + DEFINE_MEMBER_OP(maximum, int64_t, vec_max) + DEFINE_MEMBER_OP(minimum, int64_t, vec_min) + DEFINE_MEMBER_OP(operator&, int64_t, vec_and) + DEFINE_MEMBER_OP(operator|, int64_t, vec_or) + DEFINE_MEMBER_OP(operator^, int64_t, vec_xor) +}; + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + vuint64 shift_vec0 = reinterpret_cast(b.vec0()); + vuint64 shift_vec1 = reinterpret_cast(b.vec1()) ; + return Vectorized{vec_sl(a.vec0(), shift_vec0), vec_sl(a.vec1(), shift_vec1)}; +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + vuint64 shift_vec0 = reinterpret_cast(b.vec0()); + vuint64 shift_vec1 = reinterpret_cast(b.vec1()) ; + return Vectorized{vec_sr(a.vec0(), shift_vec0), vec_sr(a.vec1(), shift_vec1)}; +} + +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + return a.minimum(b); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_mul(a.vec0(), b.vec0()), vec_mul(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_div(a.vec0(), b.vec0()), vec_div(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_qint32_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_qint32_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..8068d6102f4a125bd5a5cc55ee93d1ff74f7361d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_qint32_vsx.h @@ -0,0 +1,281 @@ +#pragma once + +#include +#include +#include +#include +#include + +// This file defines Vectorized<> for the quantized types. +// +// +// Currently, we simply use these classes as efficient converters between +// the quantized types and Vectorized, usually in bandwidth-bound cases +// where doing the arithmetic in full-precision is acceptable (e.g. +// elementwise operators). +// +// +// Conversions are as follows: +// Vectorized -> 1x Vectorized +// +// The size of the returned float vector is specified by the special +// constexpr function float_num_vecs. The type of the value returned +// from dequantize (and expected as an argument to quantize) is +// specified by float_vec_return_type. +// +// When writing kernels with these vectors, it is expected that floating- +// point operations will be carried out in a loop over Vectorized::float_num_vecs +// iterations. + +namespace at { +namespace vec { +inline namespace CPU_CAPABILITY { + +template <> +struct Vectorized { + private: + union { + struct { + vint32 _vec0; + vint32 _vec1; + }; + struct { + vbool32 _vecb0; + vbool32 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + Vectorized() {} + + using size_type = int; + static constexpr size_type size() { + return 8; + } + + static constexpr size_t float_num_vecs() { + return 1; + } + static constexpr int int_num_vecs() { + return 1; + } + using float_vec_return_type = std::array, 1>; + using int_vec_return_type = std::array, 1>; + using value_type = c10::qint32::underlying; + using vec_internal_type = vint32; + using vec_internal_mask_type = vbool32; + C10_ALWAYS_INLINE Vectorized(vint32 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool32 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vint32 v1, vint32 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool32 v1, vbool32 v2) : _vecb0{v1}, _vecb1{v2} {} + + Vectorized(const c10::qint32& val) + : _vec0(vec_splats(val.val_)), _vec1(vec_splats(val.val_)) {} + + static Vectorized C10_ALWAYS_INLINE + loadu(const void* ptr, int count = size()) { + if (count == size()) { + return { + vec_vsx_ld(offset0, reinterpret_cast(ptr)), + vec_vsx_ld(offset16, reinterpret_cast(ptr))}; + } + + __at_align__ value_type tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + + return {vec_vsx_ld(offset0, tmp_values), vec_vsx_ld(offset16, tmp_values)}; + } + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + vec_vsx_st(_vec0, offset0, reinterpret_cast(ptr)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(ptr)); + } else if (count > 0) { + __at_align__ value_type tmp_values[size()]; + vec_vsx_st(_vec0, offset0, tmp_values); + vec_vsx_st(_vec1, offset16, tmp_values); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_zp_premul) const { + vfloat32 float_vals0 = vec_float(_vec0); + vfloat32 float_vals1 = vec_float(_vec1); + vfloat32 scale_vec0 = scale.vec0(); + vfloat32 scale_vec1 = scale.vec1(); + vfloat32 scale_zp_premul0 = scale_zp_premul.vec0(); + vfloat32 scale_zp_premul1 = scale_zp_premul.vec1(); + return {Vectorized{ + vec_madd(scale_vec0, float_vals0, scale_zp_premul0), + vec_madd(scale_vec1, float_vals1, scale_zp_premul1)}}; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + vfloat32 float_vals0 = vec_float(_vec0); + vfloat32 float_vals1 = vec_float(_vec1); + vfloat32 scale_vec0 = scale.vec0(); + vfloat32 scale_vec1 = scale.vec1(); + vfloat32 zero_point0 = zero_point.vec0(); + vfloat32 zero_point1 = zero_point.vec1(); + return {Vectorized{ + (float_vals0 - zero_point0) * scale_vec0, + (float_vals1 - zero_point1) * scale_vec1}}; + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + Vectorized retval; + + const vint32 vmin = vec_splats(std::numeric_limits::min()); + const vint32 vmax = vec_splats(std::numeric_limits::max()); + vfloat32 inverse_scale_v = vec_splats(inverse_scale); + vfloat32 vec_zero_point = vec_splats((float)(zero_point)); + Vectorized vf0 = rhs[0]; + + vfloat32 vecf0 = vf0.vec0(); + vfloat32 vecf1 = vf0.vec1(); + vecf0 = vec_mul(vecf0, inverse_scale_v); + vecf1 = vec_mul(vecf1, inverse_scale_v); + vecf0 = vec_add(vec_rint(vecf0), vec_zero_point); + vecf1 = vec_add(vec_rint(vecf1), vec_zero_point); + vint32 veci0 = vec_signed(vecf0); + vint32 veci1 = vec_signed(vecf1); + + veci0 = vec_max(veci0, vmin); + veci1 = vec_max(veci1, vmin); + veci0 = vec_min(veci0, vmax); + veci1 = vec_min(veci1, vmax); + + return {veci0, veci1}; + } + + Vectorized relu(Vectorized zero_point) const { + return {vec_max(_vec0, zero_point._vec0), vec_max(_vec1, zero_point._vec1)}; + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) const { + vint32 max0 = vec_max(_vec0, zero_point._vec0); + vint32 max1 = vec_max(_vec1, zero_point._vec1); + return {vec_min(max0, q_six._vec0), vec_min(max1, q_six._vec1)}; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + return {*this - b}; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + const vint32 vmin = vec_splats(std::numeric_limits::min()); + const vint32 vmax = vec_splats(std::numeric_limits::max()); + vfloat32 vec_mult = vec_splats(multiplier); + vint32 vec_zero_point = vec_splats(zero_point); + Vectorized vi = inp[0]; + vfloat32 vecf0 = vec_float(vi.vec0()); + vfloat32 vecf1 = vec_float(vi.vec1()); + + vecf0 = vec_mul(vecf0, vec_mult); + vecf1 = vec_mul(vecf1, vec_mult); + + vecf0 = vec_rint(vecf0); + vecf1 = vec_rint(vecf1); + + vint32 veci0 = vec_add(vec_signed(vecf0),vec_zero_point); + vint32 veci1 = vec_add(vec_signed(vecf1),vec_zero_point); + + veci0 = vec_max(veci0, vmin); + veci1 = vec_max(veci1, vmin); + veci0 = vec_min(veci0, vmax); + veci1 = vec_min(veci1, vmax); + + return {veci0, veci1}; + } + + DEFINE_MEMBER_OP(operator==, c10::qint32, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, c10::qint32, vec_cmpne) + DEFINE_MEMBER_OP(operator<, c10::qint32, vec_cmplt) + DEFINE_MEMBER_OP(operator<=, c10::qint32, vec_cmple) + DEFINE_MEMBER_OP(operator>, c10::qint32, vec_cmpgt) + DEFINE_MEMBER_OP(operator>=, c10::qint32, vec_cmpge) + DEFINE_MEMBER_OP(operator+, c10::qint32, vec_add) + DEFINE_MEMBER_OP(operator-, c10::qint32, vec_sub) + DEFINE_MEMBER_OP(operator*, c10::qint32, vec_mul) + DEFINE_MEMBER_EMULATE_BINARY_OP(operator/, c10::qint32, /) + DEFINE_MEMBER_OP(maximum, c10::qint32, vec_max) + DEFINE_MEMBER_OP(minimum, c10::qint32, vec_min) + DEFINE_MEMBER_OP(operator&, c10::qint32, vec_and) + DEFINE_MEMBER_OP(operator|, c10::qint32, vec_or) + DEFINE_MEMBER_OP(operator^, c10::qint32, vec_xor) +}; + +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + return a.minimum(b); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_mul(a.vec0(), b.vec0()), vec_mul(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { + return Vectorized{a.vec0()/b.vec0(), a.vec1()/b.vec1()}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_qint8_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_qint8_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..f67d42a4cb5170123989eaf4b7759f60e071c6cb --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_qint8_vsx.h @@ -0,0 +1,483 @@ +#pragma once + +#include +#include +#include +#include +#include + +// This file defines Vectorized<> for the quantized types. +// +// +// Currently, we simply use these classes as efficient converters between +// the quantized types and Vectorized, usually in bandwidth-bound cases +// where doing the arithmetic in full-precision is acceptable (e.g. +// elementwise operators). +// +// +// Conversions are as follows: +// Vectorized -> 4x Vectorized +// +// The size of the returned float vector is specified by the special +// constexpr function float_num_vecs. The type of the value returned +// from dequantize (and expected as an argument to quantize) is +// specified by float_vec_return_type. +// +// When writing kernels with these vectors, it is expected that floating- +// point operations will be carried out in a loop over Vectorized::float_num_vecs +// iterations. + +namespace at { +namespace vec { +inline namespace CPU_CAPABILITY { + +template <> +struct Vectorized { + private: + union { + struct { + vint8 _vec0; + vint8 _vec1; + }; + struct { + vbool8 _vecb0; + vbool8 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + Vectorized() {} + using size_type = int; + static constexpr size_type size() { + return 32; + } + + static constexpr size_t float_num_vecs() { + return 4; + } + static constexpr int int_num_vecs() { + return 4; + } + using float_vec_return_type = std::array, 4>; + using int_vec_return_type = std::array, 4>; + using value_type = typename c10::qint8::underlying; + using vec_internal_type = vint8; + using vec_internal_mask_type = vbool8; + // Broadcast constructor + C10_ALWAYS_INLINE Vectorized(const c10::qint8& val) + : _vec0{vec_splats(val.val_)}, _vec1{vec_splats(val.val_)} {} + + C10_ALWAYS_INLINE Vectorized(const Vectorized& other) + : _vec0{other._vec0}, _vec1(other._vec1) {} + + C10_ALWAYS_INLINE Vectorized(vint8 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool8 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vint8 v1, vint8 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool8 v1, vbool8 v2) : _vecb0{v1}, _vecb1{v2} {} + + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + static C10_ALWAYS_INLINE Vectorized loadu( + const void* ptr, + int count = size()) { + if (count == size()) { + return { + vec_vsx_ld(offset0, reinterpret_cast(ptr)), + vec_vsx_ld(offset16, reinterpret_cast(ptr))}; + } + __at_align__ value_type tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + return {vec_vsx_ld(offset0, tmp_values), vec_vsx_ld(offset16, tmp_values)}; + } + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + vec_vsx_st(_vec0, offset0, reinterpret_cast(ptr)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(ptr)); + } else if (count > 0) { + __at_align__ value_type tmp_values[size()]; + vec_vsx_st(_vec0, offset0, tmp_values); + vec_vsx_st(_vec1, offset16, tmp_values); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + + public: + float_vec_return_type C10_ALWAYS_INLINE dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_zp_premul) const { + vint16 vecshi0 = vec_unpackh(_vec0); + vint16 vecshi1 = vec_unpackl(_vec0); + + vint16 vecshi2 = vec_unpackh(_vec1); + vint16 vecshi3 = vec_unpackl(_vec1); + + vint32 veci0 = vec_unpackh(vecshi0); + vint32 veci1 = vec_unpackl(vecshi0); + + vint32 veci2 = vec_unpackh(vecshi1); + vint32 veci3 = vec_unpackl(vecshi1); + + vint32 veci4 = vec_unpackh(vecshi2); + vint32 veci5 = vec_unpackl(vecshi2); + + vint32 veci6 = vec_unpackh(vecshi3); + vint32 veci7 = vec_unpackl(vecshi3); + + vfloat32 vecf0_0 = vec_float(veci0); + vfloat32 vecf1_0 = vec_float(veci1); + + vfloat32 vecf0_1 = vec_float(veci2); + vfloat32 vecf1_1 = vec_float(veci3); + + vfloat32 vecf0_2 = vec_float(veci4); + vfloat32 vecf1_2 = vec_float(veci5); + + vfloat32 vecf0_3 = vec_float(veci6); + vfloat32 vecf1_3 = vec_float(veci7); + vfloat32 scale_vec0 = scale.vec0(); + vfloat32 scale_vec1 = scale.vec1(); + vfloat32 scale_zp_premul0 = scale_zp_premul.vec0(); + vfloat32 scale_zp_premul1 = scale_zp_premul.vec1(); + return { + Vectorized{ + vec_madd(scale_vec0, vecf0_0, scale_zp_premul0), + vec_madd(scale_vec1, vecf1_0, scale_zp_premul1)}, + Vectorized{ + vec_madd(scale_vec0, vecf0_1, scale_zp_premul0), + vec_madd(scale_vec1, vecf1_1, scale_zp_premul1)}, + Vectorized{ + vec_madd(scale_vec0, vecf0_2, scale_zp_premul0), + vec_madd(scale_vec1, vecf1_2, scale_zp_premul1)}, + Vectorized{ + vec_madd(scale_vec0, vecf0_3, scale_zp_premul0), + vec_madd(scale_vec1, vecf1_3, scale_zp_premul1)}}; + } + + float_vec_return_type C10_ALWAYS_INLINE dequantize( + Vectorized scale, + Vectorized zero_point) const { + vint16 vecshi0 = vec_unpackh(_vec0); + vint16 vecshi1 = vec_unpackl(_vec0); + + vint16 vecshi2 = vec_unpackh(_vec1); + vint16 vecshi3 = vec_unpackl(_vec1); + + vint32 veci0 = vec_unpackh(vecshi0); + vint32 veci1 = vec_unpackl(vecshi0); + + vint32 veci2 = vec_unpackh(vecshi1); + vint32 veci3 = vec_unpackl(vecshi1); + + vint32 veci4 = vec_unpackh(vecshi2); + vint32 veci5 = vec_unpackl(vecshi2); + + vint32 veci6 = vec_unpackh(vecshi3); + vint32 veci7 = vec_unpackl(vecshi3); + + vfloat32 vecf0_0 = vec_float(veci0); + vfloat32 vecf1_0 = vec_float(veci1); + + vfloat32 vecf0_1 = vec_float(veci2); + vfloat32 vecf1_1 = vec_float(veci3); + + vfloat32 vecf0_2 = vec_float(veci4); + vfloat32 vecf1_2 = vec_float(veci5); + + vfloat32 vecf0_3 = vec_float(veci6); + vfloat32 vecf1_3 = vec_float(veci7); + vfloat32 scale_vec0 = scale.vec0(); + vfloat32 scale_vec1 = scale.vec1(); + vfloat32 zero_point0 = zero_point.vec0(); + vfloat32 zero_point1 = zero_point.vec1(); + return { + Vectorized{ + (vecf0_0 - zero_point0) * scale_vec0, + (vecf1_0 - zero_point1) * scale_vec1}, + Vectorized{ + (vecf0_1 - zero_point0) * scale_vec0, + (vecf1_1 - zero_point1) * scale_vec1}, + Vectorized{ + (vecf0_2 - zero_point0) * scale_vec0, + (vecf1_2 - zero_point1) * scale_vec1}, + Vectorized{ + (vecf0_3 - zero_point0) * scale_vec0, + (vecf1_3 - zero_point1) * scale_vec1}}; + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + // constexpr int32_t min_val = std::numeric_limits::min(); + // constexpr int32_t max_val = std::numeric_limits::max(); + + vfloat32 inverse_scale_v = vec_splats(inverse_scale); + vfloat32 vec_zero_point = vec_splats((float)zero_point); + // vint32 vmin = vec_splats(min_val); + // vint32 vmax = vec_splats(max_val); + + Vectorized vf0 = rhs[0]; + Vectorized vf1 = rhs[1]; + Vectorized vf2 = rhs[2]; + Vectorized vf3 = rhs[3]; + vfloat32 vecf0 = vf0.vec0(); + vfloat32 vecf1 = vf0.vec1(); + vfloat32 vecf2 = vf1.vec0(); + vfloat32 vecf3 = vf1.vec1(); + + vfloat32 vecf4 = vf2.vec0(); + vfloat32 vecf5 = vf2.vec1(); + vfloat32 vecf6 = vf3.vec0(); + vfloat32 vecf7 = vf3.vec1(); + + vecf0 = vec_mul(vecf0, inverse_scale_v); + vecf1 = vec_mul(vecf1, inverse_scale_v); + vecf2 = vec_mul(vecf2, inverse_scale_v); + vecf3 = vec_mul(vecf3, inverse_scale_v); + + vecf4 = vec_mul(vecf4, inverse_scale_v); + vecf5 = vec_mul(vecf5, inverse_scale_v); + vecf6 = vec_mul(vecf6, inverse_scale_v); + vecf7 = vec_mul(vecf7, inverse_scale_v); + + vecf0 = vec_add(vec_rint(vecf0), vec_zero_point); + vecf1 = vec_add(vec_rint(vecf1), vec_zero_point); + vecf2 = vec_add(vec_rint(vecf2), vec_zero_point); + vecf3 = vec_add(vec_rint(vecf3), vec_zero_point); + + vecf4 = vec_add(vec_rint(vecf4), vec_zero_point); + vecf5 = vec_add(vec_rint(vecf5), vec_zero_point); + vecf6 = vec_add(vec_rint(vecf6), vec_zero_point); + vecf7 = vec_add(vec_rint(vecf7), vec_zero_point); + + vint32 veci0 = vec_signed(vecf0); + vint32 veci1 = vec_signed(vecf1); + vint32 veci2 = vec_signed(vecf2); + vint32 veci3 = vec_signed(vecf3); + + vint32 veci4 = vec_signed(vecf4); + vint32 veci5 = vec_signed(vecf5); + vint32 veci6 = vec_signed(vecf6); + vint32 veci7 = vec_signed(vecf7); + + // veci0 = vec_min(vmax, vec_max( vmin, vecf0)) ; + // veci1 = vec_min(vmax, vec_max( vmin, vecf1)) ; + // veci2 = vec_min(vmax, vec_max( vmin, vecf2)) ; + // veci3 = vec_min(vmax, vec_max( vmin, vecf3)) ; + + // veci4 = vec_min(vmax, vec_max( vmin, vecf4)) ; + // veci5 = vec_min(vmax, vec_max( vmin, vecf5)) ; + // veci6 = vec_min(vmax, vec_max( vmin, vecf6)) ; + // veci7 = vec_min(vmax, vec_max( vmin, vecf7)) ; + // vec_packs CLAMP already + vint16 vecshi0 = vec_packs(veci0, veci1); + vint16 vecshi1 = vec_packs(veci2, veci3); + vint16 vecshi2 = vec_packs(veci4, veci5); + vint16 vecshi3 = vec_packs(veci6, veci7); + + vint8 vec0 = vec_packs(vecshi0, vecshi1); + vint8 vec1 = vec_packs(vecshi2, vecshi3); + + return {vec0, vec1}; + } + + Vectorized C10_ALWAYS_INLINE relu(Vectorized zero_point) const { + return {vec_max(_vec0, zero_point._vec0), vec_max(_vec1, zero_point._vec1)}; + } + + Vectorized C10_ALWAYS_INLINE + relu6(Vectorized zero_point, Vectorized q_six) const { + vint8 max0 = vec_max(_vec0, zero_point._vec0); + vint8 max1 = vec_max(_vec1, zero_point._vec1); + return {vec_min(max0, q_six._vec0), vec_min(max1, q_six._vec1)}; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + vint16 vecshi0 = vec_unpackh(_vec0); + vint16 vecBshi0 = vec_unpackh(b._vec0); + vint16 vecshi1 = vec_unpackl(_vec0); + vint16 vecBshi1 = vec_unpackl(b._vec0); + + vint16 vecshi2 = vec_unpackh(_vec1); + vint16 vecBshi2 = vec_unpackh(b._vec1); + vint16 vecshi3 = vec_unpackl(_vec1); + vint16 vecBshi3 = vec_unpackl(b._vec1); + + vint32 veci0 = vec_unpackh(vecshi0); + vint32 vecBi0 = vec_unpackh(vecBshi0); + vint32 veci1 = vec_unpackl(vecshi0); + vint32 vecBi1 = vec_unpackl(vecBshi0); + + vint32 veci2 = vec_unpackh(vecshi1); + vint32 vecBi2 = vec_unpackh(vecBshi1); + vint32 veci3 = vec_unpackl(vecshi1); + vint32 vecBi3 = vec_unpackl(vecBshi1); + + vint32 veci4 = vec_unpackh(vecshi2); + vint32 vecBi4 = vec_unpackh(vecBshi2); + vint32 veci5 = vec_unpackl(vecshi2); + vint32 vecBi5 = vec_unpackl(vecBshi2); + + vint32 veci6 = vec_unpackh(vecshi3); + vint32 vecBi6 = vec_unpackh(vecBshi3); + vint32 veci7 = vec_unpackl(vecshi3); + vint32 vecBi7 = vec_unpackl(vecBshi3); + + return { + Vectorized(veci0 - vecBi0, veci1 - vecBi1), + Vectorized(veci2 - vecBi2, veci3 - vecBi3), + Vectorized(veci4 - vecBi4, veci5 - vecBi5), + Vectorized(veci6 - vecBi6, veci7 - vecBi7)}; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + vfloat32 vec_multiplier = vec_splats(multiplier); + vint32 vec_zero_point = vec_splats(zero_point); + + Vectorized vi0 = inp[0]; + Vectorized vi1 = inp[1]; + Vectorized vi2 = inp[2]; + Vectorized vi3 = inp[3]; + + vfloat32 vecf0 = vec_float(vi0.vec0()); + vfloat32 vecf1 = vec_float(vi0.vec1()); + vfloat32 vecf2 = vec_float(vi1.vec0()); + vfloat32 vecf3 = vec_float(vi1.vec1()); + + vfloat32 vecf4 = vec_float(vi2.vec0()); + vfloat32 vecf5 = vec_float(vi2.vec1()); + vfloat32 vecf6 = vec_float(vi3.vec0()); + vfloat32 vecf7 = vec_float(vi3.vec1()); + + vecf0 = vec_mul(vecf0, vec_multiplier); + vecf1 = vec_mul(vecf1, vec_multiplier); + vecf2 = vec_mul(vecf2, vec_multiplier); + vecf3 = vec_mul(vecf3, vec_multiplier); + + vecf4 = vec_mul(vecf4, vec_multiplier); + vecf5 = vec_mul(vecf5, vec_multiplier); + vecf6 = vec_mul(vecf6, vec_multiplier); + vecf7 = vec_mul(vecf7, vec_multiplier); + + vecf0 = vec_rint(vecf0); + vecf1 = vec_rint(vecf1); + vecf2 = vec_rint(vecf2); + vecf3 = vec_rint(vecf3); + + vecf4 = vec_rint(vecf4); + vecf5 = vec_rint(vecf5); + vecf6 = vec_rint(vecf6); + vecf7 = vec_rint(vecf7); + + vint32 veci0 = vec_signed(vecf0); + vint32 veci1 = vec_signed(vecf1); + vint32 veci2 = vec_signed(vecf2); + vint32 veci3 = vec_signed(vecf3); + + vint32 veci4 = vec_signed(vecf4); + vint32 veci5 = vec_signed(vecf5); + vint32 veci6 = vec_signed(vecf6); + vint32 veci7 = vec_signed(vecf7); + + veci0 = vec_add(veci0, vec_zero_point); + veci1 = vec_add(veci1, vec_zero_point); + veci2 = vec_add(veci2, vec_zero_point); + veci3 = vec_add(veci3, vec_zero_point); + + veci4 = vec_add(veci4, vec_zero_point); + veci5 = vec_add(veci5, vec_zero_point); + veci6 = vec_add(veci6, vec_zero_point); + veci7 = vec_add(veci7, vec_zero_point); + + vint16 vecshi0 = vec_packs(veci0, veci1); + vint16 vecshi1 = vec_packs(veci2, veci3); + vint16 vecshi2 = vec_packs(veci4, veci5); + vint16 vecshi3 = vec_packs(veci6, veci7); + + vint8 vec0 = vec_packs(vecshi0, vecshi1); + vint8 vec1 = vec_packs(vecshi2, vecshi3); + + return {vec0, vec1}; + } + + DEFINE_MEMBER_OP(operator==, c10::qint8, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, c10::qint8, vec_cmpne) + DEFINE_MEMBER_OP(operator<, c10::qint8, vec_cmplt) + DEFINE_MEMBER_OP(operator<=, c10::qint8, vec_cmple) + DEFINE_MEMBER_OP(operator>, c10::qint8, vec_cmpgt) + DEFINE_MEMBER_OP(operator>=, c10::qint8, vec_cmpge) + DEFINE_MEMBER_OP(operator+, c10::qint8, vec_add) + DEFINE_MEMBER_OP(operator-, c10::qint8, vec_sub) + DEFINE_MEMBER_OP(operator*, c10::qint8, vec_mul) + DEFINE_MEMBER_EMULATE_BINARY_OP(operator/, c10::qint8, /) + DEFINE_MEMBER_OP(maximum, c10::qint8, vec_max) + DEFINE_MEMBER_OP(minimum, c10::qint8, vec_min) + DEFINE_MEMBER_OP(operator&, c10::qint8, vec_and) + DEFINE_MEMBER_OP(operator|, c10::qint8, vec_or) + DEFINE_MEMBER_OP(operator^, c10::qint8, vec_xor) +}; + +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + return a.minimum(b); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_mul(a.vec0(), b.vec0()), vec_mul(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { + return Vectorized{a.vec0()/b.vec0(), a.vec1()/b.vec1()}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_quint8_vsx.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_quint8_vsx.h new file mode 100644 index 0000000000000000000000000000000000000000..c0d77d500491b3daa3b297832917d35b573c3c43 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vec256_quint8_vsx.h @@ -0,0 +1,501 @@ +#pragma once + +#include +#include +#include + +#include +#include +#include + +// This file defines Vectorized<> for the quantized types. +// +// +// Currently, we simply use these classes as efficient converters between +// the quantized types and Vectorized, usually in bandwidth-bound cases +// where doing the arithmetic in full-precision is acceptable (e.g. +// elementwise operators). +// +// +// Conversions are as follows: +// Vectorized -> 4x Vectorized +// +// The size of the returned float vector is specified by the special +// constexpr function float_num_vecs. The type of the value returned +// from dequantize (and expected as an argument to quantize) is +// specified by float_vec_return_type. +// +// When writing kernels with these vectors, it is expected that floating- +// point operations will be carried out in a loop over Vectorized::float_num_vecs +// iterations. + +namespace at { +namespace vec { +inline namespace CPU_CAPABILITY { + +const vint16 mask_unsigned = vec_splats((short int)0xFF); +template <> +struct Vectorized { + private: + union { + struct { + vuint8 _vec0; + vuint8 _vec1; + }; + struct { + vbool8 _vecb0; + vbool8 _vecb1; + }; + + } __attribute__((__may_alias__)); + + public: + Vectorized() {} + using size_type = int; + static constexpr size_type size() { + return 32; + } + + static constexpr size_t float_num_vecs() { + return 4; + } + static constexpr int int_num_vecs() { + return 4; + } + using float_vec_return_type = std::array, 4>; + using int_vec_return_type = std::array, 4>; + using value_type = typename c10::quint8::underlying; + using vec_internal_type = vuint8; + using vec_internal_mask_type = vbool8; + // Broadcast constructor + C10_ALWAYS_INLINE Vectorized(const c10::quint8& val) + : _vec0(vec_splats(val.val_)), _vec1(vec_splats(val.val_)) {} + + C10_ALWAYS_INLINE Vectorized(const Vectorized& other) + : _vec0{other._vec0}, _vec1(other._vec1) {} + + C10_ALWAYS_INLINE Vectorized(vuint8 v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(vbool8 vmask) : _vecb0{vmask}, _vecb1{vmask} {} + C10_ALWAYS_INLINE Vectorized(vuint8 v1, vuint8 v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(vbool8 v1, vbool8 v2) : _vecb0{v1}, _vecb1{v2} {} + + C10_ALWAYS_INLINE const vec_internal_type& vec0() const { + return _vec0; + } + C10_ALWAYS_INLINE const vec_internal_type& vec1() const { + return _vec1; + } + + static C10_ALWAYS_INLINE Vectorized loadu( + const void* ptr, + int count = size()) { + if (count == size()) { + return { + vec_vsx_ld(offset0, reinterpret_cast(ptr)), + vec_vsx_ld(offset16, reinterpret_cast(ptr))}; + } + __at_align__ value_type tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(value_type)); + return {vec_vsx_ld(offset0, tmp_values), vec_vsx_ld(offset16, tmp_values)}; + } + void C10_ALWAYS_INLINE store(void* ptr, int count = size()) const { + if (count == size()) { + vec_vsx_st(_vec0, offset0, reinterpret_cast(ptr)); + vec_vsx_st(_vec1, offset16, reinterpret_cast(ptr)); + } else if (count > 0) { + __at_align__ value_type tmp_values[size()]; + vec_vsx_st(_vec0, offset0, tmp_values); + vec_vsx_st(_vec1, offset16, tmp_values); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(value_type)); + } + } + + public: + float_vec_return_type C10_ALWAYS_INLINE dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_zp_premul) const { + // unpacking unsigned as signed + vint16 vecshi0 = vec_unpackh((vint8)_vec0); + vint16 vecshi1 = vec_unpackl((vint8)_vec0); + + vint16 vecshi2 = vec_unpackh((vint8)_vec1); + vint16 vecshi3 = vec_unpackl((vint8)_vec1); + + // signed -> unsigned + vecshi0 = vec_and(vecshi0, mask_unsigned); + vecshi1 = vec_and(vecshi1, mask_unsigned); + + vecshi2 = vec_and(vecshi2, mask_unsigned); + vecshi3 = vec_and(vecshi3, mask_unsigned); + + vint32 veci0 = vec_unpackh(vecshi0); + vint32 veci1 = vec_unpackl(vecshi0); + + vint32 veci2 = vec_unpackh(vecshi1); + vint32 veci3 = vec_unpackl(vecshi1); + + vint32 veci4 = vec_unpackh(vecshi2); + vint32 veci5 = vec_unpackl(vecshi2); + + vint32 veci6 = vec_unpackh(vecshi3); + vint32 veci7 = vec_unpackl(vecshi3); + + vfloat32 vecf0_0 = vec_float(veci0); + vfloat32 vecf1_0 = vec_float(veci1); + + vfloat32 vecf0_1 = vec_float(veci2); + vfloat32 vecf1_1 = vec_float(veci3); + + vfloat32 vecf0_2 = vec_float(veci4); + vfloat32 vecf1_2 = vec_float(veci5); + + vfloat32 vecf0_3 = vec_float(veci6); + vfloat32 vecf1_3 = vec_float(veci7); + vfloat32 scale_vec0 = scale.vec0(); + vfloat32 scale_vec1 = scale.vec1(); + vfloat32 scale_zp_premul0 = scale_zp_premul.vec0(); + vfloat32 scale_zp_premul1 = scale_zp_premul.vec1(); + return { + Vectorized{ + vec_madd(scale_vec0, vecf0_0, scale_zp_premul0), + vec_madd(scale_vec1, vecf1_0, scale_zp_premul1)}, + Vectorized{ + vec_madd(scale_vec0, vecf0_1, scale_zp_premul0), + vec_madd(scale_vec1, vecf1_1, scale_zp_premul1)}, + Vectorized{ + vec_madd(scale_vec0, vecf0_2, scale_zp_premul0), + vec_madd(scale_vec1, vecf1_2, scale_zp_premul1)}, + Vectorized{ + vec_madd(scale_vec0, vecf0_3, scale_zp_premul0), + vec_madd(scale_vec1, vecf1_3, scale_zp_premul1)}}; + } + + float_vec_return_type C10_ALWAYS_INLINE dequantize( + Vectorized scale, + Vectorized zero_point) const { + // unpacking unsigned as signed + vint16 vecshi0 = vec_unpackh((vint8)_vec0); + vint16 vecshi1 = vec_unpackl((vint8)_vec0); + + vint16 vecshi2 = vec_unpackh((vint8)_vec1); + vint16 vecshi3 = vec_unpackl((vint8)_vec1); + + // signed -> unsigned + vecshi0 = vec_and(vecshi0, mask_unsigned); + vecshi1 = vec_and(vecshi1, mask_unsigned); + + vecshi2 = vec_and(vecshi2, mask_unsigned); + vecshi3 = vec_and(vecshi3, mask_unsigned); + + vint32 veci0 = vec_unpackh(vecshi0); + vint32 veci1 = vec_unpackl(vecshi0); + + vint32 veci2 = vec_unpackh(vecshi1); + vint32 veci3 = vec_unpackl(vecshi1); + + vint32 veci4 = vec_unpackh(vecshi2); + vint32 veci5 = vec_unpackl(vecshi2); + + vint32 veci6 = vec_unpackh(vecshi3); + vint32 veci7 = vec_unpackl(vecshi3); + + vfloat32 vecf0_0 = vec_float(veci0); + vfloat32 vecf1_0 = vec_float(veci1); + + vfloat32 vecf0_1 = vec_float(veci2); + vfloat32 vecf1_1 = vec_float(veci3); + + vfloat32 vecf0_2 = vec_float(veci4); + vfloat32 vecf1_2 = vec_float(veci5); + + vfloat32 vecf0_3 = vec_float(veci6); + vfloat32 vecf1_3 = vec_float(veci7); + vfloat32 scale_vec0 = scale.vec0(); + vfloat32 scale_vec1 = scale.vec1(); + vfloat32 zero_point0 = zero_point.vec0(); + vfloat32 zero_point1 = zero_point.vec1(); + return { + Vectorized{ + (vecf0_0 - zero_point0) * scale_vec0, + (vecf1_0 - zero_point1) * scale_vec1}, + Vectorized{ + (vecf0_1 - zero_point0) * scale_vec0, + (vecf1_1 - zero_point1) * scale_vec1}, + Vectorized{ + (vecf0_2 - zero_point0) * scale_vec0, + (vecf1_2 - zero_point1) * scale_vec1}, + Vectorized{ + (vecf0_3 - zero_point0) * scale_vec0, + (vecf1_3 - zero_point1) * scale_vec1}}; + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + // constexpr int32_t min_val = std::numeric_limits::min(); + // constexpr int32_t max_val = std::numeric_limits::max(); + + vfloat32 vec_inverse = vec_splats(inverse_scale); + vfloat32 vec_zero_point = vec_splats((float)zero_point); + // vuint32 vmin = vec_splats(min_val); + // vuint32 vmax = vec_splats(max_val); + Vectorized vf0 = rhs[0]; + Vectorized vf1 = rhs[1]; + Vectorized vf2 = rhs[2]; + Vectorized vf3 = rhs[3]; + vfloat32 vecf0 = vf0.vec0(); + vfloat32 vecf1 = vf0.vec1(); + vfloat32 vecf2 = vf1.vec0(); + vfloat32 vecf3 = vf1.vec1(); + + vfloat32 vecf4 = vf2.vec0(); + vfloat32 vecf5 = vf2.vec1(); + vfloat32 vecf6 = vf3.vec0(); + vfloat32 vecf7 = vf3.vec1(); + + vecf0 = vec_mul(vecf0, vec_inverse); + vecf1 = vec_mul(vecf1, vec_inverse); + vecf2 = vec_mul(vecf2, vec_inverse); + vecf3 = vec_mul(vecf3, vec_inverse); + + vecf4 = vec_mul(vecf4, vec_inverse); + vecf5 = vec_mul(vecf5, vec_inverse); + vecf6 = vec_mul(vecf6, vec_inverse); + vecf7 = vec_mul(vecf7, vec_inverse); + + vecf0 = vec_add(vec_rint(vecf0), vec_zero_point); + vecf1 = vec_add(vec_rint(vecf1), vec_zero_point); + vecf2 = vec_add(vec_rint(vecf2), vec_zero_point); + vecf3 = vec_add(vec_rint(vecf3), vec_zero_point); + + vecf4 = vec_add(vec_rint(vecf4), vec_zero_point); + vecf5 = vec_add(vec_rint(vecf5), vec_zero_point); + vecf6 = vec_add(vec_rint(vecf6), vec_zero_point); + vecf7 = vec_add(vec_rint(vecf7), vec_zero_point); + + vint32 veci0 = vec_signed(vecf0); + vint32 veci1 = vec_signed(vecf1); + vint32 veci2 = vec_signed(vecf2); + vint32 veci3 = vec_signed(vecf3); + + vint32 veci4 = vec_signed(vecf4); + vint32 veci5 = vec_signed(vecf5); + vint32 veci6 = vec_signed(vecf6); + vint32 veci7 = vec_signed(vecf7); + + vint16 vecshi0 = vec_packs(veci0, veci1); + vint16 vecshi1 = vec_packs(veci2, veci3); + vint16 vecshi2 = vec_packs(veci4, veci5); + vint16 vecshi3 = vec_packs(veci6, veci7); + + vuint8 vec0 = vec_packsu(vecshi0, vecshi1); + vuint8 vec1 = vec_packsu(vecshi2, vecshi3); + + return {vec0, vec1}; + } + + Vectorized C10_ALWAYS_INLINE relu(Vectorized zero_point) const { + return {vec_max(_vec0, zero_point._vec0), vec_max(_vec1, zero_point._vec1)}; + } + + Vectorized C10_ALWAYS_INLINE + relu6(Vectorized zero_point, Vectorized q_six) const { + vuint8 max0 = vec_max(_vec0, zero_point._vec0); + vuint8 max1 = vec_max(_vec1, zero_point._vec1); + return {vec_min(max0, q_six._vec0), vec_min(max1, q_six._vec1)}; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + vint16 vecshi0 = vec_unpackh((vint8)_vec0); + vint16 vecBshi0 = vec_unpackh((vint8)b._vec0); + vint16 vecshi1 = vec_unpackl((vint8)_vec0); + vint16 vecBshi1 = vec_unpackl((vint8)b._vec0); + + vint16 vecshi2 = vec_unpackh((vint8)_vec1); + vint16 vecBshi2 = vec_unpackh((vint8)b._vec1); + vint16 vecshi3 = vec_unpackl((vint8)_vec1); + vint16 vecBshi3 = vec_unpackl((vint8)b._vec1); + + vecshi0 = vec_and(vecshi0, mask_unsigned); + vecBshi0 = vec_and(vecBshi0, mask_unsigned); + vecshi1 = vec_and(vecshi1, mask_unsigned); + vecBshi1 = vec_and(vecBshi1, mask_unsigned); + + vecshi2 = vec_and(vecshi2, mask_unsigned); + vecBshi2 = vec_and(vecBshi2, mask_unsigned); + vecshi3 = vec_and(vecshi3, mask_unsigned); + vecBshi3 = vec_and(vecBshi3, mask_unsigned); + + vint32 veci0 = vec_unpackh(vecshi0); + vint32 vecBi0 = vec_unpackh(vecBshi0); + vint32 veci1 = vec_unpackl(vecshi0); + vint32 vecBi1 = vec_unpackl(vecBshi0); + + vint32 veci2 = vec_unpackh(vecshi1); + vint32 vecBi2 = vec_unpackh(vecBshi1); + vint32 veci3 = vec_unpackl(vecshi1); + vint32 vecBi3 = vec_unpackl(vecBshi1); + + vint32 veci4 = vec_unpackh(vecshi2); + vint32 vecBi4 = vec_unpackh(vecBshi2); + vint32 veci5 = vec_unpackl(vecshi2); + vint32 vecBi5 = vec_unpackl(vecBshi2); + + vint32 veci6 = vec_unpackh(vecshi3); + vint32 vecBi6 = vec_unpackh(vecBshi3); + vint32 veci7 = vec_unpackl(vecshi3); + vint32 vecBi7 = vec_unpackl(vecBshi3); + + return { + Vectorized(veci0 - vecBi0, veci1 - vecBi1), + Vectorized(veci2 - vecBi2, veci3 - vecBi3), + Vectorized(veci4 - vecBi4, veci5 - vecBi5), + Vectorized(veci6 - vecBi6, veci7 - vecBi7)}; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + vfloat32 vec_multiplier = vec_splats(multiplier); + vint32 vec_zero_point = vec_splats(zero_point); + + Vectorized vi0 = inp[0]; + Vectorized vi1 = inp[1]; + Vectorized vi2 = inp[2]; + Vectorized vi3 = inp[3]; + + vfloat32 vecf0 = vec_float(vi0.vec0()); + vfloat32 vecf1 = vec_float(vi0.vec1()); + vfloat32 vecf2 = vec_float(vi1.vec0()); + vfloat32 vecf3 = vec_float(vi1.vec1()); + + vfloat32 vecf4 = vec_float(vi2.vec0()); + vfloat32 vecf5 = vec_float(vi2.vec1()); + vfloat32 vecf6 = vec_float(vi3.vec0()); + vfloat32 vecf7 = vec_float(vi3.vec1()); + + vecf0 = vec_mul(vecf0, vec_multiplier); + vecf1 = vec_mul(vecf1, vec_multiplier); + vecf2 = vec_mul(vecf2, vec_multiplier); + vecf3 = vec_mul(vecf3, vec_multiplier); + + vecf4 = vec_mul(vecf4, vec_multiplier); + vecf5 = vec_mul(vecf5, vec_multiplier); + vecf6 = vec_mul(vecf6, vec_multiplier); + vecf7 = vec_mul(vecf7, vec_multiplier); + + vecf0 = vec_rint(vecf0); + vecf1 = vec_rint(vecf1); + vecf2 = vec_rint(vecf2); + vecf3 = vec_rint(vecf3); + + vecf4 = vec_rint(vecf4); + vecf5 = vec_rint(vecf5); + vecf6 = vec_rint(vecf6); + vecf7 = vec_rint(vecf7); + + vint32 veci0 = vec_signed(vecf0); + vint32 veci1 = vec_signed(vecf1); + vint32 veci2 = vec_signed(vecf2); + vint32 veci3 = vec_signed(vecf3); + + vint32 veci4 = vec_signed(vecf4); + vint32 veci5 = vec_signed(vecf5); + vint32 veci6 = vec_signed(vecf6); + vint32 veci7 = vec_signed(vecf7); + + veci0 = vec_add(veci0, vec_zero_point); + veci1 = vec_add(veci1, vec_zero_point); + veci2 = vec_add(veci2, vec_zero_point); + veci3 = vec_add(veci3, vec_zero_point); + + veci4 = vec_add(veci4, vec_zero_point); + veci5 = vec_add(veci5, vec_zero_point); + veci6 = vec_add(veci6, vec_zero_point); + veci7 = vec_add(veci7, vec_zero_point); + + vint16 vecshi0 = vec_packs(veci0, veci1); + vint16 vecshi1 = vec_packs(veci2, veci3); + vint16 vecshi2 = vec_packs(veci4, veci5); + vint16 vecshi3 = vec_packs(veci6, veci7); + + vuint8 vec0 = vec_packsu(vecshi0, vecshi1); + vuint8 vec1 = vec_packsu(vecshi2, vecshi3); + + return {vec0, vec1}; + } + + DEFINE_MEMBER_OP(operator==, c10::quint8, vec_cmpeq) + DEFINE_MEMBER_OP(operator!=, c10::quint8, vec_cmpne) + DEFINE_MEMBER_OP(operator<, c10::quint8, vec_cmplt) + DEFINE_MEMBER_OP(operator<=, c10::quint8, vec_cmple) + DEFINE_MEMBER_OP(operator>, c10::quint8, vec_cmpgt) + DEFINE_MEMBER_OP(operator>=, c10::quint8, vec_cmpge) + DEFINE_MEMBER_OP(operator+, c10::quint8, vec_add) + DEFINE_MEMBER_OP(operator-, c10::quint8, vec_sub) + DEFINE_MEMBER_OP(operator*, c10::quint8, vec_mul) + DEFINE_MEMBER_EMULATE_BINARY_OP(operator/, c10::quint8, /) + DEFINE_MEMBER_OP(maximum, c10::quint8, vec_max) + DEFINE_MEMBER_OP(minimum, c10::quint8, vec_min) + DEFINE_MEMBER_OP(operator&, c10::quint8, vec_and) + DEFINE_MEMBER_OP(operator|, c10::quint8, vec_or) + DEFINE_MEMBER_OP(operator^, c10::quint8, vec_xor) +}; + +template <> +Vectorized inline maximum( + const Vectorized& a, + const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline minimum( + const Vectorized& a, + const Vectorized& b) { + return a.minimum(b); +} + +template <> +Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_add(a.vec0(), b.vec0()), vec_add(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_sub(a.vec0(), b.vec0()), vec_sub(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_mul(a.vec0(), b.vec0()), vec_mul(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { + return Vectorized{a.vec0()/b.vec0(), a.vec1()/b.vec1()}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_and(a.vec0(), b.vec0()), vec_and(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_or(a.vec0(), b.vec0()), vec_or(a.vec1(), b.vec1())}; +} + +template <> +Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { + return Vectorized{vec_xor(a.vec0(), b.vec0()), vec_xor(a.vec1(), b.vec1())}; +} + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vsx_helpers.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vsx_helpers.h new file mode 100644 index 0000000000000000000000000000000000000000..1dc742f3cbb1c245f972babfdb26a539c5179263 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/vsx/vsx_helpers.h @@ -0,0 +1,474 @@ +#pragma once +#include +#include +#include + +#if defined(__clang__) +typedef __vector __bool char vbool8; +typedef __vector __bool short vbool16; +typedef __vector __bool int vbool32; +typedef __vector __bool long long vbool64; +using vint8 = __attribute__((vector_size(16))) signed char; +using vint16 = __attribute__((vector_size(16))) signed short; +using vint32 = __attribute__((vector_size(16))) signed int; +using vint64 = __attribute__((vector_size(16))) signed long long; +using vuint8 = __attribute__((vector_size(16))) unsigned char; +using vuint16 = __attribute__((vector_size(16))) unsigned short; +using vuint32 = __attribute__((vector_size(16))) unsigned int; +using vuint64 = __attribute__((vector_size(16))) unsigned long long; +using vfloat32 = __attribute__((vector_size(16))) float; +using vfloat64 = __attribute__((vector_size(16))) double; +#else +using vbool8 = __attribute__((altivec(vector__))) __attribute__((altivec(bool__))) char; +using vbool16 = __attribute__((altivec(vector__))) __attribute__((altivec(bool__))) short; +using vbool32 = __attribute__((altivec(vector__))) __attribute__((altivec(bool__))) int; +using vbool64 = __attribute__((altivec(vector__))) __attribute__((altivec(bool__))) long long; +using vint8 = __attribute__((altivec(vector__))) signed char; +using vint16 = __attribute__((altivec(vector__))) signed short; +using vint32 = __attribute__((altivec(vector__))) signed int; +using vint64 = __attribute__((altivec(vector__))) signed long long; +using vuint8 = __attribute__((altivec(vector__))) unsigned char; +using vuint16 = __attribute__((altivec(vector__))) unsigned short; +using vuint32 = __attribute__((altivec(vector__))) unsigned int; +using vuint64 = __attribute__((altivec(vector__))) unsigned long long; +using vfloat32 = __attribute__((altivec(vector__))) float; +using vfloat64 = __attribute__((altivec(vector__))) double; +#endif + +#if !defined(vec_float) +C10_ALWAYS_INLINE vfloat32 vec_float(const vint32& vec_in) { + vfloat32 vec_out; + __asm__("xvcvsxwsp %x0,%x1" : "=wf"(vec_out) : "wa"(vec_in)); + return vec_out; +} +#endif + +#if !defined(vec_signed) +C10_ALWAYS_INLINE vint32 vec_signed(const vfloat32& vec_in) { + vint32 vec_out; + __asm__("xvcvspsxws %x0,%x1" : "=wa"(vec_out) : "wf"(vec_in)); + return vec_out; +} + +C10_ALWAYS_INLINE vint64 vec_signed(const vfloat64& vec_in) { + vint64 vec_out; + __asm__("xvcvdpsxds %x0,%x1" : "=wa"(vec_out) : "wd"(vec_in)); + return vec_out; +} +#endif + +#if !defined(vec_neg) +C10_ALWAYS_INLINE vfloat32 vec_neg(const vfloat32& vec_in) { + vfloat32 vec_out; + __asm__("xvnegsp %x0,%x1" : "=wf"(vec_out) : "wf"(vec_in)); + return vec_out; +} + +C10_ALWAYS_INLINE vfloat64 vec_neg(const vfloat64& vec_in) { + vfloat64 vec_out; + __asm__("xvnegdp %x0,%x1" : "=wd"(vec_out) : "wd"(vec_in)); + return vec_out; +} + +C10_ALWAYS_INLINE vint16 vec_neg(const vint16& vec_in) { + vint16 vint0 = {0, 0, 0, 0 ,0, 0, 0, 0}; + return vec_vsubuhm(vint0, vec_in); +} + +C10_ALWAYS_INLINE vint32 vec_neg(const vint32& vec_in) { + vint32 vint0 = {0, 0, 0, 0}; + return vec_vsubuwm(vint0, vec_in); +} + +C10_ALWAYS_INLINE vint64 vec_neg(const vint64& vec_in) { + return -vec_in; +} +#endif + +#if !defined(vec_sldw) +template +C10_ALWAYS_INLINE vfloat32 +vec_sldw_aux(const vfloat32& vec_in0, const vfloat32& vec_in1) { + vfloat32 vec_out; + __asm("xxsldwi %x0, %x1, %x2, %3 " + : "=wa"(vec_out) + : "wa"(vec_in0), "wa"(vec_in1), "I"(C)); + return vec_out; +} + +#define vec_sldw(a, b, c) vec_sldw_aux(a, b) +#endif + +#define vec_not(a) vec_nor(a, a) +#if defined(__clang__) && !defined(vec_splats) +C10_ALWAYS_INLINE vint64 vec_splats(const int64_t& a) { + return vec_splats(a); +} +#endif +// Vectorized min/max which return a if any operand is nan +template +C10_ALWAYS_INLINE T vec_min_nan(const T& a, const T& b) { + return vec_min(a, b); +} +template +C10_ALWAYS_INLINE T vec_max_nan(const T& a, const T& b) { + return vec_max(a, b); +} + +// Specializations for float/double taken from Eigen +template<> +C10_ALWAYS_INLINE vfloat32 vec_min_nan(const vfloat32& a, const vfloat32& b) +{ + // NOTE: about 10% slower than vec_min, but consistent with std::min and SSE regarding NaN + vfloat32 ret; + __asm__ ("xvcmpgesp %x0,%x1,%x2\n\txxsel %x0,%x1,%x2,%x0" : "=&wa" (ret) : "wa" (a), "wa" (b)); + return ret; +} +// Specializations for float/double taken from Eigen +template<> +C10_ALWAYS_INLINE vfloat32 vec_max_nan(const vfloat32& a, const vfloat32& b) +{ + // NOTE: about 10% slower than vec_max, but consistent with std::min and SSE regarding NaN + vfloat32 ret; + __asm__ ("xvcmpgtsp %x0,%x2,%x1\n\txxsel %x0,%x1,%x2,%x0" : "=&wa" (ret) : "wa" (a), "wa" (b)); + return ret; +} + +template<> +C10_ALWAYS_INLINE vfloat64 vec_min_nan(const vfloat64& a, const vfloat64& b) +{ + // NOTE: about 10% slower than vec_min, but consistent with std::min and SSE regarding NaN + vfloat64 ret; + __asm__ ("xvcmpgedp %x0,%x1,%x2\n\txxsel %x0,%x1,%x2,%x0" : "=&wa" (ret) : "wa" (a), "wa" (b)); + return ret; +} +template<> +C10_ALWAYS_INLINE vfloat64 vec_max_nan(const vfloat64& a, const vfloat64& b) +{ + // NOTE: about 10% slower than vec_max, but consistent with std::max and SSE regarding NaN + vfloat64 ret; + __asm__ ("xvcmpgtdp %x0,%x2,%x1\n\txxsel %x0,%x1,%x2,%x0" : "=&wa" (ret) : "wa" (a), "wa" (b)); + return ret; +} + +// Vectorizes min/max function which returns nan if any side is nan +#define C10_VSX_VEC_NAN_PROPAG(name, type, btype, func) \ + C10_ALWAYS_INLINE type name(const type& a, const type& b) { \ + type tmp = func(a, b); \ + btype nan_a = vec_cmpne(a, a); \ + btype nan_b = vec_cmpne(b, b); \ + tmp = vec_sel(tmp, a, nan_a); \ + return vec_sel(tmp, b, nan_b); \ + } + +C10_VSX_VEC_NAN_PROPAG(vec_min_nan2, vfloat32, vbool32, vec_min) +C10_VSX_VEC_NAN_PROPAG(vec_max_nan2, vfloat32, vbool32, vec_max) +C10_VSX_VEC_NAN_PROPAG(vec_min_nan2, vfloat64, vbool64, vec_min) +C10_VSX_VEC_NAN_PROPAG(vec_max_nan2, vfloat64, vbool64, vec_max) + +#undef C10_VSX_VEC_NAN_PROPAG + +#define DEFINE_MEMBER_UNARY_OP(op, op_type, func) \ + Vectorized C10_ALWAYS_INLINE op() const { \ + return Vectorized{func(_vec0), func(_vec1)}; \ + } + +#define DEFINE_MEMBER_OP(op, op_type, func) \ + Vectorized C10_ALWAYS_INLINE op(const Vectorized& other) const { \ + return Vectorized{ \ + func(_vec0, other._vec0), func(_vec1, other._vec1)}; \ + } + +#define DEFINE_MEMBER_BITWISE_OP(op, op_type, func) \ + Vectorized C10_ALWAYS_INLINE op(const Vectorized& other) const { \ + return Vectorized{ \ + func(_vecb0, other._vecb0), func(_vecb1, other._vecb1)}; \ + } + +#define DEFINE_MEMBER_TERNARY_OP(op, op_type, func) \ + Vectorized C10_ALWAYS_INLINE op( \ + const Vectorized& b, const Vectorized& c) const { \ + return Vectorized{ \ + func(_vec0, b._vec0, c._vec0), func(_vec1, b._vec1, c._vec1)}; \ + } + +#define DEFINE_MEMBER_EMULATE_BINARY_OP(op, op_type, binary_op) \ + Vectorized C10_ALWAYS_INLINE op(const Vectorized& b) const { \ + Vectorized::vec_internal_type ret_0; \ + Vectorized::vec_internal_type ret_1; \ + for (int i = 0; i < Vectorized::size() / 2; i++) { \ + ret_0[i] = _vec0[i] binary_op b._vec0[i]; \ + ret_1[i] = _vec1[i] binary_op b._vec1[i]; \ + } \ + return Vectorized{ret_0, ret_1}; \ + } + + +#define DEFINE_MEMBER_OP_AND_ONE(op, op_type, func) \ + Vectorized C10_ALWAYS_INLINE op(const Vectorized& other) const { \ + using vvtype = Vectorized::vec_internal_type; \ + const vvtype v_one = vec_splats(static_cast(1.0)); \ + vvtype ret0 = (vvtype)func(_vec0, other._vec0); \ + vvtype ret1 = (vvtype)func(_vec1, other._vec1); \ + return Vectorized{vec_and(ret0, v_one), vec_and(ret1, v_one)}; \ + } + +#define DEFINE_CLAMP_FUNCS(operand_type) \ + template <> \ + Vectorized C10_ALWAYS_INLINE clamp( \ + const Vectorized& a, \ + const Vectorized& min, \ + const Vectorized& max) { \ + return Vectorized{ \ + vec_min_nan(vec_max_nan(a.vec0(), min.vec0()), max.vec0()), \ + vec_min_nan(vec_max_nan(a.vec1(), min.vec1()), max.vec1())}; \ + } \ + template <> \ + Vectorized C10_ALWAYS_INLINE clamp_min( \ + const Vectorized& a, const Vectorized& min) { \ + return Vectorized{ \ + vec_max_nan(a.vec0(), min.vec0()), \ + vec_max_nan(a.vec1(), min.vec1())}; \ + } \ + template <> \ + Vectorized C10_ALWAYS_INLINE clamp_max( \ + const Vectorized& a, const Vectorized& max) { \ + return Vectorized{ \ + vec_min_nan(a.vec0(), max.vec0()), \ + vec_min_nan(a.vec1(), max.vec1())}; \ + } + +#define DEFINE_REINTERPRET_CAST_FUNCS( \ + first_type, cast_type, cast_inner_vector_type) \ + template <> \ + C10_ALWAYS_INLINE Vectorized cast( \ + const Vectorized& src) { \ + return Vectorized{(cast_inner_vector_type)src.vec0(), \ + (cast_inner_vector_type)src.vec1()}; \ + } + +#define DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(first_type) \ + DEFINE_REINTERPRET_CAST_FUNCS(first_type, double, vfloat64) \ + DEFINE_REINTERPRET_CAST_FUNCS(first_type, float, vfloat32) \ + DEFINE_REINTERPRET_CAST_FUNCS(first_type, int64_t, vint64) \ + DEFINE_REINTERPRET_CAST_FUNCS(first_type, int32_t, vint32) \ + DEFINE_REINTERPRET_CAST_FUNCS(first_type, int16_t, vint16) + +// it can be used to emulate blend faster +constexpr int blendChoice(uint32_t mask, uint32_t half1 = 0xF, uint32_t half2 = 0xF0) { + uint32_t none = 0; + uint32_t both = half1 | half2; + // clamp it between 0 and both + mask = mask & both; + // return (a._vec0, a._vec1) + if (mask == none) return 0; + // return (b._vec0,b._vec1) + else if (mask == both) + return 1; + // return (b._vec0,a._vec1) + else if (mask == half1) + return 2; + // return (a._vec0,b._vec1) + else if (mask == half2) + return 3; + // return (*_vec0,a._vec1) + else if (mask > 0 && mask < half1) + return 4; + // return (*_vec0,b._vec1) + else if ((mask & half2) == half2) + return 5; + // return (a._vec0,*_vec1) + else if ((mask & half1) == 0 && mask > half1) + return 6; + // return (b._vec0,*_vec1) + else if ((mask & half1) == half1 && mask > half1) + return 7; + // return (*_vec0,*_vec1) + return 8; +} + +// it can be used to emulate blend faster +constexpr int blendChoiceDbl(uint32_t mask) { + // clamp it 0 and 0xF + return blendChoice(mask, 0x3, 0xC); +} + +constexpr vbool32 VsxMask1(uint32_t mask) { + uint32_t g0 = (mask & 1) * 0xffffffff; + uint32_t g1 = ((mask & 2) >> 1) * 0xffffffff; + uint32_t g2 = ((mask & 4) >> 2) * 0xffffffff; + uint32_t g3 = ((mask & 8) >> 3) * 0xffffffff; + return (vbool32){g0, g1, g2, g3}; +} + +constexpr vbool32 VsxMask2(uint32_t mask) { + uint32_t mask2 = (mask & 0xFF) >> 4; + return VsxMask1(mask2); +} + +constexpr vbool64 VsxDblMask1(uint32_t mask) { + uint64_t g0 = (mask & 1) * 0xffffffffffffffff; + uint64_t g1 = ((mask & 2) >> 1) * 0xffffffffffffffff; + return (vbool64){g0, g1}; +} + +constexpr vbool64 VsxDblMask2(uint32_t mask) { + uint32_t mask2 = (mask & 0xF) >> 2; + return VsxDblMask1(mask2); +} + +constexpr int maskForComplex(uint32_t mask) { + mask = mask & 0xF; + int complex_mask = 0; + if (mask & 1) complex_mask |= 3; + if (mask & 2) complex_mask |= (3 << 2); + if (mask & 4) complex_mask |= (3 << 4); + if (mask & 8) complex_mask |= (3 << 6); + return complex_mask; +} + +constexpr int maskForComplexDbl(uint32_t mask) { + mask = mask & 0x3; + int complex_mask = 0; + if (mask & 1) complex_mask |= 3; + if (mask & 2) complex_mask |= (3 << 2); + return complex_mask; +} + +constexpr int blendChoiceComplex(uint32_t mask) { + return blendChoice(maskForComplex(mask)); +} + +constexpr int blendChoiceComplexDbl(uint32_t mask) { + return blendChoiceDbl(maskForComplexDbl(mask)); +} + +constexpr vbool32 VsxComplexMask1(uint32_t mask) { + return VsxMask1(maskForComplex(mask)); +} + +constexpr vbool32 VsxComplexMask2(uint32_t mask) { + uint32_t mask2 = (mask & 0xF) >> 2; + return VsxMask1(maskForComplex(mask2)); +} + +constexpr vbool64 VsxComplexDblMask1(uint32_t mask) { return VsxDblMask1(mask); } + +constexpr vbool64 VsxComplexDblMask2(uint32_t mask) { + uint32_t mask2 = (mask & 0xF) >> 2; + return VsxDblMask1(mask2); +} + +// constants +namespace at { +namespace vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { +// +constexpr int offset0 = 0; +constexpr int offset16 = 16; + +// #Constants +const vuint8 mask_zero_bits = vuint8{128, 128, 128, 128, 128, 128, 128, 128, + 128, 128, 128, 128, 96, 64, 32, 0}; + +const vuint8 swap_mask = + vuint8{4, 5, 6, 7, 0, 1, 2, 3, 12, 13, 14, 15, 8, 9, 10, 11}; + +const vint32 v0x7f = vec_splats(0x7f); +const vint32 vi_0 = vec_splats((int)(0)); +const vint32 vi_1 = vec_splats((int)1); +const vint32 vi_2 = vec_splats((int)2); +const vint32 vi_4 = vec_splats((int)4); +const vint32 vi_inv1 = vec_splats((int)~1); +const vuint32 vu_29 = vec_splats(29u); +const vuint32 vu_23 = vec_splats(23u); + +const vbool32 inv_mant_mask = (vbool32)vec_splats((unsigned int)~0xff800000); +const vbool32 sign_mask = (vbool32)vec_splats((int)0x80000000); +const vbool32 real_mask = vbool32{0xFFFFFFFF, 0x0, 0xFFFFFFFF, 0x0}; +const vbool32 imag_mask = vbool32{0x0, 0xFFFFFFFF, 0x0, 0xFFFFFFFF}; +const vbool32 isign_mask = vbool32{0x0, 0x80000000, 0x0, 0x80000000}; +const vbool32 rsign_mask = vbool32{0x80000000, 0x0, 0x80000000, 0x0}; + +const vbool64 vd_sign_mask = vbool64{0x8000000000000000, 0x8000000000000000}; +const vbool64 vd_imag_mask = vbool64{0x0, 0xFFFFFFFFFFFFFFFF}; +const vbool64 vd_real_mask = vbool64{0xFFFFFFFFFFFFFFFF, 0x0}; +const vbool64 vd_isign_mask = vbool64{0x0, 0x8000000000000000}; +const vbool64 vd_rsign_mask = vbool64{0x8000000000000000, 0x0}; + +const vfloat32 zero = vec_splats(0.f); +const vfloat32 half = vec_splats(0.5f); +const vfloat32 one = vec_splats(1.f); +const vfloat32 two = vec_splats(2.0f); +const vfloat32 _4div_pi = vec_splats(1.27323954473516f); +const vfloat32 v_inf = (vfloat32)vec_splats(0x7f800000u); +const vfloat32 v_minus_inf = vfloat32{ 0xff800000u, 0xff800000u, 0xff800000u, 0xff800000u }; +const vfloat32 v_nan = (vfloat32)vec_splats(0x7fffffff); +const vfloat32 log10e_inv = vec_splats(0.43429448190325176f); +const vfloat32 log2e_inv = vec_splats(1.4426950408889634f); +const vfloat32 log2eB_inv = vec_splats(1.442695036924675f); +const vfloat32 cephes_SQRTHF = vec_splats(0.707106781186547524f); +const vfloat32 coscof_p0 = vec_splats(2.443315711809948E-005f); +const vfloat32 coscof_p1 = vec_splats(-1.388731625493765E-003f); +const vfloat32 coscof_p2 = vec_splats(4.166664568298827E-002f); +const vfloat32 exp_hi = vec_splats(104.f); +const vfloat32 exp_lo = vec_splats(-104.f); +const vfloat32 exp_p0 = vec_splats(0.000198527617612853646278381f); +const vfloat32 exp_p1 = vec_splats((0.00139304355252534151077271f)); +const vfloat32 exp_p2 = vec_splats(0.00833336077630519866943359f); +const vfloat32 exp_p3 = vec_splats(0.0416664853692054748535156f); +const vfloat32 exp_p4 = vec_splats(0.166666671633720397949219f); +const vfloat32 exp_p5 = vec_splats(0.5f); +const vfloat32 log_p0 = vec_splats(7.0376836292E-2f); +const vfloat32 log_p1 = vec_splats(-1.1514610310E-1f); +const vfloat32 log_p2 = vec_splats(1.1676998740E-1f); +const vfloat32 log_p3 = vec_splats(-1.2420140846E-1f); +const vfloat32 log_p4 = vec_splats(+1.4249322787E-1f); +const vfloat32 log_p5 = vec_splats(-1.6668057665E-1f); +const vfloat32 log_p6 = vec_splats(+2.0000714765E-1f); +const vfloat32 log_p7 = vec_splats(-2.4999993993E-1f); +const vfloat32 log_p8 = vec_splats(+3.3333331174E-1f); +const vfloat32 log_q1 = vec_splats(-2.12194440e-4f); +const vfloat32 log_q2 = vec_splats(0.693359375f); +const vfloat32 max_logf = vec_splats(88.02969187150841f); +const vfloat32 max_numf = vec_splats(1.7014117331926442990585209174225846272e38f); +const vfloat32 min_inf = (vfloat32)vec_splats(0xff800000u); +const vfloat32 min_norm_pos = (vfloat32)vec_splats(0x0800000u); +const vfloat32 minus_cephes_dp1 = vec_splats(-0.78515625f); +const vfloat32 minus_cephes_dp2 = vec_splats(-2.4187564849853515625e-4f); +const vfloat32 minus_cephes_dp3 = vec_splats(-3.77489497744594108e-8f); +const vfloat32 negln2f_hi = vec_splats(-0.693145751953125f); +const vfloat32 negln2f_lo = vec_splats(-1.428606765330187045e-06f); +const vfloat32 p0 = vec_splats(2.03721912945E-4f); +const vfloat32 p1 = vec_splats(8.33028376239E-3f); +const vfloat32 p2 = vec_splats(1.66667160211E-1f); +const vfloat32 sincof_p0 = vec_splats(-1.9515295891E-4f); +const vfloat32 sincof_p1 = vec_splats(8.3321608736E-3f); +const vfloat32 sincof_p2 = vec_splats(-1.6666654611E-1f); +const vfloat32 tanh_0p625 = vec_splats(0.625f); +const vfloat32 tanh_half_max = vec_splats(44.014845935754205f); +const vfloat32 tanh_p0 = vec_splats(-5.70498872745E-3f); +const vfloat32 tanh_p1 = vec_splats(2.06390887954E-2f); +const vfloat32 tanh_p2 = vec_splats(-5.37397155531E-2f); +const vfloat32 tanh_p3 = vec_splats(1.33314422036E-1f); +const vfloat32 tanh_p4 = vec_splats(-3.33332819422E-1f); +const vfloat32 vcheck = vec_splats((float)(1LL << 24)); +const vfloat32 imag_one = vfloat32{0.f, 1.f, 0.f, 1.f}; +const vfloat32 imag_half = vfloat32{0.f, 0.5f, 0.f, 0.5f}; +const vfloat32 sqrt2_2 = vfloat32{0.70710676908493042f, 0.70710676908493042, + 0.70710676908493042, 0.70710676908493042}; +const vfloat32 pi_2 = vfloat32{M_PI / 2, 0.0, M_PI / 2, 0.0}; +const vfloat32 vf_89 = vfloat32{89.f, 89.f, 89.f, 89.f}; +const vfloat64 vd_one = vec_splats(1.0); +const vfloat64 vd_zero = vec_splats(0.0); +const vfloat64 vd_log10e_inv = vec_splats(0.43429448190325176); +const vfloat64 vd_log2e_inv = vec_splats(1.4426950408889634); +const vfloat64 vd_imag_one = vfloat64{0.0, 1.0}; +const vfloat64 vd_imag_half = vfloat64{0.0, 0.5}; +const vfloat64 vd_sqrt2_2 = vfloat64{0.70710678118654757, 0.70710678118654757}; +const vfloat64 vd_pi_2 = vfloat64{M_PI / 2.0, 0.0}; + +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/zarch/vec256_zarch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/zarch/vec256_zarch.h new file mode 100644 index 0000000000000000000000000000000000000000..7c2932b3aab7cede71c3054729ffdd914e1e9754 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec256/zarch/vec256_zarch.h @@ -0,0 +1,2899 @@ +#include +#include +#include +#include +#include +#if defined(__clang__) +#include +#elif defined(__GNUC__) || defined(__GNUG__) +#include +#include +#endif +#include +#include +#include + +namespace at { +namespace vec { + +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +template +constexpr bool is_zarch_implemented() { + return ( + std::is_same_v || std::is_same_v || + std::is_same_v || std::is_same_v || + std::is_same_v || std::is_same_v || + std::is_same_v || std::is_same_v); +} + +template +constexpr bool is_zarch_implemented_quant() { + return ( + std::is_same_v || + std::is_same_v || + std::is_same_v); +} + +template +constexpr bool is_zarch_implemented_complex() { + return std::is_same_v> || + std::is_same_v>; +} + +constexpr int offset0 = 0; +constexpr int offset16 = 16; + +template +struct VecBinaryType { + using type __attribute__((vector_size(16))) = uintmax_t; +}; + +template <> +struct VecBinaryType<8> { + using type = __attribute__((vector_size(16))) unsigned long long; +}; + +template <> +struct VecBinaryType<4> { + using type = __attribute__((vector_size(16))) unsigned int; +}; + +template <> +struct VecBinaryType<2> { + using type = __attribute__((vector_size(16))) unsigned short; +}; + +template <> +struct VecBinaryType<1> { + using type = __attribute__((vector_size(16))) unsigned char; +}; + +template +struct VecInnerType { + using Type __attribute__((vector_size(16))) = T; + using BinaryType = typename VecBinaryType::type; + using ElementType = T; + static constexpr int size = 16 / sizeof(T); +}; + +// define for int64_t properly for load +template <> +struct VecInnerType { + using Type = __attribute__((vector_size(16))) signed long long; + using ElementType = signed long long; + using BinaryType = typename VecBinaryType::type; + static constexpr int size = 16 / sizeof(signed long long); +}; + +template +using ZSimdVect = typename VecInnerType::Type; +template +using ZSimdVectBinary = typename VecInnerType::BinaryType; +template +using ZSimdVectElement = typename VecInnerType::ElementType; + +constexpr int blendChoiceInner( + const uint64_t mask, + const uint64_t half1 = 0xF, + const uint64_t half2 = 0xF0) { + uint64_t none = 0; + uint64_t both = half1 | half2; + // clamp it between 0 and both + auto res_mask = mask & both; + // return (a._vec0, a._vec1) + if (res_mask == none) + return 0; + // return (b._vec0,b._vec1) + else if (res_mask == both) + return 1; + // return (b._vec0, a._vec1) + else if (res_mask == half1) + return 2; + // return (a._vec0,b._vec1) + else if (res_mask == half2) + return 3; + // return (*_vec0,a._vec1) + else if (res_mask > 0 && res_mask < half1) + return 4; + // return (*_vec0,b._vec1) + else if ((res_mask & half2) == half2) + return 5; + // return (a._vec0,*_vec1) + else if ((res_mask & half1) == 0 && res_mask > half1) + return 6; + // return (b._vec0,*_vec1) + else if ((res_mask & half1) == half1 && res_mask > half1) + return 7; + // return (*_vec0,*_vec1) + return 8; +} + +// it can be used to emulate blend faster +template +constexpr int blendChoice(const uint64_t mask) { + static_assert(Z < 1 || Z > 8, "not implemented"); + return blendChoiceInner(mask); +} + +template <> +constexpr int blendChoice<1>(const uint64_t mask) { + return blendChoiceInner(mask, 0x0000FFFF, 0xFFFF0000); +} + +template <> +constexpr int blendChoice<2>(const uint64_t mask) { + return blendChoiceInner(mask, 0x00FF, 0xFF00); +} + +template <> +constexpr int blendChoice<4>(const uint64_t mask) { + return blendChoiceInner(mask, 0xF, 0xF0); +} + +template <> +constexpr int blendChoice<8>(const uint64_t mask) { + // clamp it 0 and 0xF + return blendChoiceInner(mask, 0x3, 0xC); +} + +template +constexpr auto GetMask1(const uint64_t mask) { + return typename VecBinaryType::type{}; +} + +template +constexpr auto GetMask2(const uint64_t mask) { + return typename VecBinaryType::type{}; +} + +template <> +constexpr auto GetMask1<1>(const uint64_t mask) { + constexpr uint8_t t = (int)0xFF; + uint8_t g0 = (mask & 1) * t; + uint8_t g1 = ((mask & 2) >> 1) * t; + uint8_t g2 = ((mask & 4) >> 2) * t; + uint8_t g3 = ((mask & 8) >> 3) * t; + uint8_t g4 = ((mask & 16) >> 4) * t; + uint8_t g5 = ((mask & 32) >> 5) * t; + uint8_t g6 = ((mask & 64) >> 6) * t; + uint8_t g7 = ((mask & 128) >> 7) * t; + uint8_t g8 = ((mask & 256) >> 8) * t; + uint8_t g9 = ((mask & 512) >> 9) * t; + uint8_t g10 = ((mask & 1024) >> 10) * t; + uint8_t g11 = ((mask & 2048) >> 11) * t; + uint8_t g12 = ((mask & 4096) >> 12) * t; + uint8_t g13 = ((mask & 8192) >> 13) * t; + uint8_t g14 = ((mask & 16384) >> 14) * t; + uint8_t g15 = ((mask & 32768) >> 15) * t; + return (typename VecBinaryType<1>::type){ + g0, g1, g2, g3, g4, g5, g6, g7, g8, g9, g10, g11, g12, g13, g14, g15}; +} + +template <> +constexpr auto GetMask2<1>(const uint64_t mask) { + uint64_t mask2 = (mask & 0xFFFFFFFF) >> 16; + return GetMask1<1>(mask2); +} + +template <> +constexpr auto GetMask1<2>(const uint64_t mask) { + constexpr uint16_t t = (int)0xFFFF; + uint16_t g0 = (mask & 1) * t; + uint16_t g1 = ((mask & 2) >> 1) * t; + uint16_t g2 = ((mask & 4) >> 2) * t; + uint16_t g3 = ((mask & 8) >> 3) * t; + uint16_t g4 = ((mask & 16) >> 4) * t; + uint16_t g5 = ((mask & 32) >> 5) * t; + uint16_t g6 = ((mask & 64) >> 6) * t; + uint16_t g7 = ((mask & 128) >> 7) * t; + return (typename VecBinaryType<2>::type){g0, g1, g2, g3, g4, g5, g6, g7}; +} + +template <> +constexpr auto GetMask2<2>(const uint64_t mask) { + uint64_t mask2 = (mask & 0xFFFF) >> 8; + return GetMask1<2>(mask2); +} + +template <> +constexpr auto GetMask1<4>(const uint64_t mask) { + uint32_t g0 = (mask & 1) * 0xffffffff; + uint32_t g1 = ((mask & 2) >> 1) * 0xffffffff; + uint32_t g2 = ((mask & 4) >> 2) * 0xffffffff; + uint32_t g3 = ((mask & 8) >> 3) * 0xffffffff; + return (typename VecBinaryType<4>::type){g0, g1, g2, g3}; +} + +template <> +constexpr auto GetMask2<4>(const uint64_t mask) { + uint64_t mask2 = (mask & 0xFF) >> 4; + return GetMask1<4>(mask2); +} + +template <> +constexpr auto GetMask1<8>(const uint64_t mask) { + uint64_t g0 = (mask & 1) * 0xffffffffffffffff; + uint64_t g1 = ((mask & 2) >> 1) * 0xffffffffffffffff; + return (typename VecBinaryType<8>::type){g0, g1}; +} + +template <> +constexpr auto GetMask2<8>(const uint64_t mask) { + uint64_t mask2 = (mask & 0xF) >> 2; + return GetMask1<8>(mask2); +} + +template +constexpr int maskForComplex(uint32_t mask) { + return 0; +} + +template <> +constexpr int maskForComplex<8>(uint32_t mask) { + mask = mask & 0xF; + int complex_mask = 0; + if (mask & 1) + complex_mask |= 3; + if (mask & 2) + complex_mask |= (3 << 2); + if (mask & 4) + complex_mask |= (3 << 4); + if (mask & 8) + complex_mask |= (3 << 6); + return complex_mask; +} + +template <> +constexpr int maskForComplex<16>(uint32_t mask) { + mask = mask & 0x3; + int complex_mask = 0; + if (mask & 1) + complex_mask |= 3; + if (mask & 2) + complex_mask |= (3 << 2); + return complex_mask; +} + +template > +constexpr int blend_choice() { + return 0xAA; +} + +template <> +constexpr int blend_choice>() { + return 0x0A; +} + +constexpr int64_t allbitset(int16_t x) { + int64_t onex = 1; + return (onex << x) - onex; +} + +namespace { /* unnamed namespace */ + +ZSimdVect vec_mergee(ZSimdVect x, ZSimdVect y) { + constexpr ZSimdVectBinary mergee_mask{ + 0, 1, 2, 3, 16, 17, 18, 19, 8, 9, 10, 11, 24, 25, 26, 27}; + return vec_perm(x, y, mergee_mask); +} + +ZSimdVect vec_mergee(ZSimdVect x, ZSimdVect y) { + return vec_mergeh(x, y); +} + +ZSimdVect vec_mergeo(ZSimdVect x, ZSimdVect y) { + constexpr ZSimdVectBinary mergeo_mask{ + 4, 5, 6, 7, 20, 21, 22, 23, 12, 13, 14, 15, 28, 29, 30, 31}; + return vec_perm(x, y, mergeo_mask); +} + +ZSimdVect vec_mergeo(ZSimdVect x, ZSimdVect y) { + return vec_mergel(x, y); +} + +} /* unnamed namespace */ + +// +template +constexpr auto GetBpermZeroMask() { + return ZSimdVectBinary{ + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 96, + 64, + 32, + 0}; +} + +template <> +constexpr auto GetBpermZeroMask() { + return ZSimdVectBinary{ + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 128, + 64, + 0}; +} + +constexpr auto GetSwapMaskFloat() { + return ZSimdVectBinary{ + 4, 5, 6, 7, 0, 1, 2, 3, 12, 13, 14, 15, 8, 9, 10, 11}; +} + +template +struct Vectorized()>> { + public: + using value_type = T; + using vtype = ZSimdVect; + using vmaskType = ZSimdVectBinary; + using size_type = int; + // because of gcc inconsistency for int64_t we are obliged to use this, not + // value_type + using ElementType = ZSimdVectElement; + using vinner_data = std::pair; + + private: + vtype _vec0; + vtype _vec1; + + public: + static constexpr size_type size() { + return VECTOR_WIDTH / sizeof(ElementType); + } + Vectorized() {} + + C10_ALWAYS_INLINE Vectorized(vtype v) : _vec0{v}, _vec1{v} {} + C10_ALWAYS_INLINE Vectorized(const vinner_data &v) : _vec0{v.first}, _vec1{v.second} {} + C10_ALWAYS_INLINE Vectorized(vtype v1, vtype v2) : _vec0{v1}, _vec1{v2} {} + C10_ALWAYS_INLINE Vectorized(T s) + : _vec0{vec_splats((ElementType)s)}, _vec1{vec_splats((ElementType)s)} {} + + template + struct LoaduHelper { + static Vectorized C10_ALWAYS_INLINE + loadu(const U* ptr, int count = size()) { + __at_align__ ElementType tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(ElementType)); + + return { + vec_xl(offset0, &(tmp_values[0])), + vec_xl(offset16, &(tmp_values[0]))}; + } + }; + + template + struct LoaduHelper { + static Vectorized C10_ALWAYS_INLINE + loadu(const ElementType* ptr, int count = size()) { + if (count == size()) { + return { + vec_xl(offset0, ptr), + vec_xl(offset16, ptr)}; + } + + __at_align__ ElementType tmp_values[size()] = {}; + std::memcpy(tmp_values, ptr, std::min(count, size()) * sizeof(ElementType)); + + return { + vec_xl(offset0, &(tmp_values[0])), + vec_xl(offset16, &(tmp_values[0]))}; + } + }; + + template + static Vectorized C10_ALWAYS_INLINE + loadu(const U* ptr, int count = size()) { + return LoaduHelper::loadu(ptr, count); + } + + template + static Vectorized C10_ALWAYS_INLINE + loadu_one_fourth(const U* ptr) { + // load only first 8 bytes + // only intended to be used with uint8_t + return loadu(ptr, 8 / sizeof(ElementType)); + } + + template + struct StoreHelper { + static void C10_ALWAYS_INLINE store(const Vectorized &vec, U* ptr, int count = size()) { + if (count > 0) { + __at_align__ ElementType tmp_values[size()]; + vec_xst(vec._vec0, offset0, &(tmp_values[0])); + vec_xst(vec._vec1, offset16, &(tmp_values[0])); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(ElementType)); + } + } + }; + + template + struct StoreHelper { + static void C10_ALWAYS_INLINE store(const Vectorized &vec, ElementType* ptr, int count = size()) { + if (count == size()) { + vec_xst(vec._vec0, offset0, ptr); + vec_xst(vec._vec1, offset16, ptr); + } else if (count > 0) { + __at_align__ ElementType tmp_values[size()]; + vec_xst(vec._vec0, offset0, &(tmp_values[0])); + vec_xst(vec._vec1, offset16, &(tmp_values[0])); + std::memcpy( + ptr, tmp_values, std::min(count, size()) * sizeof(ElementType)); + } + } + }; + + template + void C10_ALWAYS_INLINE store(U* ptr, int count = size()) const { + return StoreHelper::store(*this, ptr, count); + } + + C10_ALWAYS_INLINE const vtype& vec0() const { + return _vec0; + } + + C10_ALWAYS_INLINE const vtype& vec1() const { + return _vec1; + } + + C10_ALWAYS_INLINE vinner_data data() const { + return std::make_pair<>(_vec0, _vec1); + } + + C10_ALWAYS_INLINE operator vinner_data() const { + return data(); + } + + C10_ALWAYS_INLINE const vmaskType vecb0() const { + return (vmaskType)_vec0; + } + C10_ALWAYS_INLINE const vmaskType vecb1() const { + return (vmaskType)_vec1; + } + + static Vectorized C10_ALWAYS_INLINE blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + return { + vec_sel(a._vec0, b._vec0, mask.vecb0()), + vec_sel(a._vec1, b._vec1, mask.vecb1())}; + } + + template = 0> + C10_ALWAYS_INLINE Vectorized(T s1, T s2, T s3, T s4) + : _vec0{s1, s2}, _vec1{s3, s4} {} + + template = 0> + C10_ALWAYS_INLINE Vectorized(T s1, T s2, T s3, T s4, T s5, T s6, T s7, T s8) + : _vec0{s1, s2, s3, s4}, _vec1{s5, s6, s7, s8} {} + + template = 0> + C10_ALWAYS_INLINE Vectorized( + T s1, + T s2, + T s3, + T s4, + T s5, + T s6, + T s7, + T s8, + T s9, + T s10, + T s11, + T s12, + T s13, + T s14, + T s15, + T s16) + : _vec0{s1, s2, s3, s4, s5, s6, s7, s8}, + _vec1{s9, s10, s11, s12, s13, s14, s15, s16} {} + + template = 0> + C10_ALWAYS_INLINE Vectorized( + T s1, + T s2, + T s3, + T s4, + T s5, + T s6, + T s7, + T s8, + T s9, + T s10, + T s11, + T s12, + T s13, + T s14, + T s15, + T s16, + T s17, + T s18, + T s19, + T s20, + T s21, + T s22, + T s23, + T s24, + T s25, + T s26, + T s27, + T s28, + T s29, + T s30, + T s31, + T s32) + : _vec0{s1, s2, s3, s4, s5, s6, s7, s8, s9, s10, s11, s12, s13, s14, s15, s16}, + _vec1{ + s17, + s18, + s19, + s20, + s21, + s22, + s23, + s24, + s25, + s26, + s27, + s28, + s29, + s30, + s31, + s32} {} + + template + static std::enable_if_t> arange( + T base = 0, + step_t step = static_cast(1)) { + return Vectorized(base, base + step, base + 2 * step, base + 3 * step); + } + + template + static std::enable_if_t> arange( + T base = 0, + step_t step = static_cast(1)) { + return Vectorized( + base, + base + step, + base + 2 * step, + base + 3 * step, + base + 4 * step, + base + 5 * step, + base + 6 * step, + base + 7 * step); + } + + template + static std::enable_if_t> arange( + T base = 0, + step_t step = static_cast(1)) { + return Vectorized( + base, + base + step, + base + 2 * step, + base + 3 * step, + base + 4 * step, + base + 5 * step, + base + 6 * step, + base + 7 * step, + base + 8 * step, + base + 9 * step, + base + 10 * step, + base + 11 * step, + base + 12 * step, + base + 13 * step, + base + 14 * step, + base + 15 * step); + } + + template + static std::enable_if_t> arange( + T base = 0, + step_t step = static_cast(1)) { + return Vectorized( + base, + base + step, + base + 2 * step, + base + 3 * step, + base + 4 * step, + base + 5 * step, + base + 6 * step, + base + 7 * step, + base + 8 * step, + base + 9 * step, + base + 10 * step, + base + 11 * step, + base + 12 * step, + base + 13 * step, + base + 14 * step, + base + 15 * step, + base + 16 * step, + base + 17 * step, + base + 18 * step, + base + 19 * step, + base + 20 * step, + base + 21 * step, + base + 22 * step, + base + 23 * step, + base + 24 * step, + base + 25 * step, + base + 26 * step, + base + 27 * step, + base + 28 * step, + base + 29 * step, + base + 30 * step, + base + 31 * step); + } + + // blend section + template + static std::enable_if_t(mask) == 0, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + return a; + } + + template + static std::enable_if_t(mask) == 1, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + return b; + } + + template + static std::enable_if_t(mask) == 2, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + return {b._vec0, a._vec1}; + } + + template + static std::enable_if_t(mask) == 3, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + return {a._vec0, b._vec1}; + } + + template + static std::enable_if_t(mask) == 4, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + const vmaskType mask_1st = GetMask1(mask); + return {(vtype)vec_sel(a._vec0, b._vec0, mask_1st), a._vec1}; + } + + template + static std::enable_if_t(mask) == 5, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + const vmaskType mask_1st = GetMask1(mask); + return {(vtype)vec_sel(a._vec0, b._vec0, mask_1st), b._vec1}; + } + + template + static std::enable_if_t(mask) == 6, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + const vmaskType mask_2nd = GetMask2(mask); + // generated masks + return {a._vec0, (vtype)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + template + static std::enable_if_t(mask) == 7, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + const vmaskType mask_2nd = GetMask2(mask); + // generated masks + return {b._vec0, (vtype)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + template + static std::enable_if_t(mask) == 8, Vectorized> + C10_ALWAYS_INLINE blend(const Vectorized& a, const Vectorized& b) { + const vmaskType mask_1st = GetMask1(mask); + const vmaskType mask_2nd = GetMask2(mask); + return { + (vtype)vec_sel(a._vec0, b._vec0, mask_1st), + (vtype)vec_sel(a._vec1, b._vec1, mask_2nd)}; + } + + template + static inline std::enable_if_t<(Z >= C), Vectorized> set_inner( + const Vectorized& a, + const Vectorized& b, + size_t count) { + return b; + } + + template + static inline std::enable_if_t<(Z < C), Vectorized> set_inner( + const Vectorized& a, + const Vectorized& b, + size_t count) { + if (count == Z) + return blend(a, b); + else + return set_inner(a, b, count); + } + + static Vectorized set( + const Vectorized& a, + const Vectorized& b, + size_t count = size()) { + if (count == 0) + return a; + return set_inner<1, size()>(a, b, count); + } + + const ElementType& operator[](int idx) const = delete; + ElementType& operator[](int idx) = delete; + + Vectorized _not() const { + return {(vtype)vec_nor(vecb0(), vecb0()), (vtype)vec_nor(vecb1(), vecb1())}; + } + + Vectorized C10_ALWAYS_INLINE eq(const Vectorized& other) const { + return (*this == other) & Vectorized((T)1.0); + } + Vectorized C10_ALWAYS_INLINE ne(const Vectorized& other) const { + return (*this != other) & Vectorized((T)1.0); + } + Vectorized C10_ALWAYS_INLINE gt(const Vectorized& other) const { + return (*this > other) & Vectorized((T)1.0); + } + Vectorized C10_ALWAYS_INLINE ge(const Vectorized& other) const { + return (*this >= other) & Vectorized((T)1.0); + } + Vectorized C10_ALWAYS_INLINE lt(const Vectorized& other) const { + return (*this < other) & Vectorized((T)1.0); + } + Vectorized C10_ALWAYS_INLINE le(const Vectorized& other) const { + return (*this <= other) & Vectorized((T)1.0); + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized C10_ALWAYS_INLINE abs() const { + return {vec_abs(_vec0), vec_abs(_vec1)}; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized C10_ALWAYS_INLINE abs() const { + return {_vec0, _vec1}; + } + + Vectorized C10_ALWAYS_INLINE neg() const { + return {-_vec0, -_vec1}; + } + + Vectorized isnan() const { + auto x = *this; + auto ret = (x == x); + return ret._not(); + } + + bool has_inf_nan() const { + for (const auto i : c10::irange(size()/2)) { + if(_isnan(_vec0[i]) || _isinf(_vec0[i])) { + return true; + } + } + for (const auto i : c10::irange(size()/2)) { + if(_isnan(_vec1[i]) || _isinf(_vec1[i])) { + return true; + } + } + return false; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized angle() const { + auto tmp = blendv( + Vectorized(0), Vectorized(c10::pi), *this < Vectorized(0)); + return blendv(tmp, *this, isnan()); + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized angle() const { + return blendv( + Vectorized(0), Vectorized(c10::pi), *this < Vectorized(0)); + } + + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return Vectorized{0}; + } + Vectorized conj() const { + return *this; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + int zero_mask() const { + auto cmp = (*this == Vectorized(0)); + constexpr auto mask_zero_bits = GetBpermZeroMask(); + ZSimdVectBinary result0 = + vec_bperm_u128((ZSimdVectBinary)cmp.vecb0(), mask_zero_bits); + ZSimdVectBinary result1 = + vec_bperm_u128((ZSimdVectBinary)cmp.vecb1(), mask_zero_bits); + return (result0[0] | (result1[0] << (size() / 2))); + } + + Vectorized C10_ALWAYS_INLINE floor() const { + return {vec_floor(_vec0), vec_floor(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE ceil() const { + return {vec_ceil(_vec0), vec_ceil(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE round() const { + return {vec_round(_vec0), vec_round(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE rint() const { + return {vec_rint(_vec0), vec_rint(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE trunc() const { + return {vec_trunc(_vec0), vec_trunc(_vec1)}; + } + + Vectorized C10_ALWAYS_INLINE frac() const { + return *this - trunc(); + } + + Vectorized C10_ALWAYS_INLINE sqrt() const { + return {vec_sqrt(_vec0), vec_sqrt(_vec1)}; + } + Vectorized C10_ALWAYS_INLINE reciprocal() const { + return Vectorized((T)1) / (*this); + } + Vectorized C10_ALWAYS_INLINE rsqrt() const { + return sqrt().reciprocal(); + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + inline Vectorized mapOrdinary(float (*const f)(float)) const { + float a00 = f(_vec0[0]); + float a01 = f(_vec0[1]); + float a02 = f(_vec0[2]); + float a03 = f(_vec0[3]); + float a10 = f(_vec1[0]); + float a11 = f(_vec1[1]); + float a12 = f(_vec1[2]); + float a13 = f(_vec1[3]); + return Vectorized{a00, a01, a02, a03, a10, a11, a12, a13}; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + inline Vectorized mapOrdinary(double (*const f)(double)) const { + return Vectorized(f(_vec0[0]), f(_vec0[1]), f(_vec1[0]), f(_vec1[1])); + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + inline Vectorized mapOrdinary( + float (*const f)(float, float), + const Vectorized& b) const { + float a00 = f(_vec0[0], b._vec0[0]); + float a01 = f(_vec0[1], b._vec0[1]); + float a02 = f(_vec0[2], b._vec0[2]); + float a03 = f(_vec0[3], b._vec0[3]); + float a10 = f(_vec1[0], b._vec1[0]); + float a11 = f(_vec1[1], b._vec1[1]); + float a12 = f(_vec1[2], b._vec1[2]); + float a13 = f(_vec1[3], b._vec1[3]); + return Vectorized{a00, a01, a02, a03, a10, a11, a12, a13}; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + inline Vectorized mapOrdinary( + double (*const f)(double, double), + const Vectorized& b) const { + return Vectorized( + f(_vec0[0], b._vec0[0]), + f(_vec0[1], b._vec0[1]), + f(_vec1[0], b._vec1[0]), + f(_vec1[1], b._vec1[1])); + } + + template < + typename FloatOp, + typename DoubleOp, + typename U = T, + std::enable_if_t, int> = 0> + inline Vectorized mapSleef(FloatOp f, DoubleOp d) const { + vtype a0 = f(_vec0); + vtype a1 = f(_vec1); + return Vectorized{a0, a1}; + } + + template < + typename FloatOp, + typename DoubleOp, + typename U = T, + std::enable_if_t, int> = 0> + inline Vectorized mapSleef(FloatOp f, DoubleOp d) const { + return Vectorized(d(_vec0), d(_vec1)); + } + + template < + typename FloatOp, + typename DoubleOp, + typename U = T, + std::enable_if_t, int> = 0> + inline Vectorized mapSleef(FloatOp f, DoubleOp d, const Vectorized& b) + const { + vtype a0 = f(_vec0, b._vec0); + vtype a1 = f(_vec1, b._vec1); + return Vectorized{a0, a1}; + } + + template < + typename FloatOp, + typename DoubleOp, + typename U = T, + std::enable_if_t, int> = 0> + inline Vectorized mapSleef(FloatOp f, DoubleOp d, const Vectorized& b) + const { + return Vectorized(d(_vec0, b._vec0), d(_vec1, b._vec1)); + } + + Vectorized acos() const { + return mapSleef(Sleef_acosf4_u10, Sleef_acosd2_u10); + } + Vectorized asin() const { + return mapSleef(Sleef_asinf4_u10, Sleef_asind2_u10); + } + Vectorized atan() const { + return mapSleef(Sleef_atanf4_u10, Sleef_atand2_u10); + } + Vectorized atanh() const { + return mapSleef(Sleef_atanhf4_u10, Sleef_atanhd2_u10); + } + + Vectorized erf() const { + return mapSleef(Sleef_erff4_u10, Sleef_erfd2_u10); + } + Vectorized erfc() const { + return mapSleef(Sleef_erfcf4_u15, Sleef_erfcd2_u15); + } + + Vectorized exp() const { + return mapSleef(Sleef_expf4_u10, Sleef_expd2_u10); + } + Vectorized exp2() const { + return mapSleef(Sleef_exp2f4_u10, Sleef_exp2d2_u10); + } + Vectorized expm1() const { + return mapSleef(Sleef_expm1f4_u10, Sleef_expm1d2_u10); + } + Vectorized exp_u20() const { + return exp(); + } + + Vectorized log() const { + return mapSleef(Sleef_logf4_u10, Sleef_logd2_u10); + } + Vectorized log2() const { + return mapSleef(Sleef_log2f4_u10, Sleef_log2d2_u10); + } + Vectorized log10() const { + return mapSleef(Sleef_log10f4_u10, Sleef_log10d2_u10); + } + Vectorized log1p() const { + return mapSleef(Sleef_log1pf4_u10, Sleef_log1pd2_u10); + } + + Vectorized sin() const { + return mapSleef(Sleef_sinf4_u10, Sleef_sind2_u10); + } + Vectorized sinh() const { + return mapSleef(Sleef_sinhf4_u10, Sleef_sinhd2_u10); + } + Vectorized cos() const { + return mapSleef(Sleef_cosf4_u10, Sleef_cosd2_u10); + } + Vectorized cosh() const { + return mapSleef(Sleef_coshf4_u10, Sleef_coshd2_u10); + } + + Vectorized tan() const { + return mapSleef(Sleef_tanf4_u10, Sleef_tand2_u10); + } + Vectorized tanh() const { + return mapSleef(Sleef_tanhf4_u10, Sleef_tanhd2_u10); + } + + Vectorized lgamma() const { + return mapSleef(Sleef_lgammaf4_u10, Sleef_lgammad2_u10); + } + + Vectorized atan2(const Vectorized& b) const { + return mapSleef(Sleef_atan2f4_u10, Sleef_atan2d2_u10, b); + } + Vectorized copysign(const Vectorized& sign) const { + return mapSleef(Sleef_copysignf4, Sleef_copysignd2, sign); + } + Vectorized fmod(const Vectorized& q) const { + return mapSleef(Sleef_fmodf4, Sleef_fmodd2, q); + } + + Vectorized hypot(const Vectorized& b) const { + return mapSleef(Sleef_hypotf4_u05, Sleef_hypotd2_u05, b); + } + + Vectorized pow(const Vectorized& b) const { + return mapSleef(Sleef_powf4_u10, Sleef_powd2_u10, b); + } + + Vectorized nextafter(const Vectorized& b) const { + return mapSleef(Sleef_nextafterf4, Sleef_nextafterd2, b); + } + + Vectorized erfinv() const { + return mapOrdinary(calc_erfinv); + } + + Vectorized digamma() const { + return mapOrdinary(calc_digamma); + } + + Vectorized igamma(const Vectorized& x) const { + return mapOrdinary(calc_igamma, x); + } + + Vectorized igammac(const Vectorized& x) const { + return mapOrdinary(calc_igammac, x); + } + + Vectorized i0() const { + return mapOrdinary(calc_i0); + } + + Vectorized i0e() const { + return mapOrdinary(calc_i0e); + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized minimum(const Vectorized& other) const { + return {vec_min(_vec0, other._vec0), vec_min(_vec1, other._vec1)}; + } + + /* Propagates NaN if either input is a NaN. */ + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized minimum(const Vectorized& other) const { + Vectorized tmp = {vec_min(_vec0, other._vec0), vec_min(_vec1, other._vec1)}; + tmp = blendv(tmp, *this, isnan()); + return blendv(tmp, other, other.isnan()); + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized maximum(const Vectorized& other) const { + return {vec_max(_vec0, other._vec0), vec_max(_vec1, other._vec1)}; + } + + /* Propagates NaN if either input is a NaN. */ + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized maximum(const Vectorized& other) const { + Vectorized tmp = {vec_max(_vec0, other._vec0), vec_max(_vec1, other._vec1)}; + tmp = blendv(tmp, *this, isnan()); + return blendv(tmp, other, other.isnan()); + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized clamp_min(const Vectorized& min) const { + return {vec_max(_vec0, min._vec0), vec_max(_vec1, min._vec1)}; + } + + /* Keeps NaN if actual value is NaN */ + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized clamp_min(const Vectorized& min) const { + Vectorized tmp = {vec_max(_vec0, min._vec0), vec_max(_vec1, min._vec1)}; + return blendv(tmp, *this, isnan()); + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized clamp_max(const Vectorized& max) const { + return {vec_min(_vec0, max._vec0), vec_min(_vec1, max._vec1)}; + } + + /* Keeps NaN if actual value is NaN */ + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized clamp_max(const Vectorized& max) const { + Vectorized tmp = {vec_min(_vec0, max._vec0), vec_min(_vec1, max._vec1)}; + return blendv(tmp, *this, isnan()); + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized swapped() const { + auto swap_mask = GetSwapMaskFloat(); + vtype v0 = vec_perm(_vec0, _vec0, swap_mask); + vtype v1 = vec_perm(_vec1, _vec1, swap_mask); + return {v0, v1}; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized swapped() const { + vtype v0 = {_vec0[1], _vec0[0]}; + vtype v1 = {_vec1[1], _vec1[0]}; + return {v0, v1}; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + static Vectorized mergee(Vectorized& first, Vectorized& second) { + return { + vec_mergee(first._vec0, second._vec0), + vec_mergee(first._vec1, second._vec1)}; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + static Vectorized mergeo(Vectorized& first, Vectorized& second) { + return { + vec_mergeo(first._vec0, second._vec0), + vec_mergeo(first._vec1, second._vec1)}; + } + + static Vectorized horizontal_add_perm( + Vectorized& first, + Vectorized& second) { + // we will simulate it differently with 6 instructions total + // lets permute second so that we can add it getting horizontal sums + auto first_perm = first.swapped(); // 2perm + auto second_perm = second.swapped(); // 2perm + // summ + auto first_ret = first + first_perm; // 2add + auto second_ret = second + second_perm; // 2 add + // now lets choose evens + return mergee(first_ret, second_ret); // 2 mergee's + } + + static Vectorized horizontal_sub_perm( + Vectorized& first, + Vectorized& second) { + // we will simulate it differently with 6 instructions total + // lets permute second so that we can add it getting horizontal sums + auto first_perm = first.swapped(); // 2perm + auto second_perm = second.swapped(); // 2perm + // summ + auto first_ret = first - first_perm; // 2sub + auto second_ret = second - second_perm; // 2 sub + // now lets choose evens + return mergee(first_ret, second_ret); // 2 mergee's + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized mergee() const { + return {vec_mergee(_vec0, _vec0), vec_mergee(_vec1, _vec1)}; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized mergeo() const { + return {vec_mergeo(_vec0, _vec0), vec_mergeo(_vec1, _vec1)}; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized to_vec_float_helper() const { + int32_t values[8] = { + _vec0[0], + _vec0[1], + _vec0[2], + _vec0[3], + _vec0[4], + _vec0[5], + _vec0[6], + _vec0[7], + }; + + return Vectorized{ + values[0], values[1], values[2], values[3], + values[4], values[5], values[6], values[7] + }; + } + + template < + typename U = T, + std::enable_if_t, int> = 0> + Vectorized to_vec_uint8_helper() const { + // helper function for float to uint8_t conversion + uint8_t values[8] = { + static_cast(_vec0[0]), + static_cast(_vec0[1]), + static_cast(_vec0[2]), + static_cast(_vec0[3]), + static_cast(_vec1[0]), + static_cast(_vec1[1]), + static_cast(_vec1[2]), + static_cast(_vec1[3]), + }; + + return Vectorized{ + values[0], values[1], values[2], values[3], + values[4], values[5], values[6], values[7], + 0, 0, 0, 0, + 0, 0, 0, 0, + 0, 0, 0, 0, + 0, 0, 0, 0, + 0, 0, 0, 0, + 0, 0, 0, 0, + }; + } +}; + +#define ZVECTOR_OPERATORS(typex) \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec0() + b.vec0(), a.vec1() + b.vec1()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec0() - b.vec0(), a.vec1() - b.vec1()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec0() * b.vec0(), a.vec1() * b.vec1()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec0() / b.vec0(), a.vec1() / b.vec1()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{ \ + (Vectorized::vtype)(a.vecb0() & b.vecb0()), \ + (Vectorized::vtype)(a.vecb1() & b.vecb1())}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{ \ + (Vectorized::vtype)(a.vecb0() | b.vecb0()), \ + (Vectorized::vtype)(a.vecb1() | b.vecb1())}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{ \ + (Vectorized::vtype)(a.vecb0() ^ b.vecb0()), \ + (Vectorized::vtype)(a.vecb1() ^ b.vecb1())}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator==(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{ \ + vec_cmpeq(a.vec0(), b.vec0()), vec_cmpeq(a.vec1(), b.vec1())}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator!=(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{ \ + vec_cmpeq(a.vec0(), b.vec0()), vec_cmpeq(a.vec1(), b.vec1())} \ + ._not(); \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator>(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{ \ + vec_cmpgt(a.vec0(), b.vec0()), vec_cmpgt(a.vec1(), b.vec1())}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator>=(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{ \ + vec_cmpge(a.vec0(), b.vec0()), vec_cmpge(a.vec1(), b.vec1())}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator<(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{ \ + vec_cmplt(a.vec0(), b.vec0()), vec_cmplt(a.vec1(), b.vec1())}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator<=(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{ \ + vec_cmple(a.vec0(), b.vec0()), vec_cmple(a.vec1(), b.vec1())}; \ + } + +ZVECTOR_OPERATORS(float) +ZVECTOR_OPERATORS(double) +ZVECTOR_OPERATORS(int8_t) +ZVECTOR_OPERATORS(uint8_t) +ZVECTOR_OPERATORS(uint16_t) +ZVECTOR_OPERATORS(int16_t) +ZVECTOR_OPERATORS(int32_t) +ZVECTOR_OPERATORS(int64_t) + +#undef ZVECTOR_OPERATORS + +#define ZVECTOR_OPERATORS(typex) \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator<<(const Vectorized& a, const Vectorized& b) { \ + constexpr Vectorized::ElementType max_shift \ + = sizeof(Vectorized::ElementType) * CHAR_BIT; \ + \ + Vectorized::ElementType a_array[Vectorized::size()]; \ + Vectorized::ElementType b_array[Vectorized::size()]; \ + Vectorized::ElementType c_array[Vectorized::size()]; \ + \ + a.store(a_array); \ + b.store(b_array); \ + \ + for (int i = 0; i != Vectorized::size(); i++) { \ + typex shift = b_array[i]; \ + if ((static_cast>(shift) < 0) || (shift >= max_shift)) { \ + c_array[i] = 0; \ + } else { \ + c_array[i] = static_cast>(a_array[i]) << shift; \ + } \ + } \ + \ + return Vectorized::loadu(c_array); \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator>>(const Vectorized& a, const Vectorized& b) { \ + /* right shift value to retain sign bit for signed and no bits for unsigned */ \ + constexpr Vectorized::ElementType max_shift \ + = sizeof(typex) * CHAR_BIT - std::is_signed_v; \ + \ + Vectorized::ElementType a_array[Vectorized::size()]; \ + Vectorized::ElementType b_array[Vectorized::size()]; \ + Vectorized::ElementType c_array[Vectorized::size()]; \ + \ + a.store(a_array); \ + b.store(b_array); \ + \ + for (int i = 0; i != Vectorized::size(); i++) { \ + typex shift = b_array[i]; \ + if ((static_cast>(shift) < 0) || (shift >= max_shift)) { \ + c_array[i] = a_array[i] >> max_shift; \ + } else { \ + c_array[i] = a_array[i] >> shift; \ + } \ + } \ + \ + return Vectorized::loadu(c_array); \ + } \ + \ + template <> \ + inline Vectorized operator~(const Vectorized& a) { \ + return a._not(); \ + } + +ZVECTOR_OPERATORS(int8_t) +ZVECTOR_OPERATORS(uint8_t) +ZVECTOR_OPERATORS(uint16_t) +ZVECTOR_OPERATORS(int16_t) +ZVECTOR_OPERATORS(int32_t) +ZVECTOR_OPERATORS(int64_t) + +#undef ZVECTOR_OPERATORS + +#define DEFINE_MAXMIN_FUNCS(operand_type) \ + template <> \ + Vectorized inline maximum( \ + const Vectorized& a, const Vectorized& b) { \ + return a.maximum(b); \ + } \ + template <> \ + Vectorized inline minimum( \ + const Vectorized& a, const Vectorized& b) { \ + return a.minimum(b); \ + } + +#define DEFINE_CLAMP_MAXMIN_FUNCS(typex) \ + DEFINE_MAXMIN_FUNCS(typex) \ + template <> \ + Vectorized C10_ALWAYS_INLINE clamp_min( \ + const Vectorized& a, const Vectorized& min) { \ + return a.clamp_min(min); \ + } \ + template <> \ + Vectorized C10_ALWAYS_INLINE clamp_max( \ + const Vectorized& a, const Vectorized& max) { \ + return a.clamp_max(max); \ + } \ + template <> \ + Vectorized C10_ALWAYS_INLINE clamp( \ + const Vectorized& a, \ + const Vectorized& min, \ + const Vectorized& max) { \ + return clamp_max(clamp_min(a, min), max); \ + } + +DEFINE_CLAMP_MAXMIN_FUNCS(int8_t) +DEFINE_CLAMP_MAXMIN_FUNCS(uint8_t) +DEFINE_CLAMP_MAXMIN_FUNCS(int16_t) +DEFINE_CLAMP_MAXMIN_FUNCS(int32_t) +DEFINE_CLAMP_MAXMIN_FUNCS(int64_t) +DEFINE_CLAMP_MAXMIN_FUNCS(float) +DEFINE_CLAMP_MAXMIN_FUNCS(double) + +namespace { /* unnamed namespace */ + +#if !defined(vec_float) || __ARCH__ < 13 +#warning \ + "float->int and int->float conversion is simulated. compile for z15 for improved performance" +inline ZSimdVect vec_int_flt(const ZSimdVect x) { + return ZSimdVect{float(x[0]), float(x[1]), float(x[2]), float(x[3])}; +} +inline ZSimdVect vec_flt_int(const ZSimdVect x) { + return ZSimdVect{int(x[0]), int(x[1]), int(x[2]), int(x[3])}; +} +#else +#define vec_int_flt vec_float +#define vec_flt_int vec_signed +#endif + +Vectorized zvec_convert_to_float(const Vectorized& x) { + return {vec_int_flt(x.vec0()), vec_int_flt(x.vec1())}; +} + +Vectorized zvec_convert_to_int(const Vectorized& x) { + return {vec_flt_int(x.vec0()), vec_flt_int(x.vec1())}; +} + +Vectorized zvec_convert_to_float(const Vectorized& x) { + return {vec_double(x.vec0()), vec_double(x.vec1())}; +} + +Vectorized zvec_convert_to_int(const Vectorized& x) { + return {vec_signed(x.vec0()), vec_signed(x.vec1())}; +} + +} /* unnamed namespace */ + +template +Vectorized cast_zvector(const Vectorized& x) { + using cast_type = typename Vectorized::vtype; + return Vectorized{(cast_type)x.vec0(), (cast_type)x.vec1()}; +} + +template <> +Vectorized C10_ALWAYS_INLINE fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + return Vectorized{ + __builtin_s390_vfmasb(a.vec0(), b.vec0(), c.vec0()), + __builtin_s390_vfmasb(a.vec1(), b.vec1(), c.vec1())}; +} +template <> +Vectorized C10_ALWAYS_INLINE fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + return Vectorized{ + __builtin_s390_vfmadb(a.vec0(), b.vec0(), c.vec0()), + __builtin_s390_vfmadb(a.vec1(), b.vec1(), c.vec1())}; +} +template <> +Vectorized C10_ALWAYS_INLINE fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + return Vectorized{ + a.vec0() * b.vec0() + c.vec0(), a.vec1() * b.vec1() + c.vec1()}; +} +template <> +Vectorized C10_ALWAYS_INLINE fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + return Vectorized{ + a.vec0() * b.vec0() + c.vec0(), a.vec1() * b.vec1() + c.vec1()}; +} +template <> +Vectorized C10_ALWAYS_INLINE fmadd( + const Vectorized& a, + const Vectorized& b, + const Vectorized& c) { + return Vectorized{ + a.vec0() * b.vec0() + c.vec0(), a.vec1() * b.vec1() + c.vec1()}; +} + +template <> +Vectorized C10_ALWAYS_INLINE +convert_to_int_of_same_size(const Vectorized& src) { + return zvec_convert_to_int(src); +} + +template <> +Vectorized C10_ALWAYS_INLINE +convert_to_int_of_same_size(const Vectorized& src) { + return zvec_convert_to_int(src); +} + +template <> +inline void convert(const int32_t* src, float* dst, int64_t n) { + // int32_t and float have same size + int64_t i; + for (i = 0; i <= (n - Vectorized::size()); + i += Vectorized::size()) { + const int32_t* src_a = src + i; + float* dst_a = dst + i; + auto input_vec = Vectorized::loadu(src_a); + auto output_vec = zvec_convert_to_float(input_vec); + output_vec.store(dst_a); + } + + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +template <> +inline void convert(const int64_t* src, double* dst, int64_t n) { + int64_t i; + for (i = 0; i <= (n - Vectorized::size()); + i += Vectorized::size()) { + const int64_t* src_a = src + i; + double* dst_a = dst + i; + auto input_vec = Vectorized::loadu(src_a); + auto output_vec = zvec_convert_to_float(input_vec); + output_vec.store(dst_a); + } + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +#define DEFINE_REINTERPRET_CAST_FUNCS(Fst, Cst) \ + template <> \ + C10_ALWAYS_INLINE Vectorized cast( \ + const Vectorized& src) { \ + return cast_zvector(src); \ + } + +#define DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(Fst) \ + DEFINE_REINTERPRET_CAST_FUNCS(Fst, double) \ + DEFINE_REINTERPRET_CAST_FUNCS(Fst, float) \ + DEFINE_REINTERPRET_CAST_FUNCS(Fst, int64_t) \ + DEFINE_REINTERPRET_CAST_FUNCS(Fst, int32_t) \ + DEFINE_REINTERPRET_CAST_FUNCS(Fst, int16_t) + +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(float) +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(double) +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(int64_t) +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(int32_t) +DEFINE_REINTERPRET_CAST_TO_ALL_FUNCS(int16_t) + +#undef DEFINE_REINTERPRET_CAST_FUNCS + +template +struct unpack_type { + using type = T; +}; +template <> +struct unpack_type { + using type = int16_t; +}; +template <> +struct unpack_type { + using type = int16_t; +}; +template <> +struct unpack_type { + using type = int32_t; +}; + +template +struct pack_type { + using type = T; +}; +template <> +struct pack_type { + using type = int8_t; +}; +template <> +struct pack_type { + using type = int16_t; +}; + +namespace { /* unnamed namespace */ + +template ::type> +std::pair, Vectorized> unpack(const Vectorized& x) { + auto vec0 = vec_unpackh(x.vec0()); + auto vec1 = vec_unpackl(x.vec0()); + auto vec2 = vec_unpackh(x.vec1()); + auto vec3 = vec_unpackl(x.vec1()); + return {Vectorized{vec0, vec1}, Vectorized{vec2, vec3}}; +} + +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Wunused-function") +template <> +std::pair, Vectorized> unpack( + const Vectorized& x) { + using typeX = typename Vectorized::vtype; + typeX vec0 = vec_unpackh(x.vec0()); + typeX vec1 = vec_unpackl(x.vec0()); + typeX vec2 = vec_unpackh(x.vec1()); + typeX vec3 = vec_unpackl(x.vec1()); + // auto mask = Vectorized(0xFF); + // vec0 = vec0 & mask; + // vec1 = vec1 & mask; + // vec2 = vec2 & mask; + // vec3 = vec3 & mask; + return { + cast_zvector(Vectorized{vec0, vec1}), + cast_zvector(Vectorized{vec2, vec3})}; +} +C10_DIAGNOSTIC_POP() + +template ::type> +Vectorized pack(const Vectorized& first, const Vectorized& second) { + auto vec0 = vec_packs(first.vec0(), first.vec1()); + auto vec1 = vec_packs(second.vec0(), second.vec1()); + return Vectorized{vec0, vec1}; +} + +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Wunused-function") +template <> +Vectorized pack( + const Vectorized& first, + const Vectorized& second) { + auto vec0 = vec_packsu(first.vec0(), first.vec1()); + auto vec1 = vec_packsu(second.vec0(), second.vec1()); + return Vectorized{vec0, vec1}; +} +C10_DIAGNOSTIC_POP() + +} /* unnamed namespace */ + +//////////////////////////////////QUANT/////////////////////////////////////////// +template +struct Vectorized()>> { + public: + using value_type = typename T::underlying; + using vtype = ZSimdVect; + using vmaskType = ZSimdVectBinary; + using vinner_type = Vectorized; + using size_type = int; + + static constexpr size_type size() { + return VECTOR_WIDTH / sizeof(value_type); + } + + static constexpr int float_num_vecs() { + return size() / Vectorized::size(); + } + static constexpr int int_num_vecs() { + return float_num_vecs(); + } + using float_vec_return_type = std::array, float_num_vecs()>; + using int_vec_return_type = + std::array, int_num_vecs()>; + + private: + vinner_type _vec; + + public: + Vectorized() {} + + explicit C10_ALWAYS_INLINE Vectorized(vinner_type v) : _vec{v} {} + Vectorized(const T& val) : _vec(val.val_) {} + + C10_ALWAYS_INLINE const vinner_type& vec() const { + return _vec; + } + + template + static Vectorized C10_ALWAYS_INLINE + loadu(const U* ptr, int count = size()) { + return Vectorized{vinner_type::loadu(ptr, count)}; + } + + template + void C10_ALWAYS_INLINE store(U* ptr, int count = size()) const { + _vec.store(ptr, count); + } + + Vectorized relu(Vectorized zero_point) const { + return Vectorized{_vec.maximum(zero_point._vec)}; + } + + Vectorized relu6(Vectorized zero_point, Vectorized q_six) const { + auto ret_max = _vec.maximum(zero_point._vec); + auto ret_min = ret_max.minimum(q_six._vec); + return Vectorized{ret_min}; + } + + template < + typename U = T, + std::enable_if_t::float_num_vecs() == 1, int> = 0> + int_vec_return_type widening_subtract(Vectorized b) const { + return {*this - b}; + } + + template < + typename U = T, + std::enable_if_t::float_num_vecs() == 1, int> = 0> + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_zp_premul) const { + auto float_val = zvec_convert_to_float(_vec); + return {fmadd(scale, float_val, scale_zp_premul)}; + } + + template < + typename U = T, + std::enable_if_t::float_num_vecs() == 1, int> = 0> + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + auto float_val = zvec_convert_to_float(_vec); + return {(float_val - zero_point) * scale}; + } + + template < + typename U = T, + std::enable_if_t::float_num_vecs() == 1, int> = 0> + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + Vectorized vecf = rhs[0]; + vecf = vecf * Vectorized(inverse_scale); + vecf = vecf.rint() + Vectorized((float)(zero_point)); + auto veci = zvec_convert_to_int(vecf); + + return Vectorized{veci}; + } + + template < + typename U = T, + std::enable_if_t::int_num_vecs() == 1, int> = 0> + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + Vectorized vi = inp[0]; + auto vecf = zvec_convert_to_float(vi.vec()); + vecf = vecf * Vectorized(multiplier); + vecf = vecf.rint(); + auto veci = zvec_convert_to_int(vecf) + Vectorized(zero_point); + + return Vectorized{veci}; + } + + template < + typename U = T, + std::enable_if_t::int_num_vecs() == 4, int> = 0> + int_vec_return_type widening_subtract(Vectorized b) const { + auto ret16 = unpack(_vec); + auto ret16B = unpack(b.vec()); + auto ret32_0 = unpack(ret16.first); + auto ret32_1 = unpack(ret16.second); + auto ret32B_0 = unpack(ret16B.first); + auto ret32B_1 = unpack(ret16B.second); + + return { + Vectorized(ret32_0.first - ret32B_0.first), + Vectorized(ret32_0.second - ret32B_0.second), + Vectorized(ret32_1.first - ret32B_1.first), + Vectorized(ret32_1.second - ret32B_1.second)}; + } + + template < + typename U = T, + std::enable_if_t::float_num_vecs() == 4, int> = 0> + float_vec_return_type C10_ALWAYS_INLINE dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_zp_premul) const { + // unpacking unsigned as signed + auto ret16 = unpack(_vec); + auto ret32_0 = unpack(ret16.first); + auto ret32_1 = unpack(ret16.second); + + auto vecf_0 = zvec_convert_to_float(ret32_0.first); + auto vecf_1 = zvec_convert_to_float(ret32_0.second); + + auto vecf_2 = zvec_convert_to_float(ret32_1.first); + auto vecf_3 = zvec_convert_to_float(ret32_1.second); + return { + fmadd(scale, vecf_0, scale_zp_premul), + fmadd(scale, vecf_1, scale_zp_premul), + fmadd(scale, vecf_2, scale_zp_premul), + fmadd(scale, vecf_3, scale_zp_premul)}; + } + + template < + typename U = T, + std::enable_if_t::float_num_vecs() == 4, int> = 0> + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + // unpacking unsigned as signed + auto ret16 = unpack(_vec); + auto ret32_0 = unpack(ret16.first); + auto ret32_1 = unpack(ret16.second); + + auto vecf_0 = zvec_convert_to_float(ret32_0.first); + auto vecf_1 = zvec_convert_to_float(ret32_0.second); + + auto vecf_2 = zvec_convert_to_float(ret32_1.first); + auto vecf_3 = zvec_convert_to_float(ret32_1.second); + + return { + (vecf_0 - zero_point) * scale, + (vecf_1 - zero_point) * scale, + (vecf_2 - zero_point) * scale, + (vecf_3 - zero_point) * scale }; + } + + template < + typename U = T, + std::enable_if_t::float_num_vecs() == 4, int> = 0> + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + auto vec_inverse = Vectorized(inverse_scale); + auto vec_zero_point = Vectorized((float)zero_point); + + auto vecf0 = rhs[0]; + auto vecf2 = rhs[1]; + auto vecf4 = rhs[2]; + auto vecf6 = rhs[3]; + + vecf0 = vecf0 * vec_inverse; + vecf2 = vecf2 * vec_inverse; + vecf4 = vecf4 * vec_inverse; + vecf6 = vecf6 * vec_inverse; + + vecf0 = vecf0.rint() + vec_zero_point; + vecf2 = vecf2.rint() + vec_zero_point; + vecf4 = vecf4.rint() + vec_zero_point; + vecf6 = vecf6.rint() + vec_zero_point; + + auto veci0 = zvec_convert_to_int(vecf0); + auto veci2 = zvec_convert_to_int(vecf2); + auto veci4 = zvec_convert_to_int(vecf4); + auto veci6 = zvec_convert_to_int(vecf6); + + auto vecshi0 = pack(veci0, veci2); + auto vecshi2 = pack(veci4, veci6); + auto ret = pack(vecshi0, vecshi2); + + return Vectorized{ret}; + } + + template < + typename U = T, + std::enable_if_t::int_num_vecs() == 4, int> = 0> + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + Vectorized vec_multiplier = Vectorized(multiplier); + Vectorized vec_zero_point = Vectorized(zero_point); + + Vectorized vi0 = inp[0]; + Vectorized vi1 = inp[1]; + Vectorized vi2 = inp[2]; + Vectorized vi3 = inp[3]; + + auto vecf0 = zvec_convert_to_float(vi0.vec()); + auto vecf2 = zvec_convert_to_float(vi1.vec()); + + auto vecf4 = zvec_convert_to_float(vi2.vec()); + auto vecf6 = zvec_convert_to_float(vi3.vec()); + + vecf0 = vecf0 * vec_multiplier; + vecf2 = vecf2 * vec_multiplier; + + vecf4 = vecf4 * vec_multiplier; + vecf6 = vecf6 * vec_multiplier; + + vecf0 = vecf0.rint(); + vecf2 = vecf2.rint(); + vecf4 = vecf4.rint(); + vecf6 = vecf6.rint(); + + auto veci0 = zvec_convert_to_int(vecf0); + auto veci2 = zvec_convert_to_int(vecf2); + auto veci4 = zvec_convert_to_int(vecf4); + auto veci6 = zvec_convert_to_int(vecf6); + + veci0 = veci0 + vec_zero_point; + veci2 = veci2 + vec_zero_point; + + veci4 = veci4 + vec_zero_point; + veci6 = veci6 + vec_zero_point; + + auto vecshi0 = pack(veci0, veci2); + auto vecshi2 = pack(veci4, veci6); + + auto ret = pack(vecshi0, vecshi2); + + return Vectorized{ret}; + } + + Vectorized C10_ALWAYS_INLINE eq(const Vectorized& other) const { + return Vectorized{_vec.eq(other._vec)}; + } + Vectorized C10_ALWAYS_INLINE ne(const Vectorized& other) const { + return Vectorized{_vec.ne(other._vec)}; + } + Vectorized C10_ALWAYS_INLINE gt(const Vectorized& other) const { + return Vectorized{_vec.gt(other._vec)}; + } + Vectorized C10_ALWAYS_INLINE ge(const Vectorized& other) const { + return Vectorized{_vec.ge(other._vec)}; + } + Vectorized C10_ALWAYS_INLINE lt(const Vectorized& other) const { + return Vectorized{_vec.lt(other._vec)}; + } + Vectorized C10_ALWAYS_INLINE le(const Vectorized& other) const { + return Vectorized{_vec.le(other._vec)}; + } + + Vectorized clamp_min(const Vectorized& min) const { + return Vectorized{_vec.clamp_min(min._vec)}; + } + + Vectorized clamp_max(const Vectorized& max) const { + return Vectorized{_vec.clamp_max(max._vec)}; + } + + Vectorized minimum(const Vectorized& other) const { + return Vectorized{_vec.minimum(other._vec)}; + } + + Vectorized maximum(const Vectorized& other) const { + return Vectorized{_vec.maximum(other._vec)}; + } +}; + +#define ZVECTOR_OPERATORS(typex) \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() + b.vec()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() - b.vec()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator*(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() * b.vec()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator/(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() / b.vec()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() & b.vec()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() | b.vec()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() ^ b.vec()}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator==(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() == b.vec()}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator!=(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() != b.vec()}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator>(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() > b.vec()}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator>=(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() >= b.vec()}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator<(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() < b.vec()}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator<=(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() <= b.vec()}; \ + } + +ZVECTOR_OPERATORS(c10::qint32) +ZVECTOR_OPERATORS(c10::qint8) +ZVECTOR_OPERATORS(c10::quint8) + +#undef ZVECTOR_OPERATORS + +DEFINE_CLAMP_MAXMIN_FUNCS(c10::quint8) +DEFINE_CLAMP_MAXMIN_FUNCS(c10::qint8) +DEFINE_CLAMP_MAXMIN_FUNCS(c10::qint32) + +template +constexpr auto real_mask() { + return (ZSimdVect)ZSimdVectBinary{0xFFFFFFFF, 0, 0xFFFFFFFF, 0}; +} + +template <> +constexpr auto real_mask() { + return (ZSimdVect)ZSimdVectBinary{0xFFFFFFFFFFFFFFFF, 0}; +} + +template +constexpr auto image_mask() { + return (ZSimdVect)ZSimdVectBinary{0, 0xFFFFFFFF, 0, 0xFFFFFFFF}; +} + +template <> +constexpr auto image_mask() { + return (ZSimdVect)ZSimdVectBinary{0, 0xFFFFFFFFFFFFFFFF}; +} + +template +constexpr auto rsign_mask() { + return ZSimdVect{-0.f, 0.f, -0.f, 0.f}; +} + +template <> +constexpr auto rsign_mask() { + return ZSimdVect{-0.0, 0.f}; +} + +template +constexpr auto isign_mask() { + return ZSimdVect{0.0, -0.f, 0.0, -0.f}; +} + +template <> +constexpr auto isign_mask() { + return ZSimdVect{0.0, -0.0}; +} + +template +constexpr auto image_one() { + return ZSimdVect{0, 1.f, 0, 1.f}; +} + +template <> +constexpr auto image_one() { + return ZSimdVect{0.0, 1.0}; +} + +template +constexpr auto pi_half() { + return ZSimdVect{(float)(M_PI / 2.0), 0.f, (float)(M_PI / 2.0), 0.f}; +} + +template <> +constexpr auto pi_half() { + return ZSimdVect{M_PI / 2.0, 0.0}; +} + +template +constexpr auto image_half() { + return ZSimdVect{0, 0.5f, 0, 0.5f}; +} + +template <> +constexpr auto image_half() { + return ZSimdVect{0.0, 0.5}; +} + +template +constexpr U log2e_inv() { + return static_cast(1.4426950408889634); +} + +template +constexpr U log10e_inv() { + return static_cast(0.43429448190325176); +} + +template +struct Vectorized()>> { + public: + using underline_type = decltype(std::declval().imag()); + using value_type = T; + using vtype = ZSimdVect; + using vmaskType = ZSimdVectBinary; + using vinner_type = Vectorized; + using size_type = int; + using vinner_data = typename Vectorized::vinner_data; + + static constexpr size_type size() { + return VECTOR_WIDTH / sizeof(value_type); + } + + private: + vinner_type _vec; + + public: + Vectorized() {} + + C10_ALWAYS_INLINE Vectorized(const vinner_data &v) : _vec{v.first, v.second} {} + + template = 0> + C10_ALWAYS_INLINE Vectorized(T s1, T s2) + : _vec{s1.real(), s1.imag(), s2.real(), s2.imag()} {} + + template = 0> + C10_ALWAYS_INLINE Vectorized(T s1, T s2, T s3, T s4) + : _vec{ + s1.real(), + s1.imag(), + s2.real(), + s2.imag(), + s3.real(), + s3.imag(), + s4.real(), + s4.imag()} {} + + template = 0> + C10_ALWAYS_INLINE Vectorized(T s) : Vectorized(s, s) {} + + template = 0> + C10_ALWAYS_INLINE Vectorized(T s) : Vectorized(s, s, s, s) {} + + C10_ALWAYS_INLINE operator vinner_type() const { + return _vec; + } + + C10_ALWAYS_INLINE const vinner_type& vec() const { + return _vec; + } + + C10_ALWAYS_INLINE operator vinner_data() const { + return _vec.data(); + } + + C10_ALWAYS_INLINE vinner_data data() const { + return _vec.data(); + } + + template + static Vectorized C10_ALWAYS_INLINE + loadu(const U* ptr, int count = size()) { + return Vectorized{vinner_type::loadu(ptr, 2 * count)}; + } + + template + void C10_ALWAYS_INLINE store(U* ptr, int count = size()) const { + return _vec.store(ptr, 2 * count); + } + + static Vectorized blendv( + const Vectorized& a, + const Vectorized& b, + const Vectorized& mask) { + // convert std::complex index mask to V index mask: xy -> xxyy + vinner_type vmask = mask.vec(); + auto mask_complex = vinner_type( + vec_mergeh(vmask.vec0(), vmask.vec0()), + vec_mergeh(vmask.vec1(), vmask.vec1())); + return Vectorized{vinner_type::blendv(a.vec(), b.vec(), mask_complex)}; + } + + template + static auto C10_ALWAYS_INLINE + blend(const Vectorized& a, const Vectorized& b) { + constexpr int mask_complex = maskForComplex(mask); + return Vectorized{ + vinner_type::template blend(a.vec(), b.vec())}; + } + + template + static std::enable_if_t> arange( + T base = 0, + step_t step = static_cast(1)) { + return Vectorized(base, base + step); + } + + template + static std::enable_if_t> arange( + T base = 0, + step_t step = static_cast(1)) { + return Vectorized( + base, + base + step, + base + value_type(2) * step, + base + value_type(3) * step); + } + + template + static inline std::enable_if_t<(Z >= C), Vectorized> set_inner( + const Vectorized& a, + const Vectorized& b, + size_t count) { + return b; + } + + template + static inline std::enable_if_t<(Z < C), Vectorized> set_inner( + const Vectorized& a, + const Vectorized& b, + size_t count) { + if (count == Z) + return blend(a, b); + else + return set_inner(a, b, count); + } + + static Vectorized set( + const Vectorized& a, + const Vectorized& b, + size_t count = size()) { + if (count == 0) + return a; + return set_inner<1, size()>(a, b, count); + } + + const T& operator[](int idx) const = delete; + T& operator[](int idx) = delete; + + template < + typename U = T, + std::enable_if_t>::value, int> = 0> + Vectorized mapOrdinary(T (*const f)(const T&)) const { + auto v0 = _vec.vec0(); + auto v1 = _vec.vec1(); + return Vectorized{ + f(T(v0[0], v0[1])), + f(T(v0[2], v0[3])), + f(T(v1[0], v1[1])), + f(T(v1[2], v1[3]))}; + } + + template < + typename U = T, + std::enable_if_t>::value, int> = 0> + Vectorized mapOrdinary(T (*const f)(const T&)) const { + auto v0 = _vec.vec0(); + auto v1 = _vec.vec1(); + return Vectorized{f(T(v0[0], v0[1])), f(T(v1[0], v1[1]))}; + } + + template < + typename U = T, + std::enable_if_t>::value, int> = 0> + Vectorized mapOrdinary(T (*const f)(T)) const { + auto v0 = _vec.vec0(); + auto v1 = _vec.vec1(); + return Vectorized{ + f(T(v0[0], v0[1])), + f(T(v0[2], v0[3])), + f(T(v1[0], v1[1])), + f(T(v1[2], v1[3]))}; + } + + template < + typename U = T, + std::enable_if_t>::value, int> = 0> + Vectorized mapOrdinary(T (*const f)(T)) const { + auto v0 = _vec.vec0(); + auto v1 = _vec.vec1(); + return Vectorized{f(T(v0[0], v0[1])), f(T(v1[0], v1[1]))}; + } + + template < + typename U = T, + std::enable_if_t>::value, int> = 0> + inline Vectorized mapOrdinary( + T (*const f)(const T&, const T&), + const Vectorized& b) const { + auto v0 = _vec.vec0(); + auto v1 = _vec.vec1(); + auto bvec = b.vec(); + auto b0 = bvec.vec0(); + auto b1 = bvec.vec1(); + T a00 = f(T(v0[0], v0[1]), T(b0[0], b0[1])); + T a01 = f(T(v0[2], v0[3]), T(b0[2], b0[3])); + T a02 = f(T(v1[0], v1[1]), T(b1[0], b1[1])); + T a03 = f(T(v1[2], v1[3]), T(b1[2], b1[3])); + return Vectorized{a00, a01, a02, a03}; + } + + template < + typename U = T, + std::enable_if_t>::value, int> = 0> + inline Vectorized mapOrdinary( + T (*const f)(const T&, const T&), + const Vectorized& b) const { + auto v0 = _vec.vec0(); + auto v1 = _vec.vec1(); + auto bvec = b.vec(); + auto b0 = bvec.vec0(); + auto b1 = bvec.vec1(); + U a00 = f(U(v0[0], v0[1]), U(b0[0], b0[1])); + U a01 = f(U(v1[0], v1[1]), U(b1[0], b1[1])); + return Vectorized{a00, a01}; + } + + template < + typename U = T, + std::enable_if_t>::value, int> = 0> + static typename Vectorized::vinner_type real_neg(const typename Vectorized::vinner_type &a) + { + const auto swap_mask = ZSimdVectBinary{ + 0, 1, 2, 3, 20, 21, 22, 23, 8, 9, 10, 11, 28, 29, 30, 31}; + + auto a_neg = a.neg(); + vtype v0 = vec_perm(a_neg.vec0(), a.vec0(), swap_mask); + vtype v1 = vec_perm(a_neg.vec1(), a.vec1(), swap_mask); + return {v0, v1}; + } + + template < + typename U = T, + std::enable_if_t>::value, int> = 0> + static typename Vectorized::vinner_type real_neg(const typename Vectorized::vinner_type &a) + { + auto a_neg = a.neg(); + vtype v0 = {a_neg.vec0()[0], a.vec0()[1]}; + vtype v1 = {a_neg.vec1()[0], a.vec1()[1]}; + return { v0, v1 }; + } + + Vectorized angle2_() const { + auto b_a = _vec.swapped(); // b a + return Vectorized{_vec.atan2(b_a).swapped()}; + } + + Vectorized angle() const { + return angle2_().real(); + } + + Vectorized atan() const { + // atan(x) = i/2 * ln((i + z)/(i - z)) + auto ione = Vectorized{vinner_type(image_one())}; + auto sum = ione + *this; + auto sub = ione - *this; + auto ln = (sum / sub).log(); // ln((i + z)/(i - z)) + return ln * + Vectorized{vinner_type(image_half())}; // i/2*ln() + } + + Vectorized atanh() const { + return mapOrdinary(std::atanh); + } + + Vectorized asin() const { + // asin(x) + // = -i*ln(iz + sqrt(1 -z^2)) + // = -i*ln((ai - b) + sqrt(1 - (a + bi)*(a + bi))) + // = -i*ln((-b + ai) + sqrt(1 - (a**2 - b**2) - 2*abi)) +#if 1 + vinner_type cnj = conj().vec(); + vinner_type b_a = cnj.swapped(); + vinner_type ab = cnj * b_a; + vinner_type im = ab + ab; + vinner_type val_2 = _vec * _vec; + vinner_type val_2_swapped = val_2.swapped(); + vinner_type re = vinner_type::horizontal_sub_perm(val_2, val_2_swapped); + re = vinner_type(static_cast(1)) - re; + constexpr int blend_mask = + blend_choice(); // 0x0A for complex , 0xAA for complex + vinner_type blendx = vinner_type::template blend(re, im); + auto root = Vectorized(blendx).sqrt(); + auto ln = Vectorized(Vectorized(b_a) + root).log(); + return Vectorized(ln.vec().swapped()).conj(); +#else + return mapOrdinary(std::asin); +#endif + } + + Vectorized acos() const { + // acos(x) = pi/2 - asin(x) + return Vectorized(vinner_type(pi_half())) - asin(); + } + + Vectorized sin() const { + return mapOrdinary(std::sin); + } + Vectorized sinh() const { + return mapOrdinary(std::sinh); + } + Vectorized cos() const { + return mapOrdinary(std::cos); + } + Vectorized cosh() const { + return mapOrdinary(std::cosh); + } + Vectorized ceil() const { + return Vectorized{_vec.ceil()}; + } + Vectorized floor() const { + return Vectorized{_vec.floor()}; + } + Vectorized neg() const { + return Vectorized(_vec.neg()); + } + Vectorized round() const { + return Vectorized{_vec.round()}; + } + Vectorized tan() const { + return mapOrdinary(std::tan); + } + Vectorized tanh() const { + return mapOrdinary(std::tanh); + } + Vectorized trunc() const { + return Vectorized{_vec.trunc()}; + } + + Vectorized C10_ALWAYS_INLINE eq(const Vectorized& other) const { + auto eq = _vec.eq(other._vec); // compares real and imag individually + // If both real numbers and imag numbers are equal, then the complex numbers are equal + auto real = eq & vinner_type(real_mask()); + auto imag = (eq & vinner_type(image_mask())).swapped(); + return Vectorized{real & imag}; + } + Vectorized C10_ALWAYS_INLINE ne(const Vectorized& other) const { + auto ne = _vec.ne(other._vec); // compares real and imag individually + // If either real numbers or imag numbers are not equal, then the complex numbers are not equal + auto real = ne & vinner_type(real_mask()); + auto imag = (ne & vinner_type(image_mask())).swapped(); + return Vectorized{real | imag}; + } + + Vectorized real() const { + return Vectorized(_vec & vinner_type(real_mask())); + } + Vectorized imag_() const { + return Vectorized(_vec & vinner_type(image_mask())); + } + Vectorized imag() const { + return Vectorized{ + (_vec & vinner_type(image_mask())).swapped()}; + } + + Vectorized conj() const { + return Vectorized(_vec ^ vinner_type(isign_mask())); + } + + vinner_data abs_2_() const { + auto a = _vec * _vec; + a = a + a.swapped(); + return a.mergee().data(); + } + + static T abs_helper(const T &value) + { + return T(std::abs(value)); + } + + Vectorized abs() const { + return mapOrdinary(abs_helper); + } + + Vectorized exp() const { + return mapOrdinary(std::exp); + } + + Vectorized exp2() const { + return mapOrdinary(exp2_impl); + } + + Vectorized expm1() const { + return mapOrdinary(std::expm1); + } + + Vectorized log() const { + return mapOrdinary(std::log); + } + + Vectorized log2() const { + // log2eB_inv + auto ret = log(); + return Vectorized{ret._vec * vinner_type(log2e_inv())}; + } + + Vectorized log10() const { + auto ret = log(); + return Vectorized{ret._vec * vinner_type(log10e_inv())}; + } + + Vectorized log1p() const { + return mapOrdinary(std::log1p); + } + + Vectorized sgn() const { + return mapOrdinary(at::native::sgn_impl); + } + + Vectorized pow(const Vectorized& exp) const { + return mapOrdinary(std::pow, exp); + } + + Vectorized sqrt() const { + return mapOrdinary(std::sqrt); + } + + Vectorized reciprocal() const { + // re + im*i = (a + bi) / (c + di) + // re = (ac + bd)/abs_2() = c/abs_2() + // im = (bc - ad)/abs_2() = d/abs_2() + vinner_type c_d = _vec ^ vinner_type(isign_mask()); + vinner_type abs = abs_2_(); + return Vectorized{c_d / abs}; + } + + Vectorized rsqrt() const { + return sqrt().reciprocal(); + } + + Vectorized lt(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized le(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized gt(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized ge(const Vectorized& other) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } +}; + +#define ZVECTOR_OPERATORS(typex) \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator+(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() + b.vec()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator-(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() - b.vec()}; \ + } \ + \ + template <> \ + Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { \ + /* (a + bi) * (c + di) = (ac - bd) + (ad + bc)i */ \ + Vectorized::vinner_type bv = b.vec(); \ + \ + /* this is more z arch friendly than simulating horizontal from x86 */ \ + Vectorized::vinner_type vi = bv.mergeo(); \ + Vectorized::vinner_type vr = bv.mergee(); \ + vi = vi ^ Vectorized::vinner_type(rsign_mask::underline_type>()); \ + Vectorized::vinner_type ret = a.vec() * vr; \ + Vectorized::vinner_type vx_swapped = a.vec().swapped(); \ + ret = fmadd(vx_swapped, vi, ret); \ + \ + return Vectorized{ret}; \ + } \ + \ + template <> \ + Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { \ + /* Unfortunately, this breaks some tests */ \ + /* Implement it like it's done for avx2 */ \ + auto fabs_cd = b.vec().abs(); /* |c| |d| */ \ + auto fabs_dc = fabs_cd.swapped(); /* |d| |c| */ \ + auto scale = Vectorized::vinner_type {1.0} / maximum(fabs_cd, fabs_dc); /* 1/sc 1/sc */ \ + auto a2 = a.vec() * scale; /* a/sc b/sc */ \ + auto b2 = b.vec() * scale; /* c/sc d/sc */ \ + auto acbd2 = a2 * b2; /* ac/sc^2 bd/sc^2 */ \ + \ + auto dc2 = b2.swapped(); /* d/sc c/sc */ \ + dc2 = Vectorized::real_neg(dc2); /* -d/|c,d| c/sc */ \ + auto adbc2 = a2 * dc2; /* -ad/sc^2 bc/sc^2 */ \ + auto sum1 = acbd2 + acbd2.swapped(); /* (ac+bd)/sc^2 (ac+bd)/sc^2 */ \ + auto sum2 = adbc2 + adbc2.swapped(); /* (bc-ad)/sc^2 (bc-ad)/sc^2 */ \ + auto res2 = Vectorized::vinner_type::mergee(sum1, sum2); /* (ac+bd)/sc^2 (bc-ad)/sc^2 */ \ + \ + /* get the denominator */ \ + Vectorized::vinner_type denom2 = Vectorized{b2}.abs_2_(); /* (c^2+d^2)/sc^2 (c^2+d^2)/sc^2 */ \ + res2 = res2 / denom2; \ + return Vectorized{ res2 }; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator&(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() & b.vec()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator|(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() | b.vec()}; \ + } \ + \ + template <> \ + Vectorized C10_ALWAYS_INLINE operator^(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() ^ b.vec()}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator==(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() == b.vec()}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator!=(const Vectorized& a, const Vectorized& b) { \ + return Vectorized{a.vec() != b.vec()}; \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator<(const Vectorized& a, const Vectorized& b) { \ + TORCH_CHECK(false, "not supported for complex numbers"); \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator<=(const Vectorized& a, const Vectorized& b) { \ + TORCH_CHECK(false, "not supported for complex numbers"); \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator>(const Vectorized& a, const Vectorized& b) { \ + TORCH_CHECK(false, "not supported for complex numbers"); \ + } \ + \ + Vectorized C10_ALWAYS_INLINE operator>=(const Vectorized& a, const Vectorized& b) { \ + TORCH_CHECK(false, "not supported for complex numbers"); \ + } + +ZVECTOR_OPERATORS(c10::complex) +ZVECTOR_OPERATORS(c10::complex) + +#undef ZVECTOR_OPERATORS + +template = 0> +std::pair, Vectorized> inline inner_interleave2( + const Vectorized& a, + const Vectorized& b) { + // inputs: + // a = {a0, a1, a2, a3} + // b = {b0, b1, b2, b3} + using vtype = typename Vectorized::vtype; + vtype ab00 = {a.vec0()[0], b.vec0()[0]}; + vtype ab11 = {a.vec0()[1], b.vec0()[1]}; + vtype ab2_00 = {a.vec1()[0], b.vec1()[0]}; + vtype ab2_11 = {a.vec1()[1], b.vec1()[1]}; + // return {a0, b0, a1, b1} + // {a2, b2, a3, b3} + return std::make_pair( + Vectorized{ab00, ab11}, Vectorized{ab2_00, ab2_11}); +} + +template = 0> +std::pair, Vectorized> inline inner_deinterleave2( + const Vectorized& a, + const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1} + // b = {a2, b2, a3, b3} + using vtype = typename Vectorized::vtype; + vtype aa01 = {a.vec0()[0], a.vec1()[0]}; + vtype aa23 = {b.vec0()[0], b.vec1()[0]}; + + vtype bb_01 = {a.vec0()[1], a.vec1()[1]}; + vtype bb_23 = {b.vec0()[1], b.vec1()[1]}; + + // swap lanes: + // return {a0, a1, a2, a3} + // {b0, b1, b2, b3} + return std::make_pair(Vectorized{aa01, aa23}, Vectorized{bb_01, bb_23}); +} + +template = 0> +std::pair, Vectorized> inline inner_interleave2( + const Vectorized& a, + const Vectorized& b) { + // inputs: + // a = {a0, a1, a2, a3,, a4, a5, a6, a7} + // b = {b0, b1, b2, b3,, b4, b5, b6, b7} + using vtype = typename Vectorized::vtype; + vtype ab0011 = vec_mergeh(a.vec0(), b.vec0()); + vtype ab2233 = vec_mergel(a.vec0(), b.vec0()); + + vtype ab2_0011 = vec_mergeh(a.vec1(), b.vec1()); + vtype ab2_2233 = vec_mergel(a.vec1(), b.vec1()); + // group cols crossing lanes: + // return {a0, b0, a1, b1,, a2, b2, a3, b3} + // {a4, b4, a5, b5,, a6, b6, a7, b7} + + return std::make_pair( + Vectorized{ab0011, ab2233}, Vectorized{ab2_0011, ab2_2233}); +} + +template = 0> +std::pair, Vectorized> inline inner_deinterleave2( + const Vectorized& a, + const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1,, a2, b2, a3, b3} + // b = {a4, b4, a5, b5,, a6, b6, a7, b7} + using vtype = typename Vectorized::vtype; + // {a0,a2,b0,b2} {a1,a3,b1,b3} + vtype a0a2b0b2 = vec_mergeh(a.vec0(), a.vec1()); + vtype a1a3b1b3 = vec_mergel(a.vec0(), a.vec1()); + + vtype aa0123 = vec_mergeh(a0a2b0b2, a1a3b1b3); + vtype bb0123 = vec_mergel(a0a2b0b2, a1a3b1b3); + + vtype a0a2b0b2_2 = vec_mergeh(b.vec0(), b.vec1()); + vtype a1a3b1b3_2 = vec_mergel(b.vec0(), b.vec1()); + + vtype aa0123_2 = vec_mergeh(a0a2b0b2_2, a1a3b1b3_2); + vtype bb0123_2 = vec_mergel(a0a2b0b2_2, a1a3b1b3_2); + + // it could be done with vec_perm ,too + // swap lanes: + // return {a0, a1, a2, a3,, a4, a5, a6, a7} + // {b0, b1, b2, b3,, b4, b5, b6, b7} + + return std::make_pair( + Vectorized{aa0123, aa0123_2}, Vectorized{bb0123, bb0123_2}); +} + +template <> +std::pair, Vectorized> inline interleave2( + const Vectorized& a, + const Vectorized& b) { + return inner_interleave2(a, b); +} + +template <> +std::pair, Vectorized> inline interleave2( + const Vectorized& a, + const Vectorized& b) { + return inner_interleave2(a, b); +} + +template <> +std::pair, Vectorized> inline interleave2( + const Vectorized& a, + const Vectorized& b) { + return inner_interleave2(a, b); +} + +template <> +std::pair, Vectorized> inline interleave2( + const Vectorized& a, + const Vectorized& b) { + return inner_interleave2(a, b); +} + +template <> +std::pair, Vectorized> inline deinterleave2( + const Vectorized& a, + const Vectorized& b) { + return inner_deinterleave2(a, b); +} + +template <> +std::pair, Vectorized> inline deinterleave2< + int32_t>(const Vectorized& a, const Vectorized& b) { + return inner_deinterleave2(a, b); +} + +template <> +std::pair, Vectorized> inline deinterleave2( + const Vectorized& a, + const Vectorized& b) { + return inner_deinterleave2(a, b); +} + +template <> +std::pair, Vectorized> inline deinterleave2< + int64_t>(const Vectorized& a, const Vectorized& b) { + return inner_deinterleave2(a, b); +} + +template +std::enable_if_t, at::vec::Vectorized> +inline convert_int8_to_float(const Vectorized &src) { + // Note: this function only convert inputs number of elements equal to at::vec::Vectorized.size() + // Only handle first 64 bits + auto vec_int = src.to_vec_float_helper(); + + return zvec_convert_to_float(vec_int); +} + +template +std::enable_if_t, at::vec::Vectorized> +inline convert_float_to_int8(const Vectorized &src) { + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + + auto vec_int = clamp(zvec_convert_to_int(src), Vectorized(min_val), Vectorized(max_val)); + + return vec_int.to_vec_uint8_helper(); +} + +#undef DEFINE_CLAMP_MAXMIN_FUNCS +#undef DEFINE_MAXMIN_FUNCS +} // namespace +} // namespace vec +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512.h new file mode 100644 index 0000000000000000000000000000000000000000..d593d184c3190a04a46131ecef57b10f3989ed87 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512.h @@ -0,0 +1,291 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include + +namespace at { +namespace vec { + +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +inline std::ostream& operator<<(std::ostream& stream, const c10::qint32& val) { + stream << val.val_; + return stream; +} +inline std::ostream& operator<<(std::ostream& stream, const c10::qint8& val) { + stream << static_cast(val.val_); + return stream; +} +inline std::ostream& operator<<(std::ostream& stream, const c10::quint8& val) { + stream << static_cast(val.val_); + return stream; +} + +template +std::ostream& operator<<(std::ostream& stream, const Vectorized& vec) { + T buf[Vectorized::size()]; + vec.store(buf); + stream << "vec["; + for (int i = 0; i != Vectorized::size(); i++) { + if (i != 0) { + stream << ", "; + } + stream << buf[i]; + } + stream << "]"; + return stream; +} + + +#if defined(CPU_CAPABILITY_AVX512) + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ CAST (AVX512) ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template<> +inline Vectorized cast(const Vectorized& src) { + return _mm512_castpd_ps(src); +} + +template<> +inline Vectorized cast(const Vectorized& src) { + return _mm512_castps_pd(src); +} + +template<> +inline Vectorized cast(const Vectorized& src) { + return _mm512_castsi512_ps(src); +} + +template<> +inline Vectorized cast(const Vectorized& src) { + return _mm512_castsi512_pd(src); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ GATHER ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +#ifndef _MSC_VER +// MSVC is not working well on complex function overload. +template +std::enable_if_t> +inline gather(const double* base_addr, const Vectorized& vindex) { + return _mm512_i64gather_pd(vindex, base_addr, scale); +} + +template +std::enable_if_t> +inline gather(const float* base_addr, const Vectorized& vindex) { + return _mm512_i32gather_ps(vindex, base_addr, scale); +} +#endif +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ MASK GATHER ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +#ifndef _MSC_VER +// MSVC is not working well on complex function overload. +template +std::enable_if_t> +inline mask_gather(const Vectorized& src, const double* base_addr, + const Vectorized& vindex, Vectorized& mask) { + auto all_ones = _mm512_castsi512_pd(_mm512_set1_epi64(0xFFFFFFFFFFFFFFFF)); + auto mask_ = _mm512_cmp_pd_mask(all_ones, mask.values, _CMP_EQ_OQ); + return _mm512_mask_i64gather_pd(src, mask_, vindex, base_addr, scale); +} + +template +std::enable_if_t> +inline mask_gather(const Vectorized& src, const float* base_addr, + const Vectorized& vindex, Vectorized& mask) { + auto all_ones = _mm512_castsi512_ps(_mm512_set1_epi32(0xFFFFFFFF)); + auto mask_ = _mm512_cmp_ps_mask(all_ones, mask.values, _CMP_EQ_OQ); + return _mm512_mask_i32gather_ps(src, mask_, vindex, base_addr, scale); +} +#endif +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ CONVERT ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template<> +Vectorized +inline convert_to_int_of_same_size(const Vectorized &src) { + return _mm512_cvtpd_epi64(src); +} + +template<> +Vectorized +inline convert_to_int_of_same_size(const Vectorized &src) { + return _mm512_cvttps_epi32(src); +} + +template<> +Vectorized +inline convert_to_fp_of_same_size(const Vectorized &src) { + return _mm512_cvtepi64_pd(src); +} + +template<> +Vectorized +inline convert_to_fp_of_same_size(const Vectorized &src) { + return _mm512_cvtepi32_ps(src); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ INTERLEAVE ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template <> +std::pair, Vectorized> +inline interleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, a1, a3, a3, a4, a5, a6, a7} + // b = {b0, b1, b2, b3, b4, b5, b6, b7} + // group cols crossing lanes: + // return {a0, b0, a1, b1, a2, b2, a3, b3} + // {a4, b4, a5, b5, a6, b6, a7, b7} + __m512i idx1 = _mm512_set_epi64(11, 3, 10, 2, 9, 1, 8, 0); + __m512i idx2 = _mm512_set_epi64(15, 7, 14, 6, 13, 5, 12, 4); + return std::make_pair(_mm512_mask_permutex2var_pd(a, 0xff, idx1, b), + _mm512_mask_permutex2var_pd(a, 0xff, idx2, b)); +} + +template <> +std::pair, Vectorized> +inline interleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11, a12, a13, a14, a15} + // b = {b0, b1, b2, b3, b4, b5, b6, b7, b8, b9, b10, b11, b12, b13, b14, b15} + // + // return: + // {a0, b0, a1, b1, a2, b2, a3, b3, a4, b4, a5, b5, a6, b6, a7, b7} + // {a8, b8, a9, b9, a10, b10, a11, b11, a12, b12, a13, b13, a14, b14, a15, b15} + __m512i idx1 = _mm512_set_epi32(23, 7, 22, 6, 21, 5, 20, 4, + 19, 3, 18, 2, 17, 1, 16, 0); + __m512i idx2 = _mm512_set_epi32(31, 15, 30, 14, 29, 13, 28, 12, + 27, 11, 26, 10, 25, 9, 24, 8); + return std::make_pair(_mm512_mask_permutex2var_ps(a, 0xffff, idx1, b), + _mm512_mask_permutex2var_ps(a, 0xffff, idx2, b)); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ DEINTERLEAVE ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template <> +std::pair, Vectorized> +inline deinterleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1, a2, b2, a3, b3} + // b = {a4, b4, a5, b5, a6, b6, a7, b7} + // output: + // return {a0, a1, a2, a3, a4, a5, a6, a7} + // {b0, b1, b2, b3, b4, b5, b6, b7} + // The members of indices have been written in binary format for better understandability + __m512i idx1 = _mm512_set_epi64(14, 12, 10, 8, 6, 4, 2, 0); + __m512i idx2 = _mm512_set_epi64(15, 13, 11, 9, 7, 5, 3, 1); + + return std::make_pair(_mm512_mask_permutex2var_pd(a, 0xff, idx1, b), + _mm512_mask_permutex2var_pd(a, 0xff, idx2, b)); +} + +template <> +std::pair, Vectorized> +inline deinterleave2(const Vectorized& a, const Vectorized& b) { + // inputs: + // a = {a0, b0, a1, b1, a2, b2, a3, b3, a4, b4, a5, b5, a6, b6, a7, b7} + // b = {a8, b8, a9, b9, a10, b10, a11, b11, a12, b12, a13, b13, a14, b14, a15, b15} + // output: + // return {a0, a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11, a12, a13, a14, a15} + // {b0, b1, b2, b3, b4, b5, b6, b7, b8, b9, b10, b11, b12, b13, b14, b15} + __m512i idx1 = _mm512_set_epi32(30, 28, 26, 24, 22, 20, 18, 16, + 14, 12, 10, 8, 6, 4, 2, 0); + __m512i idx2 = _mm512_set_epi32(31, 29, 27, 25, 23, 21, 19, 17, + 15, 13, 11, 9, 7, 5, 3, 1); + + return std::make_pair(_mm512_mask_permutex2var_ps(a, 0xffff, idx1, b), + _mm512_mask_permutex2var_ps(a, 0xffff, idx2, b)); +} + +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ FLIP ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +template<> +inline Vectorized flip(const Vectorized & v) { + const __m512i mask = _mm512_set_epi32(0, 1, 2, 3, 4, 5, 6, 7, + 8, 9, 10, 11, 12, 13, 14, 15); + return _mm512_permutexvar_ps(mask, v); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + const __m512i mask = _mm512_set_epi64(0, 1, 2, 3, 4, 5, 6, 7); + return _mm512_permutexvar_pd(mask, v); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + const __m512i mask = _mm512_set_epi64(0, 1, 2, 3, 4, 5, 6, 7); + return _mm512_permutexvar_epi64(mask, v); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + const __m512i mask = _mm512_set_epi32(0, 1, 2, 3, 4, 5, 6, 7, + 8, 9, 10, 11, 12, 13, 14, 15); + return _mm512_permutexvar_epi32(mask, v); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + const __m512i mask = _mm512_set_epi16( + 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, + 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31 + ); + return _mm512_permutexvar_epi16(mask, v); +} + +inline __m512i flip8(const __m512i & v) { + const __m512i mask1 = _mm512_set_epi8( + 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, + 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, + 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, + 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 + ); + const __m512i mask2 = _mm512_set_epi64(1, 0, 3, 2, 5, 4, 7, 6); + auto reversed_vec = _mm512_shuffle_epi8(v, mask1); + return _mm512_permutexvar_epi64(mask2, reversed_vec); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + return flip8(v); +} + +template<> +inline Vectorized flip(const Vectorized & v) { + return flip8(v); +} + +inline Vectorized operator&&( + const Vectorized& self, + const Vectorized& other) { + const __m512i* self_ = reinterpret_cast(self.as_bytes()); + const __m512i* other_ = reinterpret_cast(other.as_bytes()); + __m512i out = _mm512_and_si512(*self_, *other_); + Vectorized ret; + // We do not have a constructer that takes __m512i, so we need to memcpy + std::memcpy(ret, &out, ret.size() * sizeof(bool)); + return ret; +} + +#endif // defined(CPU_CAPABILITY_AVX512) + +}}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_bfloat16.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_bfloat16.h new file mode 100644 index 0000000000000000000000000000000000000000..f116929f8b088c32b2e09e19cf6a2f764babe06e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_bfloat16.h @@ -0,0 +1,1673 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include + +#if defined(CPU_CAPABILITY_AVX512) +#define SLEEF_STATIC_LIBS +#include +#endif + + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX512) + +#ifndef SLEEF_CONST +#if (defined(__GNUC__) || defined(__CLANG__)) && !defined(__INTEL_COMPILER) +#define SLEEF_CONST const +#else +#define SLEEF_CONST +#endif +#define SLEEF_CONST_OLD SLEEF_CONST +#else +#define SLEEF_CONST_OLD +#endif + +// bfloat16 conversion +static inline void cvtbf16_fp32(const __m256i& a, __m512& o) { + o = _mm512_castsi512_ps(_mm512_slli_epi32(_mm512_cvtepu16_epi32(a), 16)); +} + +static inline void cvtbf16_fp32(const __m512i& a, __m512& o1, __m512& o2) { + __m256i lo = _mm512_extracti32x8_epi32(a, 0); + __m256i hi = _mm512_extracti32x8_epi32(a, 1); + cvtbf16_fp32(lo, o1); + cvtbf16_fp32(hi, o2); +} + +static inline __m256i cvtfp32_bf16(const __m512& src) { + __m512i value = _mm512_castps_si512(src); + __m512i nan = _mm512_set1_epi32(0xffff); + auto mask_value = _mm512_cmp_ps_mask(src, src, _CMP_ORD_Q); + __m512i ones = _mm512_set1_epi32(0x1); + __m512i vec_bias = _mm512_set1_epi32(0x7fff); + // uint32_t lsb = (input >> 16) & 1; + auto t_value = _mm512_and_si512(_mm512_srli_epi32(value, 16), ones); + // uint32_t rounding_bias = 0x7fff + lsb; + t_value = _mm512_add_epi32(t_value, vec_bias); + // input += rounding_bias; + t_value = _mm512_add_epi32(t_value, value); + // input = input >> 16; + t_value = _mm512_srli_epi32(t_value, 16); + // Check NaN before converting back to bf16 + t_value = _mm512_mask_blend_epi32(mask_value, nan, t_value); + return _mm512_cvtusepi32_epi16(t_value); +} + +static inline __m512i cvtfp32_bf16(const __m512& a, const __m512& b) { + __m512i lo = _mm512_castps_si512(a); + __m512i hi = _mm512_castps_si512(b); + __m512i nan = _mm512_set1_epi32(0xffff); + auto mask_lo = _mm512_cmp_ps_mask(a, a, _CMP_ORD_Q); + auto mask_hi = _mm512_cmp_ps_mask(b, b, _CMP_ORD_Q); + __m512i ones = _mm512_set1_epi32(0x1); + __m512i vec_bias = _mm512_set1_epi32(0x7fff); + // uint32_t lsb = (input >> 16) & 1; + auto t_lo = _mm512_and_si512(_mm512_srli_epi32(lo, 16), ones); + auto t_hi = _mm512_and_si512(_mm512_srli_epi32(hi, 16), ones); + // uint32_t rounding_bias = 0x7fff + lsb; + t_lo = _mm512_add_epi32(t_lo, vec_bias); + t_hi = _mm512_add_epi32(t_hi, vec_bias); + // input += rounding_bias; + t_lo = _mm512_add_epi32(t_lo, lo); + t_hi = _mm512_add_epi32(t_hi, hi); + // input = input >> 16; + t_lo = _mm512_srli_epi32(t_lo, 16); + t_hi = _mm512_srli_epi32(t_hi, 16); + // Check NaN before converting back to bf16 + t_lo = _mm512_mask_blend_epi32(mask_lo, nan, t_lo); + t_hi = _mm512_mask_blend_epi32(mask_hi, nan, t_hi); + + t_lo = _mm512_packus_epi32(t_lo, t_hi); // t_hi[4-7] t_lo[4-7] t_hi[0-4] t_lo[0-4] + __m512i idx = _mm512_set_epi64(7, 5, 3, 1, 6, 4, 2, 0); + return _mm512_permutexvar_epi64(idx, t_lo); +} + +static inline __m512i merge_compare_result(const __m512& a, const __m512& b) { + __m512i lo = _mm512_castps_si512(a); + __m512i hi = _mm512_castps_si512(b); + lo = _mm512_srli_epi32(lo, 16); + hi = _mm512_srli_epi32(hi, 16); + auto out = _mm512_packus_epi32(lo, hi); + __m512i idx = _mm512_set_epi64(7, 5, 3, 1, 6, 4, 2, 0); + return _mm512_permutexvar_epi64(idx, out); +} + +// float16 conversion +static inline void cvtfp16_fp32(const __m256i& a, __m512& o) { + o = _mm512_cvtph_ps(a); +} + +static inline void cvtfp16_fp32(const __m512i& a, __m512& o1, __m512& o2) { + __m256i lo = _mm512_extracti32x8_epi32(a, 0); + __m256i hi = _mm512_extracti32x8_epi32(a, 1); + cvtfp16_fp32(lo, o1); + cvtfp16_fp32(hi, o2); +} + +static inline __m256i cvtfp32_fp16(const __m512& src) { + return _mm512_cvtps_ph( + src, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); +} + +static inline __m512i cvtfp32_fp16(const __m512& a, const __m512& b) { + __m256i lo = _mm512_cvtps_ph( + a, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + __m256i hi = _mm512_cvtps_ph( + b, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + __m512 t_lo = _mm512_castsi512_ps(_mm512_castsi256_si512(lo)); + __m256 t_hi = _mm256_castsi256_ps(hi); + return _mm512_castps_si512(_mm512_insertf32x8(t_lo, t_hi, 1)); +} + +// dtype conversion between float16/bfloat16 and float32 +template , int> = 0> +inline void cvt_to_fp32(const __m256i& a, __m512& o); +template <> inline void cvt_to_fp32(const __m256i& a, __m512& o) { + cvtbf16_fp32(a, o); +} +template <> inline void cvt_to_fp32(const __m256i& a, __m512& o) { + cvtfp16_fp32(a, o); +} + +template , int> = 0> +inline void cvt_to_fp32(const __m512i& a, __m512& o1, __m512& o2); +template <> inline void cvt_to_fp32(const __m512i& a, __m512& o1, __m512& o2) { + cvtbf16_fp32(a, o1, o2); +} +template <> inline void cvt_to_fp32(const __m512i& a, __m512& o1, __m512& o2) { + cvtfp16_fp32(a, o1, o2); +} + +template , int> = 0> +inline __m512i cvt_from_fp32(const __m512& a, const __m512& b); +template <> inline __m512i cvt_from_fp32(const __m512& a, const __m512& b) { + return cvtfp32_bf16(a, b); +} +template <> inline __m512i cvt_from_fp32(const __m512& a, const __m512& b) { + return merge_compare_result(a, b); +} +template <> inline __m512i cvt_from_fp32(const __m512& a, const __m512& b) { + return cvtfp32_fp16(a, b); +} +template <> inline __m512i cvt_from_fp32(const __m512& a, const __m512& b) { + return cvtfp32_fp16(a, b); +} + +template +class Vectorized16 { +static_assert( + is_reduced_floating_point_v, + "Support only float16 and bfloat16."); +private: + __m512i values; +public: + using value_type = uint16_t; + using size_type = int; + static constexpr size_type size() { + return 32; + } + Vectorized16() {} + Vectorized16(__m512i v) : values(v) {} + Vectorized16(T val) { + value_type uw = val.x; + values = _mm512_set1_epi16(uw); + } + Vectorized16(T val1, T val2, T val3, T val4, + T val5, T val6, T val7, T val8, + T val9, T val10, T val11, T val12, + T val13, T val14, T val15, T val16, + T val17, T val18, T val19, T val20, + T val21, T val22, T val23, T val24, + T val25, T val26, T val27, T val28, + T val29, T val30, T val31, T val32) { + values = _mm512_set_epi16( + val32.x, val31.x, val30.x, val29.x, val28.x, val27.x, val26.x, val25.x, + val24.x, val23.x, val22.x, val21.x, val20.x, val19.x, val18.x, val17.x, + val16.x, val15.x, val14.x, val13.x, val12.x, val11.x, val10.x, val9.x, + val8.x, val7.x, val6.x, val5.x, val4.x, val3.x, val2.x, val1.x); + } + operator __m512i() const { + return values; + } + T& operator[](int idx) = delete; + const T& operator[](int idx) const = delete; + int zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit and others are translated to 0-bit + return _mm512_cmpeq_epi16_mask(values, _mm512_set1_epi16(0)); + } + static Vectorized loadu(const void* ptr, int16_t count = size()) { + if (count == size()) + return _mm512_loadu_si512(reinterpret_cast(ptr)); + + __mmask32 mask = (1ULL << count) - 1; + return _mm512_maskz_loadu_epi16(mask, ptr); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + _mm512_storeu_si512(reinterpret_cast<__m512i*>(ptr), values); + } else if (count > 0) { + __mmask32 mask = (1ULL << count) - 1; + _mm512_mask_storeu_epi16(ptr, mask, values); + } + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + return _mm512_mask_blend_epi16(mask, a.values, b.values); + } + static Vectorized blendv(const Vectorized& a, + const Vectorized& b, const Vectorized& mask) { + auto all_ones = _mm512_set1_epi16(0xFFFF); + auto mask_ = _mm512_cmp_epi16_mask(mask, all_ones, _MM_CMPINT_EQ); + return _mm512_mask_blend_epi16(mask_, a.values, b.values); + } + template + static Vectorized arange(T base = 0.f, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step, + base + 8 * step, base + 9 * step, base + 10 * step, base + 11 * step, + base + 12 * step, base + 13 * step, base + 14 * step, base + 15 * step, + base + 16 * step, base + 17 * step, base + 18 * step, base + 19 * step, + base + 20 * step, base + 21 * step, base + 22 * step, base + 23 * step, + base + 24 * step, base + 25 * step, base + 26 * step, base + 27 * step, + base + 28 * step, base + 29 * step, base + 30 * step, base + 31 * step); + } + static Vectorized set(const Vectorized& a, + const Vectorized& b, int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + case 8: + return blend<255>(a, b); + case 9: + return blend<511>(a, b); + case 10: + return blend<1023>(a, b); + case 11: + return blend<2047>(a, b); + case 12: + return blend<4095>(a, b); + case 13: + return blend<8191>(a, b); + case 14: + return blend<16383>(a, b); + case 15: + return blend<32767>(a, b); + case 16: + return blend<65535>(a, b); + case 17: + return blend<131071>(a, b); + case 18: + return blend<262143>(a, b); + case 19: + return blend<524287>(a, b); + case 20: + return blend<1048575>(a, b); + case 21: + return blend<2097151>(a, b); + case 22: + return blend<4194303>(a, b); + case 23: + return blend<8388607>(a, b); + case 24: + return blend<16777215>(a, b); + case 25: + return blend<33554431>(a, b); + case 26: + return blend<67108863>(a, b); + case 27: + return blend<134217727>(a, b); + case 28: + return blend<268435455>(a, b); + case 29: + return blend<536870911>(a, b); + case 30: + return blend<1073741823>(a, b); + case 31: + return blend<2147483647>(a, b); + } + return b; + } + #pragma clang diagnostic push + #pragma clang diagnostic ignored "-Wignored-qualifiers" + + Vectorized map(SLEEF_CONST __m512 (*SLEEF_CONST_OLD vop)(__m512)) const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + const auto o1 = vop(lo); + const auto o2 = vop(hi); + return cvt_from_fp32(o1, o2); + } + Vectorized isnan() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + __mmask16 lo_mask, hi_mask; + __m512 zero = _mm512_set1_ps(0.0); + __m512i zeroi = _mm512_castps_si512(zero); + lo_mask = _mm512_cmp_ps_mask(lo, zero, _CMP_UNORD_Q); + lo = _mm512_castsi512_ps(_mm512_mask_set1_epi32(zeroi, lo_mask, 0xFFFF'FFFF)); + hi_mask = _mm512_cmp_ps_mask(hi, zero, _CMP_UNORD_Q); + hi = _mm512_castsi512_ps(_mm512_mask_set1_epi32(zeroi, hi_mask, 0xFFFF'FFFF)); + return merge_compare_result(lo, hi); + } + #pragma clang diagnostic pop + Vectorized abs() const { + return _mm512_andnot_si512(_mm512_set1_epi16(0x8000), values); + } + Vectorized angle() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + auto angle_lambda = [](__m512 values) { + const auto zero_vec = _mm512_set1_ps(0.f); + const auto nan_vec = _mm512_set1_ps(NAN); + const auto not_nan_mask = _mm512_cmp_ps_mask(values, values, _CMP_EQ_OQ); + const auto non_nan_mask_vec = _mm512_mask_set1_epi32(_mm512_castps_si512(zero_vec), + not_nan_mask, 0xFFFFFFFF); + const auto nan_mask = _mm512_cmp_ps_mask(_mm512_castsi512_ps(non_nan_mask_vec), + zero_vec, _CMP_EQ_OQ); + const auto pi = _mm512_set1_ps(c10::pi); + + const auto neg_mask = _mm512_cmp_ps_mask(values, zero_vec, _CMP_LT_OQ); + auto angle = _mm512_mask_blend_ps(neg_mask, zero_vec, pi); + angle = _mm512_mask_blend_ps(nan_mask, angle, nan_vec); + return angle; + }; + auto o1 = angle_lambda(lo); + auto o2 = angle_lambda(hi); + return cvt_from_fp32(o1, o2); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm512_set1_epi16(0); + } + Vectorized conj() const { + return *this; + } + Vectorized acos() const { + return map(Sleef_acosf16_u10); + } + Vectorized acosh() const { + return map(Sleef_acoshf16_u10); + } + Vectorized asin() const { + return map(Sleef_asinf16_u10); + } + Vectorized asinh() const { + return map(Sleef_asinhf16_u10); + } + Vectorized atan() const { + return map(Sleef_atanf16_u10); + } + Vectorized atanh() const { + return map(Sleef_atanhf16_u10); + } + Vectorized atan2(const Vectorized &b) const { + __m512 lo, hi; + __m512 b1, b2; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(b.values, b1, b2); + auto o1 = Sleef_atan2f16_u10(lo, b1); + auto o2 = Sleef_atan2f16_u10(hi, b2); + return cvt_from_fp32(o1, o2); + } + Vectorized copysign(const Vectorized &sign) const { + // copy sign bit (0x8000) from sign and remaining bits from values + __m512i mask_value = _mm512_set1_epi32(~0x80008000); + __m512i mask_signbit = _mm512_set1_epi32(0x80008000); + return Vectorized( + _mm512_or_si512( + _mm512_and_si512(values, mask_value), + _mm512_and_si512(sign, mask_signbit))); + } + Vectorized erf() const { + return map(Sleef_erff16_u10); + } + Vectorized erfc() const { + return map(Sleef_erfcf16_u15); + } + Vectorized erfinv() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + __at_align__ float tmp1[size() / 2], tmp2[size() / 2]; + _mm512_storeu_ps(reinterpret_cast(tmp1), lo); + _mm512_storeu_ps(reinterpret_cast(tmp2), hi); + for (int64_t i = 0; i < size() / 2; i++) { + tmp1[i] = calc_erfinv(tmp1[i]); + tmp2[i] = calc_erfinv(tmp2[i]); + } + auto o1 = _mm512_loadu_ps(tmp1); + auto o2 = _mm512_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized exp() const { + return map(Sleef_expf16_u10); + } + Vectorized exp2() const { + return map(Sleef_exp2f16_u10); + } + Vectorized expm1() const { + return map(Sleef_expm1f16_u10); + } + Vectorized exp_u20() const { + return exp(); + } + Vectorized fmod(const Vectorized & q) const { + __m512 x_lo, x_hi; + cvt_to_fp32(values, x_lo, x_hi); + __m512 q_lo, q_hi; + cvtbf16_fp32(q.values, q_lo, q_hi); + auto o1 = Sleef_fmodf16(x_lo, q_lo); + auto o2 = Sleef_fmodf16(x_hi, q_hi); + return cvt_from_fp32(o1, o2); + } + Vectorized hypot(const Vectorized &b) const { + __m512 lo, hi; + __m512 b1, b2; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(b.values, b1, b2); + auto o1 = Sleef_hypotf16_u05(lo, b1); + auto o2 = Sleef_hypotf16_u05(hi, b2); + return cvt_from_fp32(o1, o2); + } + Vectorized i0() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + __at_align__ float tmp1[size() / 2], tmp2[size() / 2]; + _mm512_storeu_ps(reinterpret_cast(tmp1), lo); + _mm512_storeu_ps(reinterpret_cast(tmp2), hi); + for (int64_t i = 0; i < size() / 2; i++) { + tmp1[i] = calc_i0(tmp1[i]); + tmp2[i] = calc_i0(tmp2[i]); + } + auto o1 = _mm512_loadu_ps(tmp1); + auto o2 = _mm512_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized i0e() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + constexpr auto sz = size(); + __at_align__ float tmp1[sz / 2], tmp2[sz / 2]; + _mm512_storeu_ps(reinterpret_cast(tmp1), lo); + _mm512_storeu_ps(reinterpret_cast(tmp2), hi); + + for (auto i = decltype(sz){0}; i < sz / 2; i++) { + tmp1[i] = calc_i0e(tmp1[i]); + tmp2[i] = calc_i0e(tmp2[i]); + } + const auto o1 = _mm512_loadu_ps(tmp1); + const auto o2 = _mm512_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized digamma() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + constexpr auto sz = size(); + __at_align__ float tmp1[sz / 2], tmp2[sz / 2]; + _mm512_storeu_ps(reinterpret_cast(tmp1), lo); + _mm512_storeu_ps(reinterpret_cast(tmp2), hi); + + for (auto i = decltype(sz){0}; i < sz / 2; i++) { + tmp1[i] = calc_digamma(tmp1[i]); + tmp2[i] = calc_digamma(tmp2[i]); + } + const auto o1 = _mm512_loadu_ps(tmp1); + const auto o2 = _mm512_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized igamma(const Vectorized &x) const { + __m512 lo, hi; + __m512 xlo, xhi; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(x.values, xlo, xhi); + __at_align__ float tmp1[size() / 2], tmp2[size() / 2]; + _mm512_storeu_ps(reinterpret_cast(tmp1), lo); + _mm512_storeu_ps(reinterpret_cast(tmp2), hi); + __at_align__ float tmpx1[size() / 2], tmpx2[size() / 2]; + _mm512_storeu_ps(reinterpret_cast(tmpx1), xlo); + _mm512_storeu_ps(reinterpret_cast(tmpx2), xhi); + for (int64_t i = 0; i < size() / 2; ++i) { + tmp1[i] = calc_igamma(tmp1[i], tmpx1[i]); + tmp2[i] = calc_igamma(tmp2[i], tmpx2[i]); + } + auto o1 = _mm512_loadu_ps(tmp1); + auto o2 = _mm512_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + + Vectorized igammac(const Vectorized &x) const { + __m512 lo, hi; + __m512 xlo, xhi; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(x.values, xlo, xhi); + __at_align__ float tmp1[size() / 2], tmp2[size() / 2]; + _mm512_storeu_ps(reinterpret_cast(tmp1), lo); + _mm512_storeu_ps(reinterpret_cast(tmp2), hi); + __at_align__ float tmpx1[size() / 2], tmpx2[size() / 2]; + _mm512_storeu_ps(reinterpret_cast(tmpx1), xlo); + _mm512_storeu_ps(reinterpret_cast(tmpx2), xhi); + for (int64_t i = 0; i < size() / 2; ++i) { + tmp1[i] = calc_igammac(tmp1[i], tmpx1[i]); + tmp2[i] = calc_igammac(tmp2[i], tmpx2[i]); + } + auto o1 = _mm512_loadu_ps(tmp1); + auto o2 = _mm512_loadu_ps(tmp2); + return cvt_from_fp32(o1, o2); + } + Vectorized log() const { + return map(Sleef_logf16_u10); + } + Vectorized log2() const { + return map(Sleef_log2f16_u10); + } + Vectorized log10() const { + return map(Sleef_log10f16_u10); + } + Vectorized log1p() const { + return map(Sleef_log1pf16_u10); + } + Vectorized sin() const { + return map(Sleef_sinf16_u10); + } + Vectorized sinh() const { + return map(Sleef_sinhf16_u10); + } + Vectorized cos() const { + return map(Sleef_cosf16_u10); + } + Vectorized cosh() const { + return map(Sleef_coshf16_u10); + } + Vectorized ceil() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm512_ceil_ps(lo); + auto o2 = _mm512_ceil_ps(hi); + return cvt_from_fp32(o1, o2); + } + Vectorized floor() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm512_floor_ps(lo); + auto o2 = _mm512_floor_ps(hi); + return cvt_from_fp32(o1, o2); + } + Vectorized neg() const { + return _mm512_xor_si512(values, _mm512_set1_epi16(0x8000)); + } + Vectorized round() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm512_roundscale_ps(lo, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + auto o2 = _mm512_roundscale_ps(hi, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + return cvt_from_fp32(o1, o2); + } + Vectorized tan() const { + return map(Sleef_tanf16_u10); + } + Vectorized tanh() const { + return map(Sleef_tanhf16_u10); + } + Vectorized trunc() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm512_roundscale_ps(lo, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + auto o2 = _mm512_roundscale_ps(hi, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + return cvt_from_fp32(o1, o2); + } + Vectorized lgamma() const { + return map(Sleef_lgammaf16_u10); + } + Vectorized sqrt() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + auto o1 = _mm512_sqrt_ps(lo); + auto o2 = _mm512_sqrt_ps(hi); + return cvt_from_fp32(o1, o2); + } + Vectorized reciprocal() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + auto ones = _mm512_set1_ps(1); + auto o1 = _mm512_div_ps(ones, lo); + auto o2 = _mm512_div_ps(ones, hi); + return cvt_from_fp32(o1, o2); + } + Vectorized rsqrt() const { + __m512 lo, hi; + cvt_to_fp32(values, lo, hi); + auto ones = _mm512_set1_ps(1); + auto o1 = _mm512_div_ps(ones, _mm512_sqrt_ps(lo)); + auto o2 = _mm512_div_ps(ones, _mm512_sqrt_ps(hi)); + return cvt_from_fp32(o1, o2); + } + Vectorized pow(const Vectorized &b) const { + __m512 lo, hi; + __m512 b1, b2; + cvt_to_fp32(values, lo, hi); + cvt_to_fp32(b.values, b1, b2); + auto o1 = Sleef_powf16_u10(lo, b1); + auto o2 = Sleef_powf16_u10(hi, b2); + return cvt_from_fp32(o1, o2); + } +private: + template + Vectorized inline binary_compare(const VectorizedType& b, Op op) const { + __m512 a_lo, a_hi; + __m512 b_lo, b_hi; + cvt_to_fp32(values, a_lo, a_hi); + cvt_to_fp32(b.values, b_lo, b_hi); + auto o1 = op(a_lo, b_lo); + auto o2 = op(a_hi, b_hi); + return cvt_from_fp32(o1, o2); + } + +public: + Vectorized inline operator>(const Vectorized& other) const { + return binary_compare(other, [](__m512 x, __m512 y) { + auto zero_vec = _mm512_set1_epi32(0); + auto cmp = _mm512_cmp_ps_mask(x, y, _CMP_GT_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, cmp, 0xFFFFFFFF)); + }); + } + Vectorized inline operator<(const Vectorized& other) const { + return binary_compare(other, [](__m512 x, __m512 y) { + auto zero_vec = _mm512_set1_epi32(0); + auto cmp = _mm512_cmp_ps_mask(x, y, _CMP_LT_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, cmp, 0xFFFFFFFF)); + }); + } + Vectorized inline operator>=(const Vectorized& other) const { + return binary_compare(other, [](__m512 x, __m512 y) { + auto zero_vec = _mm512_set1_epi32(0); + auto cmp = _mm512_cmp_ps_mask(x, y, _CMP_GE_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, cmp, 0xFFFFFFFF)); + }); + } + Vectorized inline operator<=(const Vectorized& other) const { + return binary_compare(other, [](__m512 x, __m512 y) { + auto zero_vec = _mm512_set1_epi32(0); + auto cmp = _mm512_cmp_ps_mask(x, y, _CMP_LE_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, cmp, 0xFFFFFFFF)); + }); + } + Vectorized inline operator==(const Vectorized16& other) const { + return binary_compare(other, [](__m512 x, __m512 y) { + auto zero_vec = _mm512_set1_epi32(0); + auto cmp = _mm512_cmp_ps_mask(x, y, _CMP_EQ_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, cmp, 0xFFFFFFFF)); + }); + } + Vectorized inline operator!=(const Vectorized16& other) const { + return binary_compare(other, [](__m512 x, __m512 y) { + auto zero_vec = _mm512_set1_epi32(0); + auto cmp = _mm512_cmp_ps_mask(x, y, _CMP_NEQ_UQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, cmp, 0xFFFFFFFF)); + }); + } +}; + +template +static inline Vectorized binary_op_as_fp32(const Vectorized& a, const Vectorized& b, Op op) { + __m512 a_lo, a_hi; + __m512 b_lo, b_hi; + cvt_to_fp32(__m512i(a), a_lo, a_hi); + cvt_to_fp32(__m512i(b), b_lo, b_hi); + auto o1 = op(a_lo, b_lo); + auto o2 = op(a_hi, b_hi); + return cvt_from_fp32(o1, o2); +} + +template <> +class Vectorized: public Vectorized16 { +public: + using Vectorized16::Vectorized16; + + using value_type = BFloat16; + + Vectorized frac() const; + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m512& x, const __m512& y) { return _mm512_add_ps(x, y); }); +} +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m512& x, const __m512& y) { return _mm512_sub_ps(x, y); }); +} +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m512& x, const __m512& y) { return _mm512_mul_ps(x, y); }); +} +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m512& x, const __m512& y) { return _mm512_div_ps(x, y); }); +} +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return _mm512_and_si512(a, b); +} +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return _mm512_or_si512(a, b); +} +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return _mm512_xor_si512(a, b); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0f); +} + +// frac. Implement this here so we can use subtraction +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + __m512 a_lo, a_hi; + __m512 b_lo, b_hi; + cvtbf16_fp32(__m512i(a), a_lo, a_hi); + cvtbf16_fp32(__m512i(b), b_lo, b_hi); + auto max_lo = _mm512_max_ps(a_lo, b_lo); + auto max_hi = _mm512_max_ps(a_hi, b_hi); + auto nan_lo_mask = _mm512_cmp_ps_mask(a_lo, b_lo, _CMP_UNORD_Q); + auto nan_hi_mask = _mm512_cmp_ps_mask(a_hi, b_hi, _CMP_UNORD_Q); + auto nan_lo = _mm512_castsi512_ps(_mm512_set1_epi32(nan_lo_mask)); + auto nan_hi = _mm512_castsi512_ps(_mm512_set1_epi32(nan_hi_mask)); + // Exploit the fact that all-ones is a NaN. + auto o1 = _mm512_or_ps(max_lo, nan_lo); + auto o2 = _mm512_or_ps(max_hi, nan_hi); + return cvtfp32_bf16(o1, o2); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + __m512 a_lo, a_hi; + __m512 b_lo, b_hi; + __m512i zero_vec = _mm512_set1_epi32(0); + cvtbf16_fp32(__m512i(a), a_lo, a_hi); + cvtbf16_fp32(__m512i(b), b_lo, b_hi); + auto min_lo = _mm512_min_ps(a_lo, b_lo); + auto min_hi = _mm512_min_ps(a_hi, b_hi); + auto nan_lo_mask = _mm512_cmp_ps_mask(a_lo, b_lo, _CMP_UNORD_Q); + auto nan_hi_mask = _mm512_cmp_ps_mask(a_hi, b_hi, _CMP_UNORD_Q); + auto nan_lo = _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, nan_lo_mask, + 0xFFFFFFFF)); + auto nan_hi = _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, nan_hi_mask, + 0xFFFFFFFF)); + // Exploit the fact that all-ones is a NaN. + auto o1 = _mm512_or_ps(min_lo, nan_lo); + auto o2 = _mm512_or_ps(min_hi, nan_hi); + return cvtfp32_bf16(o1, o2); +} + +template <> +Vectorized inline clamp(const Vectorized& a, + const Vectorized& min, const Vectorized& max) { + __m512 a_lo, a_hi; + __m512 min_lo, min_hi; + __m512 max_lo, max_hi; + cvtbf16_fp32(__m512i(a), a_lo, a_hi); + cvtbf16_fp32(__m512i(min), min_lo, min_hi); + cvtbf16_fp32(__m512i(max), max_lo, max_hi); + auto o1 = _mm512_min_ps(max_lo, _mm512_max_ps(min_lo, a_lo)); + auto o2 = _mm512_min_ps(max_hi, _mm512_max_ps(min_hi, a_hi)); + return cvtfp32_bf16(o1, o2); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + __m512 a_lo, a_hi; + __m512 max_lo, max_hi; + cvtbf16_fp32(__m512i(a), a_lo, a_hi); + cvtbf16_fp32(__m512i(max), max_lo, max_hi); + auto o1 = _mm512_min_ps(max_lo, a_lo); + auto o2 = _mm512_min_ps(max_hi, a_hi); + return cvtfp32_bf16(o1, o2); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + __m512 a_lo, a_hi; + __m512 min_lo, min_hi; + cvtbf16_fp32(__m512i(a), a_lo, a_hi); + cvtbf16_fp32(__m512i(min), min_lo, min_hi); + auto o1 = _mm512_max_ps(min_lo, a_lo); + auto o2 = _mm512_max_ps(min_hi, a_hi); + return cvtfp32_bf16(o1, o2); +} + +template <> +inline void convert(const BFloat16* src, BFloat16* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + auto vsrc = _mm512_loadu_si512(reinterpret_cast<__m512i*>((void*)(src + i))); + _mm512_storeu_si512(reinterpret_cast<__m512i*>((void*)(dst + i)), vsrc); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = src[i]; + } +} + +template <> +inline void convert(const float* src, BFloat16* dst, int64_t n) { + int64_t i; + for (i = 0; i + Vectorized::size() <= n; i += Vectorized::size()) { + __m512 a = _mm512_loadu_ps(&src[i]); + __m512 b = _mm512_loadu_ps(&src[i + 16]); + + __m512i bf = cvtfp32_bf16(a, b); + _mm512_storeu_si512(reinterpret_cast<__m512i*>(&dst[i]), bf); + } + for (; i < n; i++) { + dst[i] = c10::convert(src[i]); + } +} + +template <> +inline void convert(const double* src, BFloat16* dst, int64_t n) { + auto load_float = [](const double *src) -> __m512 { + // Load one float vector from an array of doubles + __m256 a = _mm512_cvtpd_ps(_mm512_loadu_pd(src)); + __m256 b = _mm512_cvtpd_ps(_mm512_loadu_pd(src + 8)); + return _mm512_insertf32x8(_mm512_castps256_ps512(a), b, 1); + }; + + int64_t i; + for (i = 0; i + Vectorized::size() <= n; i += Vectorized::size()) { + __m512 a = load_float(&src[i]); + __m512 b = load_float(&src[i + 16]); + + __m512i bf = cvtfp32_bf16(a, b); + _mm512_storeu_si512(reinterpret_cast<__m512i*>(&dst[i]), bf); + } + for (; i < n; i++) { + dst[i] = c10::convert(src[i]); + } +} + +template <> +Vectorized inline fmadd(const Vectorized& a, + const Vectorized& b, const Vectorized& c) { + __m512 a_lo, a_hi; + __m512 b_lo, b_hi; + __m512 c_lo, c_hi; + cvtbf16_fp32(__m512i(a), a_lo, a_hi); + cvtbf16_fp32(__m512i(b), b_lo, b_hi); + cvtbf16_fp32(__m512i(c), c_lo, c_hi); + auto o1 = _mm512_fmadd_ps(a_lo, b_lo, c_lo); + auto o2 = _mm512_fmadd_ps(a_hi, b_hi, c_hi); + return cvtfp32_bf16(o1, o2); +} + +static inline void _transpose_mxn_half_16_16(__m256i t[], __m512i u[]) { + __m512i r[8]; + // a0a1 a2a3 a4a5 a6a7 a8a9 a10a11 a12a13 a14a15 e0e1 e2e3 e4e5 e6e7 e8e9 e10e11 e12e13 e14e15 + // b0-b15 f0-f15 + // c0-c15 g0-g15 + // d0-d15 h0-h15 + // i0-i15 m0-m15 + // j0-j15 n0-n15 + // k0-k15 o0-o15 + // l0-l15 p0-p15 +#ifndef __msvc_cl__ +#pragma unroll(4) +#endif + for (int i = 0; i < 4; i++) { + r[i] = _mm512_inserti64x4(_mm512_castsi256_si512(t[i]), t[i + 4], 0x01); + r[i + 4] = _mm512_inserti64x4(_mm512_castsi256_si512(t[i + 8]), t[i + 12], 0x01); + } + + // u0: a0a1 b0b1 a2a3 b2b3 a8a9 b8b9 a10a11 b10b11 e0e1 f0f1 e2e3 f2f3 e8e9 f8f9 e10e11 f10f11 + // u1: a4a5 b4b5 a6a7 b6b7 a12a13 b12b13 a14a15 b14b15 e4e5 f4f5 e6e7 f6f7 e12e13 f12f13 e14e15 f14f15 + // u2: c0c1 d0d1 c2c3 d2d3 c8c9 d8d9 c10c11 d10d11 g0g1 h0h1 g2g3 h2h3 g8g9 h8h9 g10g11 h10h11 + // u3: c4c5 d4b5 c6c7 d6b7 c12c13 d12d13 c14c15 d14d15 g4g5 h4h5 g6g7 h6h7 g12g13 h12h13 g14g15 h14h15 + // i j m n + // k l o p +#ifndef __msvc_cl__ +#pragma unroll(4) +#endif + for (int i = 0; i < 8; i += 2) { + u[i] = _mm512_unpacklo_epi32(r[i], r[i + 1]); + u[i + 1] = _mm512_unpackhi_epi32(r[i], r[i + 1]); + } + + // r0: a0a1 b0b1 c0c1 d0d1 a8a9 b8b9 c8c9 d8d9 e0e1 f0f1 g0g1 h0h1 e8e9 f8f9 g8g9 h8h9 + // r1: a2a3 b2b3 c2c3 d2d3 a10a11 b10b11 c10c11 d10d11 e2e3 f2f3 g2g3 h2h3 e10e11 f10f11 g10g11 h10h11 + // r2: a4a5 b4b5 c4c5 d4b5 a12a13 b12b13 c12c13 d12d13 + // r3: a6a7 b6b7 c6c7 d6b7 a14a15 b14b15 c14c15 d14d15 + // r4: i j k l m n o p + r[0] = _mm512_unpacklo_epi64(u[0], u[2]); + r[1] = _mm512_unpackhi_epi64(u[0], u[2]); + r[2] = _mm512_unpacklo_epi64(u[1], u[3]); + r[3] = _mm512_unpackhi_epi64(u[1], u[3]); + r[4] = _mm512_unpacklo_epi64(u[4], u[6]); + r[5] = _mm512_unpackhi_epi64(u[4], u[6]); + r[6] = _mm512_unpacklo_epi64(u[5], u[7]); + r[7] = _mm512_unpackhi_epi64(u[5], u[7]); + + __m512i const1 = _mm512_set_epi32( + 0x00370035, + 0x00330031, + 0x00270025, + 0x00230021, + 0x00170015, + 0x00130011, + 0x00070005, + 0x00030001, + 0x00360034, + 0x00320030, + 0x00260024, + 0x00220020, + 0x00160014, + 0x00120010, + 0x00060004, + 0x00020000); + __m512i const2 = _mm512_set_epi32( + 0x003f003d, + 0x003b0039, + 0x002f002d, + 0x002b0029, + 0x001f001d, + 0x001b0019, + 0x000f000d, + 0x000b0009, + 0x003e003c, + 0x003a0038, + 0x002e002c, + 0x002a0028, + 0x001e001c, + 0x001a0018, + 0x000e000c, + 0x000a0008); + // merge values from two regs + // 0-- 1-- + // 8-- 9-- + // 2-- 3-- + // 10-- 11-- + // 4-- 5-- + // 12-- 13-- + // 6-- 7-- + // 14-- 15-- +#ifndef __msvc_cl__ +#pragma unroll(4) +#endif + for (int i = 0; i < 4; i++) { + u[i] = _mm512_permutex2var_epi16(r[i], const1, r[i + 4]); + u[i + 4] = _mm512_permutex2var_epi16(r[i], const2, r[i + 4]); + } +} + +// TODO(Leslie): Add the AVX2 Version of transpose_mxn for BFloat16 and Float16 +// Code referred to FBGEMM: +// https://github.com/pytorch/FBGEMM/blob/39a423e4ad1a04b77fea81c7d09c3e6f8984fae9/src/UtilsAvx512.cc#L1483-L1607 +template<> +inline void transpose_mxn( + const BFloat16* src, + int64_t ld_src, + BFloat16* dst, + int64_t ld_dst) { + __m256i t[16]; + // load from src to registers + // a: a0 a1 a2 a3 a4 a5 a6 a7 a8 a9 a10 a11 a12 a13 a14 a15 + // b: b0 b1 b2 b3 b4 b5 b6 b7 b8 b9 b10 b11 b12 b13 b14 b15 + // c: c0 c1 c2 c3 c4 c5 c6 c7 c8 c9 c10 c11 c12 c13 c14 c15 + // d: d0 d1 d2 d3 d4 d5 d6 d7 d8 d9 d10 d11 d12 d13 d14 d15 + // e: e0 e1 e2 e3 e4 e5 e6 e7 e8 e9 e10 e11 e12 e13 e14 e15 + // f: f0 f1 f2 f3 f4 f5 f6 f7 f8 f9 f10 f11 f12 f13 f14 f15 + // g: g0 g1 g2 g3 g4 g5 g6 g7 g8 g9 g10 g11 g12 g13 g14 g15 + // h: h0 h1 h2 h3 h4 h5 h6 h7 h8 h9 h10 h11 h12 h13 h14 h15 + // i: i0 i1 i2 i3 i4 i5 i6 i7 i8 i9 i10 i11 i12 i13 i14 i15 + // j: j0 j1 j2 j3 j4 j5 j6 j7 j8 j9 j10 j11 j12 j13 j14 j15 + // k: k0 k1 k2 k3 k4 k5 k6 k7 k8 k9 k10 k11 k12 k13 k14 k15 + // l: l0 l1 l2 l3 l4 l5 l6 l7 l8 l9 l10 l11 l12 l13 l14 l15 + // m: m0 m1 m2 m3 m4 m5 m6 m7 m8 m9 m10 m11 m12 m13 m14 m15 + // n: n0 n1 n2 n3 n4 n5 n6 n7 n8 n9 n10 n11 n12 n13 n14 n15 + // o: o0 o1 o2 o3 o4 o5 o6 o7 o8 o9 o10 o11 o12 o13 o14 o15 + // p: p0 p1 p2 p3 p4 p5 p6 p7 p8 p9 p10 p11 p12 p13 p14 p15 +#ifndef __msvc_cl__ +#pragma unroll(16) +#endif + for (int i = 0; i < 16; i++) { + t[i] = _mm256_loadu_si256(reinterpret_cast(src + i * ld_src)); + } + + __m512i u[8]; + _transpose_mxn_half_16_16(t, u); + +#ifndef __msvc_cl__ +#pragma unroll(8) +#endif + for (int i = 0; i < 8; i++) { + _mm256_storeu_si256( + reinterpret_cast<__m256i*>(dst + (i * 2) * ld_dst), + _mm512_extracti32x8_epi32(u[i], 0x0)); + _mm256_storeu_si256( + reinterpret_cast<__m256i*>(dst + (i * 2 + 1) * ld_dst), + _mm512_extracti32x8_epi32(u[i], 0x01)); + } +} + +// Code referred to FBGEMM: +// https://github.com/pytorch/FBGEMM/blob/39a423e4ad1a04b77fea81c7d09c3e6f8984fae9/src/UtilsAvx512.cc#L1483-L1607 +template<> +inline void transpose_mxn( + const Half* src, + int64_t ld_src, + Half* dst, + int64_t ld_dst) { + __m256i t[16]; + // load from src to registers + // Same matrix indices as above transpose_mxn +#ifndef __msvc_cl__ +#pragma unroll(16) +#endif + for (int i = 0; i < 16; i++) { + t[i] = _mm256_loadu_si256(reinterpret_cast(src + i * ld_src)); + } + + __m512i u[8]; + _transpose_mxn_half_16_16(t, u); + +#ifndef __msvc_cl__ +#pragma unroll(8) +#endif + for (int i = 0; i < 8; i++) { + _mm256_storeu_si256( + reinterpret_cast<__m256i*>(dst + (i * 2) * ld_dst), + _mm512_extracti32x8_epi32(u[i], 0x0)); + _mm256_storeu_si256( + reinterpret_cast<__m256i*>(dst + (i * 2 + 1) * ld_dst), + _mm512_extracti32x8_epi32(u[i], 0x01)); + } +} + +static inline void _transpose_mxn_half_32_32(__m512i r[], __m512i d[]) { + // t[0]: 0 32 1 33 2 34 3 35 8 40 9 41 10 42 11 43 16 ... 59 + // t[1]: 4 36 5 37 6 38 7 39 12 44 13 45 14 46 15 47 20 ... 63 + // t[2]: 64 96 65 97 66 98 67 99 72 104 73 105 74 106 75 ... 123 + // t[3]: 68 100 69 101 70 102 71 103 76 108 77 109 78 110 79 111 84 ... 127 + // t[4]: 128 160 129 161 130 162 131 163 136 168 137 169 138 170 139 171 144 ... 187 + // t[5]: 132 164 133 165 134 166 135 167 140 172 141 173 142 174 143 175 148 ... 191 + // t[6]: 192 224 193 225 194 226 195 227 200 232 201 233 202 234 203 235 208 ... 251 + // t[7]: 196 228 197 229 198 230 199 231 204 236 205 237 206 238 207 239 212 ... 255 + // t[8]: 256 288 257 289 258 290 259 291 264 296 265 297 266 298 267 299 272 ... 315 + // t[9]: 260 292 261 293 262 294 263 295 268 300 269 301 270 302 271 303 276 ... 319 + // t[10]: 320 352 321 353 322 354 323 355 328 360 329 361 330 362 331 363 336 ... 379 + // t[11]: 324 356 325 357 326 358 327 359 332 364 333 365 334 366 335 367 340 ... 383 + // t[12]: 384 416 385 417 386 418 387 419 392 424 393 425 394 426 395 427 400 ... 443 + // t[13]: 388 420 389 421 390 422 391 423 396 428 397 429 398 430 399 431 404 ... 447 + // t[14]: 448 480 449 481 450 482 451 483 456 488 457 489 458 490 459 491 464 ... 507 + // t[15]: 452 484 453 485 454 486 455 487 460 492 461 493 462 494 463 495 468 ... 511 + // t[16]: 512 544 513 545 514 546 515 547 520 552 521 553 522 554 523 555 528 ... 571 + // ... + // t[31]: 964 996 965 997 966 998 967 999 972 1004 973 1005 974 1006 975 1007 980 ... 1023 +#ifndef __msvc_cl__ +#pragma unroll(16) +#endif + for (int i = 0; i < 16; ++i) { + d[i * 2] = _mm512_unpacklo_epi16(r[i * 2], r[i * 2 + 1]); + d[i * 2 + 1] = _mm512_unpackhi_epi16(r[i * 2], r[i * 2 + 1]); + } + + // t[0]: 0 32 64 96 1 33 65 97 8 40 72 104 9 41 73 105 16 ... 121 + // t[1]: 2 34 66 98 3 35 67 99 10 42 74 106 11 43 75 107 18 ... 123 + // t[2]: 4 36 68 100 5 37 69 101 12 44 76 108 13 45 77 109 20 ... 125 + // t[3]: 6 38 70 102 7 39 71 103 14 46 78 110 15 47 79 111 22 ... 127 + // t[4]: 128 160 192 224 129 161 193 225 136 168 200 232 137 169 201 233 144 ... 249 + // t[5]: 130 162 194 226 131 163 195 227 138 170 202 234 139 171 203 235 146 ... 251 + // t[6]: 132 164 196 228 133 165 197 229 140 172 204 236 141 173 205 237 148 ... 253 + // t[7]: 134 166 198 230 135 167 199 231 142 174 206 238 143 175 207 239 150 ... 255 + // t[8]: 256 288 320 352 257 289 321 353 264 296 328 360 265 297 329 361 272 ... 377 + // t[9]: 258 290 322 354 259 291 323 355 266 298 330 362 267 299 331 363 274 ... 379 + // t[10]: 260 292 324 356 261 293 325 357 268 300 332 364 269 301 333 365 276 ... 381 + // t[11]: 262 294 326 358 263 295 327 359 270 302 334 366 271 303 335 367 278 ... 383 + // t[12]: 384 416 448 480 385 417 449 481 392 424 456 488 393 425 457 489 400 ... 505 + // t[13]: 386 418 450 482 387 419 451 483 394 426 458 490 395 427 459 491 402 ... 507 + // t[14]: 388 420 452 484 389 421 453 485 396 428 460 492 397 429 461 493 404 ... 509 + // t[15]: 390 422 454 486 391 423 455 487 398 430 462 494 399 431 463 495 406 ... 511 + // t[16]: 512 544 576 608 513 545 577 609 520 552 584 616 521 553 585 617 528 ... 633 + // ... + // t[31]: 902 934 966 998 903 935 967 999 910 942 974 1006 911 943 975 1007 918 ... 1023 +#ifndef __msvc_cl__ +#pragma unroll(8) +#endif + for (int i = 0; i < 8; ++i) { + r[i * 4] = _mm512_unpacklo_epi32(d[i * 4], d[i * 4 + 2]); + r[i * 4 + 1] = _mm512_unpackhi_epi32(d[i * 4], d[i * 4 + 2]); + r[i * 4 + 2] = _mm512_unpacklo_epi32(d[i * 4 + 1], d[i * 4 + 3]); + r[i * 4 + 3] = _mm512_unpackhi_epi32(d[i * 4 + 1], d[i * 4 + 3]); + } + + // t[0]: 0 32 64 96 128 160 192 224 8 40 72 104 136 168 200 232 16 ... 248 + // t[1]: 1 33 65 97 129 161 193 225 9 41 73 105 137 169 201 233 17 ... 249 + // t[2]: 2 34 66 98 130 162 194 226 10 42 74 106 138 170 202 234 18 ... 250 + // t[3]: 3 35 67 99 131 163 195 227 11 43 75 107 139 171 203 235 19 ... 251 + // t[4]: 4 36 68 100 132 164 196 228 12 44 76 108 140 172 204 236 20 ... 252 + // t[5]: 5 37 69 101 133 165 197 229 13 45 77 109 141 173 205 237 21 ... 253 + // t[6]: 6 38 70 102 134 166 198 230 14 46 78 110 142 174 206 238 22 ... 254 + // t[7]: 7 39 71 103 135 167 199 231 15 47 79 111 143 175 207 239 23 ... 255 + // t[8]: 256 288 320 352 384 416 448 480 264 296 328 360 392 424 456 488 272 ... 504 + // t[9]: 257 289 321 353 385 417 449 481 265 297 329 361 393 425 457 489 273 ... 505 + // t[10]: 258 290 322 354 386 418 450 482 266 298 330 362 394 426 458 490 274 ... 506 + // t[11]: 259 291 323 355 387 419 451 483 267 299 331 363 395 427 459 491 275 ... 507 + // t[12]: 260 292 324 356 388 420 452 484 268 300 332 364 396 428 460 492 276 ... 508 + // t[13]: 261 293 325 357 389 421 453 485 269 301 333 365 397 429 461 493 277 ... 509 + // t[14]: 262 294 326 358 390 422 454 486 270 302 334 366 398 430 462 494 278 ... 510 + // t[15]: 263 295 327 359 391 423 455 487 271 303 335 367 399 431 463 495 279 ... 511 + // t[16]: 512 544 576 608 640 672 704 736 520 552 584 616 648 680 712 744 528 ... 760 + // ... + // t[31]: 775 807 839 871 903 935 967 999 783 815 847 879 911 943 975 1007 791 ... 1023 +#ifndef __msvc_cl__ +#pragma unroll(4) +#endif + for (int i = 0; i < 4; ++i) { + d[i * 8] = _mm512_unpacklo_epi64(r[i * 8], r[i * 8 + 4]); + d[i * 8 + 1] = _mm512_unpackhi_epi64(r[i * 8], r[i * 8 + 4]); + d[i * 8 + 2] = _mm512_unpacklo_epi64(r[i * 8 + 1], r[i * 8 + 5]); + d[i * 8 + 3] = _mm512_unpackhi_epi64(r[i * 8 + 1], r[i * 8 + 5]); + d[i * 8 + 4] = _mm512_unpacklo_epi64(r[i * 8 + 2], r[i * 8 + 6]); + d[i * 8 + 5] = _mm512_unpackhi_epi64(r[i * 8 + 2], r[i * 8 + 6]); + d[i * 8 + 6] = _mm512_unpacklo_epi64(r[i * 8 + 3], r[i * 8 + 7]); + d[i * 8 + 7] = _mm512_unpackhi_epi64(r[i * 8 + 3], r[i * 8 + 7]); + } + + // t[0]: 0 32 64 96 128 160 192 224 256 288 320 352 384 416 448 480 16 ... 496 + // t[1]: 1 33 65 97 129 161 193 225 257 289 321 353 385 417 449 481 17 ... 497 + // t[2]: 2 34 66 98 130 162 194 226 258 290 322 354 386 418 450 482 18 ... 498 + // t[3]: 3 35 67 99 131 163 195 227 259 291 323 355 387 419 451 483 19 ... 499 + // t[4]: 4 36 68 100 132 164 196 228 260 292 324 356 388 420 452 484 20 ... 500 + // t[5]: 5 37 69 101 133 165 197 229 261 293 325 357 389 421 453 485 21 ... 501 + // t[6]: 6 38 70 102 134 166 198 230 262 294 326 358 390 422 454 486 22 ... 502 + // t[7]: 7 39 71 103 135 167 199 231 263 295 327 359 391 423 455 487 23 ... 503 + // t[8]: 8 40 72 104 136 168 200 232 264 296 328 360 392 424 456 488 24 ... 504 + // t[9]: 9 41 73 105 137 169 201 233 265 297 329 361 393 425 457 489 25 ... 505 + // t[10]: 10 42 74 106 138 170 202 234 266 298 330 362 394 426 458 490 26 ... 506 + // t[11]: 11 43 75 107 139 171 203 235 267 299 331 363 395 427 459 491 27 ... 507 + // t[12]: 12 44 76 108 140 172 204 236 268 300 332 364 396 428 460 492 28 ... 508 + // t[13]: 13 45 77 109 141 173 205 237 269 301 333 365 397 429 461 493 29 ... 509 + // t[14]: 14 46 78 110 142 174 206 238 270 302 334 366 398 430 462 494 30 ... 510 + // t[15]: 15 47 79 111 143 175 207 239 271 303 335 367 399 431 463 495 31 ... 511 + // t[16]: 512 544 576 608 640 672 704 736 768 800 832 864 896 928 960 992 528 ... 1008 + // ... + // t[31]: 527 559 591 623 655 687 719 751 783 815 847 879 911 943 975 1007 543 ... 1023 + __m512i const1 = _mm512_set_epi64( + 0x000000000000000d, + 0x000000000000000c, + 0x0000000000000005, + 0x0000000000000004, + 0x0000000000000009, + 0x0000000000000008, + 0x0000000000000001, + 0x0000000000000000); + __m512i const2 = _mm512_set_epi64( + 0x000000000000000f, + 0x000000000000000e, + 0x0000000000000007, + 0x0000000000000006, + 0x000000000000000b, + 0x000000000000000a, + 0x0000000000000003, + 0x0000000000000002); +#ifndef __msvc_cl__ +#pragma unroll(8) +#endif + for (int i = 0; i < 8; ++i) { + r[i] = _mm512_permutex2var_epi64(d[i], /*idx*/const1, d[i + 8]); + r[i + 8] = _mm512_permutex2var_epi64(d[i], /*idx*/const2, d[i + 8]); + r[i + 16] = _mm512_permutex2var_epi64(d[i + 16], /*idx*/const1, d[i + 24]); + r[i + 24] = _mm512_permutex2var_epi64(d[i + 16], /*idx*/const2, d[i + 24]); + } + + // t[0]: 0 32 64 96 128 160 192 224 256 288 320 352 384 416 448 480 512 544 ... 992 + // t[1]: 1 33 65 97 129 161 193 225 257 289 321 353 385 417 449 481 513 545 ... 993 + // t[2]: 2 34 66 98 130 162 194 226 258 290 322 354 386 418 450 482 514 546 ... 994 + // t[3]: 3 35 67 99 131 163 195 227 259 291 323 355 387 419 451 483 515 547 ... 995 + // t[4]: 4 36 68 100 132 164 196 228 260 292 324 356 388 420 452 484 516 548 ... 996 + // t[5]: 5 37 69 101 133 165 197 229 261 293 325 357 389 421 453 485 517 549 ... 997 + // t[6]: 6 38 70 102 134 166 198 230 262 294 326 358 390 422 454 486 518 550 ... 998 + // t[7]: 7 39 71 103 135 167 199 231 263 295 327 359 391 423 455 487 519 551 ... 999 + // t[8]: 8 40 72 104 136 168 200 232 264 296 328 360 392 424 456 488 520 552 ... 1000 + // t[9]: 9 41 73 105 137 169 201 233 265 297 329 361 393 425 457 489 521 553 ... 1001 + // t[10]: 10 42 74 106 138 170 202 234 266 298 330 362 394 426 458 490 522 554 ... 1002 + // t[11]: 11 43 75 107 139 171 203 235 267 299 331 363 395 427 459 491 523 555 ... 1003 + // t[12]: 12 44 76 108 140 172 204 236 268 300 332 364 396 428 460 492 524 556 ... 1004 + // t[13]: 13 45 77 109 141 173 205 237 269 301 333 365 397 429 461 493 525 557 ... 1005 + // t[14]: 14 46 78 110 142 174 206 238 270 302 334 366 398 430 462 494 526 558 ... 1006 + // t[15]: 15 47 79 111 143 175 207 239 271 303 335 367 399 431 463 495 527 559 ... 1007 + // t[16]: 16 48 80 112 144 176 208 240 272 304 336 368 400 432 464 496 528 560 ... 1008 + // ... + // t[31]: 31 63 95 127 159 191 223 255 287 319 351 383 415 447 479 511 543 575 ... 1023 + __m512i const3 = _mm512_set_epi64( + 0x000000000000000b, + 0x000000000000000a, + 0x0000000000000009, + 0x0000000000000008, + 0x0000000000000003, + 0x0000000000000002, + 0x0000000000000001, + 0x0000000000000000); + __m512i const4 = _mm512_set_epi64( + 0x000000000000000f, + 0x000000000000000e, + 0x000000000000000d, + 0x000000000000000c, + 0x0000000000000007, + 0x0000000000000006, + 0x0000000000000005, + 0x0000000000000004); +#ifndef __msvc_cl__ +#pragma unroll(16) +#endif + for (int i = 0; i < 16; ++i) { + d[i] = _mm512_permutex2var_epi64(r[i], /*idx*/const3, r[i + 16]); + d[i + 16] = _mm512_permutex2var_epi64(r[i], /*idx*/const4, r[i + 16]); + } +} + +// Code referred to FBGEMM: +// https://github.com/pytorch/FBGEMM/blob/39a423e4ad1a04b77fea81c7d09c3e6f8984fae9/src/UtilsAvx512.cc#LL19C6-L19C6 +template<> +inline void transpose_mxn(const BFloat16* src, int64_t ld_src, BFloat16* dst, int64_t ld_dst, int M, int N) { + // load from src + TORCH_CHECK(M <= 32 && N <= 32, "transpose_mxn expects M, N <= 32."); + __m512i r[32]; + int i; + if (N == 32) { + for (i = 0; i < M; ++i) { + r[i] = _mm512_loadu_si512(&src[i * ld_src]); + } + } else { + __mmask32 src_mask = (1 << N) - 1; + for (i = 0; i < M; ++i) { + r[i] = _mm512_maskz_loadu_epi16(src_mask, &src[i * ld_src]); + } + } + for (; i < 32; ++i) { + r[i] = _mm512_setzero_si512(); + } + + __m512i d[32]; + _transpose_mxn_half_32_32(r, d); + + // store to dst + if (M == 32) { + for (i = 0; i < N; ++i) { + _mm512_storeu_si512(&dst[i * ld_dst], d[i]); + } + } else { + __mmask32 dst_mask = (1 << M) - 1; + for (i = 0; i < N; ++i) { + _mm512_mask_storeu_epi16(&dst[i * ld_dst], dst_mask, d[i]); + } + } +} + +template && ((M <= 32 && M != 16) || (N <= 32 && N != 16)), int> = 0> +inline void transpose_mxn(const BFloat16* src, int64_t ld_src, BFloat16* dst, int64_t ld_dst) { + transpose_mxn(src, ld_src, dst, ld_dst, M, N); +} + +template<> +inline void transpose_mxn(const Half* src, int64_t ld_src, Half* dst, int64_t ld_dst, int M, int N) { + TORCH_CHECK(M <= 32 && N <= 32, "transpose_mxn expects M, N <= 32."); + // load from src + __m512i r[32]; + int i; + if (N == 32) { + for (i = 0; i < M; ++i) { + r[i] = _mm512_loadu_si512(&src[i * ld_src]); + } + } else { + __mmask32 src_mask = (1 << N) - 1; + for (i = 0; i < M; ++i) { + r[i] = _mm512_maskz_loadu_epi16(src_mask, &src[i * ld_src]); + } + } + for (; i < 32; ++i) { + r[i] = _mm512_setzero_si512(); + } + + __m512i d[32]; + _transpose_mxn_half_32_32(r, d); + + // store to dst + if (M == 32) { + for (i = 0; i < N; ++i) { + _mm512_storeu_si512(&dst[i * ld_dst], d[i]); + } + } else { + __mmask32 dst_mask = (1 << M) - 1; + for (i = 0; i < N; ++i) { + _mm512_mask_storeu_epi16(&dst[i * ld_dst], dst_mask, d[i]); + } + } +} + +template && ((M <= 32 && M != 16) || (N <= 32 && N != 16)), int> = 0> +inline void transpose_mxn(const Half* src, int64_t ld_src, Half* dst, int64_t ld_dst) { + transpose_mxn(src, ld_src, dst, ld_dst, M, N); +} + +template <> +class Vectorized: public Vectorized16 { +public: + using Vectorized16::Vectorized16; + + using value_type = Half; + + Vectorized frac() const; + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m512& x, const __m512& y) { return _mm512_add_ps(x, y); }); +} +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m512& x, const __m512& y) { return _mm512_sub_ps(x, y); }); +} +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m512& x, const __m512& y) { return _mm512_mul_ps(x, y); }); +} +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return binary_op_as_fp32(a, b, [](const __m512& x, const __m512& y) { return _mm512_div_ps(x, y); }); +} + +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return _mm512_and_si512(a, b); +} +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return _mm512_or_si512(a, b); +} +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return _mm512_xor_si512(a, b); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0f); +} + +// frac. Implement this here so we can use subtraction +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + __m512 a_lo, a_hi; + __m512 b_lo, b_hi; + cvtfp16_fp32(__m512i(a), a_lo, a_hi); + cvtfp16_fp32(__m512i(b), b_lo, b_hi); + auto max_lo = _mm512_max_ps(a_lo, b_lo); + auto max_hi = _mm512_max_ps(a_hi, b_hi); + auto nan_lo_mask = _mm512_cmp_ps_mask(a_lo, b_lo, _CMP_UNORD_Q); + auto nan_hi_mask = _mm512_cmp_ps_mask(a_hi, b_hi, _CMP_UNORD_Q); + auto nan_lo = _mm512_castsi512_ps(_mm512_set1_epi32(nan_lo_mask)); + auto nan_hi = _mm512_castsi512_ps(_mm512_set1_epi32(nan_hi_mask)); + // Exploit the fact that all-ones is a NaN. + auto o1 = _mm512_or_ps(max_lo, nan_lo); + auto o2 = _mm512_or_ps(max_hi, nan_hi); + return cvtfp32_fp16(o1, o2); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + __m512 a_lo, a_hi; + __m512 b_lo, b_hi; + __m512i zero_vec = _mm512_set1_epi32(0); + cvtfp16_fp32(__m512i(a), a_lo, a_hi); + cvtfp16_fp32(__m512i(b), b_lo, b_hi); + auto min_lo = _mm512_min_ps(a_lo, b_lo); + auto min_hi = _mm512_min_ps(a_hi, b_hi); + auto nan_lo_mask = _mm512_cmp_ps_mask(a_lo, b_lo, _CMP_UNORD_Q); + auto nan_hi_mask = _mm512_cmp_ps_mask(a_hi, b_hi, _CMP_UNORD_Q); + auto nan_lo = _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, nan_lo_mask, + 0xFFFFFFFF)); + auto nan_hi = _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, nan_hi_mask, + 0xFFFFFFFF)); + // Exploit the fact that all-ones is a NaN. + auto o1 = _mm512_or_ps(min_lo, nan_lo); + auto o2 = _mm512_or_ps(min_hi, nan_hi); + return cvtfp32_fp16(o1, o2); +} + +template <> +Vectorized inline clamp(const Vectorized& a, + const Vectorized& min, const Vectorized& max) { + __m512 a_lo, a_hi; + __m512 min_lo, min_hi; + __m512 max_lo, max_hi; + cvtfp16_fp32(__m512i(a), a_lo, a_hi); + cvtfp16_fp32(__m512i(min), min_lo, min_hi); + cvtfp16_fp32(__m512i(max), max_lo, max_hi); + auto o1 = _mm512_min_ps(max_lo, _mm512_max_ps(min_lo, a_lo)); + auto o2 = _mm512_min_ps(max_hi, _mm512_max_ps(min_hi, a_hi)); + return cvtfp32_fp16(o1, o2); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + __m512 a_lo, a_hi; + __m512 max_lo, max_hi; + cvtfp16_fp32(__m512i(a), a_lo, a_hi); + cvtfp16_fp32(__m512i(max), max_lo, max_hi); + auto o1 = _mm512_min_ps(max_lo, a_lo); + auto o2 = _mm512_min_ps(max_hi, a_hi); + return cvtfp32_fp16(o1, o2); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + __m512 a_lo, a_hi; + __m512 min_lo, min_hi; + cvtfp16_fp32(__m512i(a), a_lo, a_hi); + cvtfp16_fp32(__m512i(min), min_lo, min_hi); + auto o1 = _mm512_max_ps(min_lo, a_lo); + auto o2 = _mm512_max_ps(min_hi, a_hi); + return cvtfp32_fp16(o1, o2); +} + +template <> +inline void convert(const Half* src, Half* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + auto vsrc = _mm512_loadu_si512(reinterpret_cast<__m512i*>((void*)(src + i))); + _mm512_storeu_si512(reinterpret_cast<__m512i*>((void*)(dst + i)), vsrc); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = src[i]; + } +} + +template <> +inline void convert(const float* src, Half* dst, int64_t n) { + int64_t i; + for (i = 0; i + Vectorized::size() <= n; i += Vectorized::size()) { + __m512 a = _mm512_loadu_ps(&src[i]); + __m512 b = _mm512_loadu_ps(&src[i + 16]); + + __m512i bf = cvtfp32_fp16(a, b); + _mm512_storeu_si512(reinterpret_cast<__m512i*>(&dst[i]), bf); + } + for (; i < n; i++) { + dst[i] = c10::convert(src[i]); + } +} + +template <> +inline void convert(const double* src, Half* dst, int64_t n) { + auto load_float = [](const double *src) -> __m512 { + // Load one float vector from an array of doubles + __m256 a = _mm512_cvtpd_ps(_mm512_loadu_pd(src)); + __m256 b = _mm512_cvtpd_ps(_mm512_loadu_pd(src + 8)); + return _mm512_insertf32x8(_mm512_castps256_ps512(a), b, 1); + }; + + int64_t i; + for (i = 0; i + Vectorized::size() <= n; i += Vectorized::size()) { + __m512 a = load_float(&src[i]); + __m512 b = load_float(&src[i + 16]); + + __m512i bf = cvtfp32_fp16(a, b); + _mm512_storeu_si512(reinterpret_cast<__m512i*>(&dst[i]), bf); + } + for (; i < n; i++) { + dst[i] = c10::convert(src[i]); + } +} + +template <> +Vectorized inline fmadd(const Vectorized& a, + const Vectorized& b, const Vectorized& c) { + __m512 a_lo, a_hi; + __m512 b_lo, b_hi; + __m512 c_lo, c_hi; + cvtfp16_fp32(__m512i(a), a_lo, a_hi); + cvtfp16_fp32(__m512i(b), b_lo, b_hi); + cvtfp16_fp32(__m512i(c), c_lo, c_hi); + auto o1 = _mm512_fmadd_ps(a_lo, b_lo, c_lo); + auto o2 = _mm512_fmadd_ps(a_hi, b_hi, c_hi); + return cvtfp32_fp16(o1, o2); +} + +#define CONVERT_VECTORIZED_INIT(type, name) \ +inline std::tuple, Vectorized> convert_##name##_float(const Vectorized& a) { \ + __m512 o1, o2; \ + cvt_to_fp32(__m512i(a), o1, o2); \ + return std::make_tuple(o1, o2); \ +} \ +\ +inline Vectorized convert_float_##name(const Vectorized& a, const Vectorized& b) { \ + return cvt_from_fp32(__m512(a), __m512(b)); \ +} +CONVERT_VECTORIZED_INIT(BFloat16, bfloat16) +CONVERT_VECTORIZED_INIT(Half, half) + +#else //defined(CPU_CAPABILITY_AVX512) + +#define CONVERT_NON_VECTORIZED_INIT(type, name) \ +inline std::tuple, Vectorized> convert_##name##_float(const Vectorized& a) { \ + constexpr int64_t K = Vectorized::size(); \ + __at_align__ float arr[K]; \ + __at_align__ type arr2[K]; \ + a.store(arr2); \ + for (const auto k : c10::irange(K)) { \ + arr[k] = c10::convert(arr2[k]); \ + } \ + return std::make_tuple( \ + Vectorized::loadu(arr), \ + Vectorized::loadu(arr + Vectorized::size())); \ +} \ +\ +inline Vectorized convert_float_##name(const Vectorized& a, const Vectorized& b) { \ + constexpr int64_t K = Vectorized::size(); \ + __at_align__ float arr[K]; \ + __at_align__ type arr2[K]; \ + a.store(arr); \ + b.store(arr + Vectorized::size()); \ + for (const auto k : c10::irange(K)) { \ + arr2[k] = c10::convert(arr[k]); \ + } \ + return Vectorized::loadu(arr2); \ +} +CONVERT_NON_VECTORIZED_INIT(BFloat16, bfloat16) +CONVERT_NON_VECTORIZED_INIT(Half, half) + +#endif // defined(CPU_CAPABILITY_AVX512) + +#if defined(CPU_CAPABILITY_AVX512) +#define LOAD_FP32_VECTORIZED_INIT(type, name) \ +inline void load_fp32_from_##name(const type *data, Vectorized& out) { \ + auto values = _mm256_loadu_si256(reinterpret_cast(data)); \ + __m512 out_values; \ + cvt_to_fp32(values, out_values); \ + out = out_values; \ +} \ +\ +inline void load_fp32_from_##name(const type *data, Vectorized& out1, Vectorized& out2) { \ + auto vec = Vectorized::loadu(data); \ + __m512 out1_values, out2_values; \ + cvt_to_fp32(vec, out1_values, out2_values); \ + out1 = out1_values; \ + out2 = out2_values; \ +} +LOAD_FP32_VECTORIZED_INIT(BFloat16, bf16) +LOAD_FP32_VECTORIZED_INIT(Half, fp16) + +#else // defined(CPU_CAPABILITY_AVX512) +#define LOAD_FP32_NON_VECTORIZED_INIT(type, name) \ +inline void load_fp32_from_##name(const type *data, Vectorized& out) { \ + __at_align__ float values[Vectorized::size()]; \ + for (const auto k : c10::irange(Vectorized::size())) { \ + values[k] = data[k]; \ + } \ + out = Vectorized::loadu(values); \ +} \ +\ +inline void load_fp32_from_##name(const type *data, Vectorized& out1, Vectorized& out2) { \ + load_fp32_from_##name(data, out1); \ + data += Vectorized::size(); \ + load_fp32_from_##name(data, out2); \ +} +LOAD_FP32_NON_VECTORIZED_INIT(BFloat16, bf16) +LOAD_FP32_NON_VECTORIZED_INIT(Half, fp16) + +#endif +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_complex_double.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_complex_double.h new file mode 100644 index 0000000000000000000000000000000000000000..444b41cfb7e5cda51d7d3ee1cbabb6ee1ec869d0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_complex_double.h @@ -0,0 +1,536 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#include +#if defined(CPU_CAPABILITY_AVX512) +#define SLEEF_STATIC_LIBS +#include +#endif + + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX512) + +template <> class Vectorized> { +private: + __m512d values; + static constexpr __m512i zero_vector {0, 0, 0, 0, 0, 0, 0, 0}; +public: + using value_type = c10::complex; + using size_type = int; + static constexpr size_type size() { + return 4; + } + Vectorized() {} + Vectorized(__m512d v) : values(v) {} + Vectorized(c10::complex val) { + double real_value = val.real(); + double imag_value = val.imag(); + values = _mm512_setr_pd(real_value, imag_value, real_value, imag_value, + real_value, imag_value, real_value, imag_value); + } + Vectorized(c10::complex val1, c10::complex val2, + c10::complex val3, c10::complex val4) { + values = _mm512_setr_pd(val1.real(), val1.imag(), + val2.real(), val2.imag(), + val3.real(), val3.imag(), + val4.real(), val4.imag()); + } + operator __m512d() const { + return values; + } + template + static Vectorized> blend(const Vectorized>& a, + const Vectorized>& b) { + // convert c10::complex index mask to V index mask: xy -> xxyy + // NOLINTNEXTLINE(clang-diagnostic-warning) + switch (mask) { + case 0: + return a; + case 1: + return _mm512_mask_blend_pd(0x03, a.values, b.values); //b0000 0001 = b0000 0011 + case 2: + return _mm512_mask_blend_pd(0x0C, a.values, b.values); //b0000 0010 = b0000 1100 + case 3: + return _mm512_mask_blend_pd(0x0F, a.values, b.values); //b0000 0011 = b0000 1111 + case 4: + return _mm512_mask_blend_pd(0x30, a.values, b.values); //b0000 0100 = b0011 0000 + case 5: + return _mm512_mask_blend_pd(0x33, a.values, b.values); //b0000 0101 = b0011 0011 + case 6: + return _mm512_mask_blend_pd(0x3C, a.values, b.values); //b0000 0110 = b0011 1100 + case 7: + return _mm512_mask_blend_pd(0x3F, a.values, b.values); //b0000 0111 = b0011 1111 + case 8: + return _mm512_mask_blend_pd(0xC0, a.values, b.values); //b0000 1000 = b1100 0000 + case 9: + return _mm512_mask_blend_pd(0xC3, a.values, b.values); //b0000 1001 = b1100 0011 + case 10: + return _mm512_mask_blend_pd(0xCC, a.values, b.values); //b0000 1010 = b1100 1100 + case 11: + return _mm512_mask_blend_pd(0xCF, a.values, b.values); //b0000 1011 = b1100 1111 + case 12: + return _mm512_mask_blend_pd(0xF0, a.values, b.values); //b0000 1100 = b1111 0000 + case 13: + return _mm512_mask_blend_pd(0xF3, a.values, b.values); //b0000 1101 = b1111 0011 + case 14: + return _mm512_mask_blend_pd(0xFC, a.values, b.values); //b0000 1110 = b1111 1100 + case 15: + return _mm512_mask_blend_pd(0xFF, a.values, b.values); //b0000 1111 = b1111 1111 + } + return b; + } + static Vectorized> blendv(const Vectorized>& a, + const Vectorized>& b, + const Vectorized>& mask) { + // convert c10::complex index mask to V index mask: xy -> xxyy + auto mask_ = _mm512_unpacklo_pd(mask.values, mask.values); + auto all_ones = _mm512_set1_epi64(0xFFFFFFFFFFFFFFFF); + auto mmask = _mm512_cmp_epi64_mask(_mm512_castpd_si512(mask_), all_ones, _MM_CMPINT_EQ); + return _mm512_mask_blend_pd(mmask, a.values, b.values); + } + template + static Vectorized> arange(c10::complex base = 0., + step_t step = static_cast(1)) { + return Vectorized>(base, + base + c10::complex(1)*step, + base + c10::complex(2)*step, + base + c10::complex(3)*step); + } + static Vectorized> set(const Vectorized>& a, + const Vectorized>& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + } + return b; + } + static Vectorized> loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return _mm512_loadu_pd(reinterpret_cast(ptr)); + + __at_align__ double tmp_values[2*size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(2*size())) { + tmp_values[i] = 0.0; + } + std::memcpy( + tmp_values, + reinterpret_cast(ptr), + count * sizeof(c10::complex)); + return _mm512_load_pd(tmp_values); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + _mm512_storeu_pd(reinterpret_cast(ptr), values); + } else if (count > 0) { + double tmp_values[2*size()]; + _mm512_storeu_pd(reinterpret_cast(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(c10::complex)); + } + } + const c10::complex& operator[](int idx) const = delete; + c10::complex& operator[](int idx) = delete; + Vectorized> map(c10::complex (*const f)(const c10::complex &)) const { + __at_align__ c10::complex tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + // AVX512 doesn't have horizontal add & horizontal sub instructions. + // TODO: hadd_pd() & hsub_pd() may have scope for improvement. + static inline __m512d hadd_pd(__m512d a, __m512d b) { + __m512i idx1 = _mm512_set_epi64(14, 6, 12, 4, 10, 2, 8, 0); + __m512i idx2 = _mm512_set_epi64(15, 7, 13, 5, 11, 3, 9, 1); + return _mm512_add_pd(_mm512_mask_permutex2var_pd(a, 0xff, idx1, b), + _mm512_mask_permutex2var_pd(a, 0xff, idx2, b)); + } + static inline __m512d hsub_pd(__m512d a, __m512d b) { + __m512i idx1 = _mm512_set_epi64(14, 6, 12, 4, 10, 2, 8, 0); + __m512i idx2 = _mm512_set_epi64(15, 7, 13, 5, 11, 3, 9, 1); + return _mm512_sub_pd(_mm512_mask_permutex2var_pd(a, 0xff, idx1, b), + _mm512_mask_permutex2var_pd(a, 0xff, idx2, b)); + } + __m512d abs_2_() const { + auto val_2 = _mm512_mul_pd(values, values); // a*a b*b + return hadd_pd(val_2, val_2); // a*a+b*b a*a+b*b + } + __m512d abs_() const { + auto real = _mm512_movedup_pd(values); // real real + // movehdup_pd does not exist... + auto imag = _mm512_permute_pd(values, 0xff); // imag imag + return Sleef_hypotd8_u05(real, imag); // abs abs + } + Vectorized> abs() const { + const __m512d real_mask = _mm512_castsi512_pd(_mm512_setr_epi64(0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000)); + return _mm512_and_pd(abs_(), real_mask); // abs 0 + } + __m512d angle_() const { + //angle = atan2(b/a) + auto b_a = _mm512_permute_pd(values, 0x55); // b a + return Sleef_atan2d8_u10(values, b_a); // 90-angle angle + } + Vectorized> angle() const { + const __m512d real_mask = _mm512_castsi512_pd(_mm512_setr_epi64(0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000)); + auto angle = _mm512_permute_pd(angle_(), 0x55); // angle 90-angle + return _mm512_and_pd(angle, real_mask); // angle 0 + } + Vectorized> sgn() const { + auto abs = abs_(); + auto zero = _mm512_setzero_pd(); + auto mask = _mm512_cmp_pd_mask(abs, zero, _CMP_EQ_OQ); + auto div = _mm512_div_pd(values, abs); + return _mm512_mask_blend_pd(mask, div, zero); + } + __m512d real_() const { + const __m512d real_mask = _mm512_castsi512_pd(_mm512_setr_epi64(0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000, + 0xFFFFFFFFFFFFFFFF, 0x0000000000000000)); + return _mm512_and_pd(values, real_mask); + } + Vectorized> real() const { + return real_(); + } + __m512d imag_() const { + const __m512d imag_mask = _mm512_castsi512_pd(_mm512_setr_epi64(0x0000000000000000, 0xFFFFFFFFFFFFFFFF, + 0x0000000000000000, 0xFFFFFFFFFFFFFFFF, + 0x0000000000000000, 0xFFFFFFFFFFFFFFFF, + 0x0000000000000000, 0xFFFFFFFFFFFFFFFF)); + return _mm512_and_pd(values, imag_mask); + } + Vectorized> imag() const { + return _mm512_permute_pd(imag_(), 0x55); //b a + } + __m512d conj_() const { + const __m512d sign_mask = _mm512_setr_pd(0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0); + return _mm512_xor_pd(values, sign_mask); // a -b + } + Vectorized> conj() const { + return conj_(); + } + Vectorized> log() const { + // Most trigonomic ops use the log() op to improve complex number performance. + return map(std::log); + } + Vectorized> log2() const { + const __m512d log2_ = _mm512_set1_pd(std::log(2)); + return _mm512_div_pd(log(), log2_); + } + Vectorized> log10() const { + const __m512d log10_ = _mm512_set1_pd(std::log(10)); + return _mm512_div_pd(log(), log10_); + } + Vectorized> log1p() const { + return map(std::log1p); + } + Vectorized> asin() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // // asin(x) + // // = -i*ln(iz + sqrt(1 -z^2)) + // // = -i*ln((ai - b) + sqrt(1 - (a + bi)*(a + bi))) + // // = -i*ln((-b + ai) + sqrt(1 - (a**2 - b**2) - 2*abi)) + // const __m512d one = _mm512_set1_pd(1); + + // auto conj = conj_(); + // auto b_a = _mm512_permute_pd(conj, 0x55); //-b a + // auto ab = _mm512_mul_pd(conj, b_a); //-ab -ab + // auto im = _mm512_add_pd(ab, ab); //-2ab -2ab + + // auto val_2 = _mm512_mul_pd(values, values); // a*a b*b + // auto re = hsub_pd(val_2, _mm512_permute_pd(val_2, 0x55)); // a*a-b*b b*b-a*a + // re = _mm512_sub_pd(one, re); + + // auto root = Vectorized(_mm512_mask_blend_pd(0xAA, re, im)).sqrt(); //sqrt(re + i*im) + // auto ln = Vectorized(_mm512_add_pd(b_a, root)).log(); //ln(iz + sqrt()) + // return Vectorized(_mm512_permute_pd(ln.values, 0x55)).conj(); //-i*ln() + return map(std::asin); + } + Vectorized> acos() const { + // acos(x) = pi/2 - asin(x) + constexpr auto pi_2d = c10::pi / 2; + const __m512d pi_2 = _mm512_setr_pd(pi_2d, 0.0, pi_2d, 0.0, pi_2d, 0.0, pi_2d, 0.0); + return _mm512_sub_pd(pi_2, asin()); + } + Vectorized> atan() const; + Vectorized> atanh() const { + return map(std::atanh); + } + Vectorized> exp() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //exp(a + bi) + // // = exp(a)*(cos(b) + sin(b)i) + // auto exp = Sleef_expd8_u10(values); //exp(a) exp(b) + // exp = _mm512_mask_blend_pd(0xAA, exp, _mm512_permute_pd(exp, 0x55)); //exp(a) exp(a) + + // auto sin_cos = Sleef_sincosd8_u10(values); //[sin(a), cos(a)] [sin(b), cos(b)] + // auto cos_sin = _mm512_mask_blend_pd(0xAA, _mm512_permute_pd(sin_cos.y, 0x55), + // sin_cos.x); //cos(b) sin(b) + // return _mm512_mul_pd(exp, cos_sin); + return map(std::exp); + } + Vectorized> exp2() const { + // Use identity 2**x = exp(log(2) * x) + const __m512d ln_2 = _mm512_set1_pd(c10::ln_2); + Vectorized> scaled_values = _mm512_mul_pd(values, ln_2); + return scaled_values.exp(); + } + Vectorized> expm1() const { + return map(std::expm1); + } + Vectorized> sin() const { + return map(std::sin); + } + Vectorized> sinh() const { + return map(std::sinh); + } + Vectorized> cos() const { + return map(std::cos); + } + Vectorized> cosh() const { + return map(std::cosh); + } + Vectorized> ceil() const { + return _mm512_ceil_pd(values); + } + Vectorized> floor() const { + return _mm512_floor_pd(values); + } + Vectorized> neg() const { + auto zero = _mm512_setzero_pd(); + return _mm512_sub_pd(zero, values); + } + Vectorized> round() const { + return _mm512_roundscale_pd(values, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + } + Vectorized> tan() const { + return map(std::tan); + } + Vectorized> tanh() const { + return map(std::tanh); + } + Vectorized> trunc() const { + return _mm512_roundscale_pd(values, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + } + Vectorized> sqrt() const { + return map(std::sqrt); + } + Vectorized> reciprocal() const; + Vectorized> rsqrt() const { + return sqrt().reciprocal(); + } + Vectorized> pow(const Vectorized> &exp) const { + __at_align__ c10::complex x_tmp[size()]; + __at_align__ c10::complex y_tmp[size()]; + store(x_tmp); + exp.store(y_tmp); + for (const auto i : c10::irange(size())) { + x_tmp[i] = std::pow(x_tmp[i], y_tmp[i]); + } + return loadu(x_tmp); + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized> operator==(const Vectorized>& other) const { + auto mask = _mm512_cmp_pd_mask(values, other.values, _CMP_EQ_OQ); + return _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vector, mask, + 0xFFFFFFFFFFFFFFFF)); + } + Vectorized> operator!=(const Vectorized>& other) const { + auto mask = _mm512_cmp_pd_mask(values, other.values, _CMP_NEQ_UQ); + return _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vector, mask, + 0xFFFFFFFFFFFFFFFF)); + } + Vectorized> operator<(const Vectorized>& other [[maybe_unused]]) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator<=(const Vectorized>& other [[maybe_unused]]) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator>(const Vectorized>& other [[maybe_unused]]) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator>=(const Vectorized>& other [[maybe_unused]]) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized> eq(const Vectorized>& other) const; + Vectorized> ne(const Vectorized>& other) const; +}; + +template <> Vectorized> inline operator+(const Vectorized> &a, + const Vectorized> &b) { + return _mm512_add_pd(a, b); +} + +template <> Vectorized> inline operator-(const Vectorized> &a, + const Vectorized> &b) { + return _mm512_sub_pd(a, b); +} + +template <> Vectorized> inline operator*(const Vectorized> &a, + const Vectorized> &b) { + //(a + bi) * (c + di) = (ac - bd) + (ad + bc)i + const __m512d sign_mask = _mm512_setr_pd(0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0); + auto ac_bd = _mm512_mul_pd(a, b); //ac bd + + auto d_c = _mm512_permute_pd(b, 0x55); //d c + d_c = _mm512_xor_pd(sign_mask, d_c); //d -c + auto ad_bc = _mm512_mul_pd(a, d_c); //ad -bc + + auto ret = Vectorized>::hsub_pd(ac_bd, ad_bc); //ac - bd ad + bc + return ret; +} + +template <> Vectorized> inline operator/(const Vectorized> &a, + const Vectorized> &b) { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //re + im*i = (a + bi) / (c + di) + // auto mask = _mm512_set1_pd(-0.f); + // auto fabs_cd = _mm512_andnot_pd(mask, b); // |c| |d| + // auto fabs_dc = _mm512_permute_pd(fabs_cd, 0x55); // |d| |c| + // auto scale = _mm512_rcp14_pd(_mm512_max_pd(fabs_cd, fabs_dc)); // 1/sc 1/sc + // auto a2 = _mm512_mul_pd(a, scale); // a/sc b/sc + // auto b2 = _mm512_mul_pd(b, scale); // c/sc d/sc + // auto acbd2 = _mm512_mul_pd(a2, b2); + + // const __m512d sign_mask = _mm512_setr_pd(-0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0); + // auto dc2 = _mm512_permute_pd(b2, 0x55); // d/sc c/sc + // dc2 = _mm512_xor_pd(sign_mask, dc2); // -d/|c,d| c/sc + // auto adbc2 = _mm512_mul_pd(a2, dc2); //-ad/sc^2 bc/sc^2 + // auto res2 = Vectorized>::hadd_pd(acbd2, adbc2); //(ac+bd)/sc^2 (bc-ad)/sc^2 + + // // get the denominator + // auto denom2 = Vectorized>(b2).abs_2_(); // (c^2+d^2)/sc^2 (c^2+d^2)/sc^2 + // res2 = _mm512_div_pd(res2, denom2); + // return res2; + __at_align__ c10::complex tmp1[Vectorized>::size()]; + __at_align__ c10::complex tmp2[Vectorized>::size()]; + __at_align__ c10::complex out[Vectorized>::size()]; + a.store(tmp1); + b.store(tmp2); + for (const auto i : c10::irange(Vectorized>::size())) { + out[i] = tmp1[i] / tmp2[i]; + } + return _mm512_loadu_pd(reinterpret_cast(out)); +} + +// reciprocal. Implement this here so we can use multiplication. +inline Vectorized> Vectorized>::reciprocal() const{ + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //re + im*i = (a + bi) / (c + di) + // //re = (ac + bd)/abs_2() = c/abs_2() + // //im = (bc - ad)/abs_2() = d/abs_2() + // const __m512d sign_mask = _mm512_setr_pd(0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0); + // auto c_d = _mm512_xor_pd(sign_mask, values); //c -d + // return _mm512_div_pd(c_d, abs_2_()); + __at_align__ c10::complex tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = c10::complex(1) / tmp[i]; + } + return loadu(tmp); +} + +inline Vectorized> Vectorized>::atan() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // // atan(x) = i/2 * ln((i + z)/(i - z)) + // const __m512d i = _mm512_setr_pd(0.0, 1.0, 0.0, 1.0, 0.0, 1.0, 0.0, 1.0); + // const Vectorized i_half = _mm512_setr_pd(0.0, 0.5, 0.0, 0.5, 0.0, 0.5, 0.0, 0.5); + + // auto sum = Vectorized(_mm512_add_pd(i, values)); // a 1+b + // auto sub = Vectorized(_mm512_sub_pd(i, values)); // -a 1-b + // auto ln = (sum/sub).log(); // ln((i + z)/(i - z)) + // return i_half*ln; // i/2*ln() + return map(std::atan); +} + +template <> +Vectorized> inline maximum(const Vectorized>& a, + const Vectorized>& b) { + auto zero_vec = _mm512_set1_epi64(0); + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + auto mask = _mm512_cmp_pd_mask(abs_a, abs_b, _CMP_LT_OQ); + auto max = _mm512_mask_blend_pd(mask, a, b); + // Exploit the fact that all-ones is a NaN. + auto isnan_mask = _mm512_cmp_pd_mask(abs_a, abs_b, _CMP_UNORD_Q); + auto isnan = _mm512_mask_set1_epi64(zero_vec, isnan_mask, + 0xFFFFFFFFFFFFFFFF); + return _mm512_or_pd(max, _mm512_castsi512_pd(isnan)); +} + +template <> +Vectorized> inline minimum(const Vectorized>& a, + const Vectorized>& b) { + auto zero_vec = _mm512_set1_epi64(0); + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + auto mask = _mm512_cmp_pd_mask(abs_a, abs_b, _CMP_GT_OQ); + auto min = _mm512_mask_blend_pd(mask, a, b); + // Exploit the fact that all-ones is a NaN. + auto isnan_mask = _mm512_cmp_pd_mask(abs_a, abs_b, _CMP_UNORD_Q); + auto isnan = _mm512_mask_set1_epi64(zero_vec, isnan_mask, + 0xFFFFFFFFFFFFFFFF); + return _mm512_or_pd(min, _mm512_castsi512_pd(isnan)); +} + +template <> +Vectorized> inline operator&(const Vectorized>& a, + const Vectorized>& b) { + return _mm512_and_pd(a, b); +} + +template <> +Vectorized> inline operator|(const Vectorized>& a, + const Vectorized>& b) { + return _mm512_or_pd(a, b); +} + +template <> +Vectorized> inline operator^(const Vectorized>& a, + const Vectorized>& b) { + return _mm512_xor_pd(a, b); +} + +inline Vectorized> Vectorized>::eq(const Vectorized>& other) const { + auto eq = (*this == other); // compares real and imag individually + // If both real numbers and imag numbers are equal, then the complex numbers are equal + return (eq.real() & eq.imag()) & Vectorized>(_mm512_set1_pd(1.0)); +} + +inline Vectorized> Vectorized>::ne(const Vectorized>& other) const { + auto ne = (*this != other); // compares real and imag individually + // If either real numbers or imag numbers are not equal, then the complex numbers are not equal + return (ne.real() | ne.imag()) & Vectorized>(_mm512_set1_pd(1.0)); +} + +#endif + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_complex_float.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_complex_float.h new file mode 100644 index 0000000000000000000000000000000000000000..4b07fb3af8638eabcb3617242d7cf9d373c41157 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_complex_float.h @@ -0,0 +1,1042 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#include +#if defined(CPU_CAPABILITY_AVX512) +#define SLEEF_STATIC_LIBS +#include +#endif + + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX512) + +template <> class Vectorized> { +private: + __m512 values; + static constexpr __m512i zero_vector {0, 0, 0, 0, 0, 0, 0, 0}; +public: + using value_type = c10::complex; + using size_type = int; + static constexpr size_type size() { + return 8; + } + Vectorized() {} + Vectorized(__m512 v) : values(v) {} + Vectorized(c10::complex val) { + float real_value = val.real(); + float imag_value = val.imag(); + values = _mm512_setr_ps(real_value, imag_value, + real_value, imag_value, + real_value, imag_value, + real_value, imag_value, + real_value, imag_value, + real_value, imag_value, + real_value, imag_value, + real_value, imag_value); + } + Vectorized(c10::complex val1, c10::complex val2, + c10::complex val3, c10::complex val4, + c10::complex val5, c10::complex val6, + c10::complex val7, c10::complex val8) { + values = _mm512_setr_ps(val1.real(), val1.imag(), + val2.real(), val2.imag(), + val3.real(), val3.imag(), + val4.real(), val4.imag(), + val5.real(), val5.imag(), + val6.real(), val6.imag(), + val7.real(), val7.imag(), + val8.real(), val8.imag()); + } + operator __m512() const { + return values; + } + template + static Vectorized> blend(const Vectorized>& a, + const Vectorized>& b) { + // convert c10::complex index mask to V index mask: xy -> xxyy + static_assert(mask > -1 && mask < 256, "Unexpected mask value"); + // The compiler would hopefully convert this switch condition + // into a jump table + switch (mask) { + case 0: + return a; + case 1: + return _mm512_mask_blend_ps(0x03, a.values, b.values); + case 2: + return _mm512_mask_blend_ps(0x0C, a.values, b.values); + case 3: + return _mm512_mask_blend_ps(0x0F, a.values, b.values); + case 4: + return _mm512_mask_blend_ps(0x30, a.values, b.values); + case 5: + return _mm512_mask_blend_ps(0x33, a.values, b.values); + case 6: + return _mm512_mask_blend_ps(0x3C, a.values, b.values); + case 7: + return _mm512_mask_blend_ps(0x3F, a.values, b.values); + case 8: + return _mm512_mask_blend_ps(0xC0, a.values, b.values); + case 9: + return _mm512_mask_blend_ps(0xC3, a.values, b.values); + case 10: + return _mm512_mask_blend_ps(0xCC, a.values, b.values); + case 11: + return _mm512_mask_blend_ps(0xCF, a.values, b.values); + case 12: + return _mm512_mask_blend_ps(0xF0, a.values, b.values); + case 13: + return _mm512_mask_blend_ps(0xF3, a.values, b.values); + case 14: + return _mm512_mask_blend_ps(0xFC, a.values, b.values); + case 15: + return _mm512_mask_blend_ps(0xFF, a.values, b.values); + case 16: + return _mm512_mask_blend_ps(0x300, a.values, b.values); + case 17: + return _mm512_mask_blend_ps(0x303, a.values, b.values); + case 18: + return _mm512_mask_blend_ps(0x30C, a.values, b.values); + case 19: + return _mm512_mask_blend_ps(0x30F, a.values, b.values); + case 20: + return _mm512_mask_blend_ps(0x330, a.values, b.values); + case 21: + return _mm512_mask_blend_ps(0x333, a.values, b.values); + case 22: + return _mm512_mask_blend_ps(0x33C, a.values, b.values); + case 23: + return _mm512_mask_blend_ps(0x33F, a.values, b.values); + case 24: + return _mm512_mask_blend_ps(0x3C0, a.values, b.values); + case 25: + return _mm512_mask_blend_ps(0x3C3, a.values, b.values); + case 26: + return _mm512_mask_blend_ps(0x3CC, a.values, b.values); + case 27: + return _mm512_mask_blend_ps(0x3CF, a.values, b.values); + case 28: + return _mm512_mask_blend_ps(0x3F0, a.values, b.values); + case 29: + return _mm512_mask_blend_ps(0x3F3, a.values, b.values); + case 30: + return _mm512_mask_blend_ps(0x3FC, a.values, b.values); + case 31: + return _mm512_mask_blend_ps(0x3FF, a.values, b.values); + case 32: + return _mm512_mask_blend_ps(0xC00, a.values, b.values); + case 33: + return _mm512_mask_blend_ps(0xC03, a.values, b.values); + case 34: + return _mm512_mask_blend_ps(0xC0C, a.values, b.values); + case 35: + return _mm512_mask_blend_ps(0xC0F, a.values, b.values); + case 36: + return _mm512_mask_blend_ps(0xC30, a.values, b.values); + case 37: + return _mm512_mask_blend_ps(0xC33, a.values, b.values); + case 38: + return _mm512_mask_blend_ps(0xC3C, a.values, b.values); + case 39: + return _mm512_mask_blend_ps(0xC3F, a.values, b.values); + case 40: + return _mm512_mask_blend_ps(0xCC0, a.values, b.values); + case 41: + return _mm512_mask_blend_ps(0xCC3, a.values, b.values); + case 42: + return _mm512_mask_blend_ps(0xCCC, a.values, b.values); + case 43: + return _mm512_mask_blend_ps(0xCCF, a.values, b.values); + case 44: + return _mm512_mask_blend_ps(0xCF0, a.values, b.values); + case 45: + return _mm512_mask_blend_ps(0xCF3, a.values, b.values); + case 46: + return _mm512_mask_blend_ps(0xCFC, a.values, b.values); + case 47: + return _mm512_mask_blend_ps(0xCFF, a.values, b.values); + case 48: + return _mm512_mask_blend_ps(0xF00, a.values, b.values); + case 49: + return _mm512_mask_blend_ps(0xF03, a.values, b.values); + case 50: + return _mm512_mask_blend_ps(0xF0C, a.values, b.values); + case 51: + return _mm512_mask_blend_ps(0xF0F, a.values, b.values); + case 52: + return _mm512_mask_blend_ps(0xF30, a.values, b.values); + case 53: + return _mm512_mask_blend_ps(0xF33, a.values, b.values); + case 54: + return _mm512_mask_blend_ps(0xF3C, a.values, b.values); + case 55: + return _mm512_mask_blend_ps(0xF3F, a.values, b.values); + case 56: + return _mm512_mask_blend_ps(0xFC0, a.values, b.values); + case 57: + return _mm512_mask_blend_ps(0xFC3, a.values, b.values); + case 58: + return _mm512_mask_blend_ps(0xFCC, a.values, b.values); + case 59: + return _mm512_mask_blend_ps(0xFCF, a.values, b.values); + case 60: + return _mm512_mask_blend_ps(0xFF0, a.values, b.values); + case 61: + return _mm512_mask_blend_ps(0xFF3, a.values, b.values); + case 62: + return _mm512_mask_blend_ps(0xFFC, a.values, b.values); + case 63: + return _mm512_mask_blend_ps(0xFFF, a.values, b.values); + case 64: + return _mm512_mask_blend_ps(0x3000, a.values, b.values); + case 65: + return _mm512_mask_blend_ps(0x3003, a.values, b.values); + case 66: + return _mm512_mask_blend_ps(0x300C, a.values, b.values); + case 67: + return _mm512_mask_blend_ps(0x300F, a.values, b.values); + case 68: + return _mm512_mask_blend_ps(0x3030, a.values, b.values); + case 69: + return _mm512_mask_blend_ps(0x3033, a.values, b.values); + case 70: + return _mm512_mask_blend_ps(0x303C, a.values, b.values); + case 71: + return _mm512_mask_blend_ps(0x303F, a.values, b.values); + case 72: + return _mm512_mask_blend_ps(0x30C0, a.values, b.values); + case 73: + return _mm512_mask_blend_ps(0X30C3, a.values, b.values); + case 74: + return _mm512_mask_blend_ps(0x30CC, a.values, b.values); + case 75: + return _mm512_mask_blend_ps(0x30CF, a.values, b.values); + case 76: + return _mm512_mask_blend_ps(0x30F0, a.values, b.values); + case 77: + return _mm512_mask_blend_ps(0x30F3, a.values, b.values); + case 78: + return _mm512_mask_blend_ps(0x30FC, a.values, b.values); + case 79: + return _mm512_mask_blend_ps(0x30FF, a.values, b.values); + case 80: + return _mm512_mask_blend_ps(0x3300, a.values, b.values); + case 81: + return _mm512_mask_blend_ps(0X3303, a.values, b.values); + case 82: + return _mm512_mask_blend_ps(0x330C, a.values, b.values); + case 83: + return _mm512_mask_blend_ps(0x330F, a.values, b.values); + case 84: + return _mm512_mask_blend_ps(0x3330, a.values, b.values); + case 85: + return _mm512_mask_blend_ps(0x3333, a.values, b.values); + case 86: + return _mm512_mask_blend_ps(0x333C, a.values, b.values); + case 87: + return _mm512_mask_blend_ps(0X333F, a.values, b.values); + case 88: + return _mm512_mask_blend_ps(0x33C0, a.values, b.values); + case 89: + return _mm512_mask_blend_ps(0x33C3, a.values, b.values); + case 90: + return _mm512_mask_blend_ps(0x33CC, a.values, b.values); + case 91: + return _mm512_mask_blend_ps(0x33CF, a.values, b.values); + case 92: + return _mm512_mask_blend_ps(0x33F0, a.values, b.values); + case 93: + return _mm512_mask_blend_ps(0x33F3, a.values, b.values); + case 94: + return _mm512_mask_blend_ps(0x33FC, a.values, b.values); + case 95: + return _mm512_mask_blend_ps(0x33FF, a.values, b.values); + case 96: + return _mm512_mask_blend_ps(0X3C00, a.values, b.values); + case 97: + return _mm512_mask_blend_ps(0x3C03, a.values, b.values); + case 98: + return _mm512_mask_blend_ps(0x3C0C, a.values, b.values); + case 99: + return _mm512_mask_blend_ps(0x3C0F, a.values, b.values); + case 100: + return _mm512_mask_blend_ps(0x3C30, a.values, b.values); + case 101: + return _mm512_mask_blend_ps(0x3C33, a.values, b.values); + case 102: + return _mm512_mask_blend_ps(0x3C3C, a.values, b.values); + case 103: + return _mm512_mask_blend_ps(0x3C3F, a.values, b.values); + case 104: + return _mm512_mask_blend_ps(0x3CC0, a.values, b.values); + case 105: + return _mm512_mask_blend_ps(0x3CC3, a.values, b.values); + case 106: + return _mm512_mask_blend_ps(0x3CCC, a.values, b.values); + case 107: + return _mm512_mask_blend_ps(0x3CCF, a.values, b.values); + case 108: + return _mm512_mask_blend_ps(0x3CF0, a.values, b.values); + case 109: + return _mm512_mask_blend_ps(0x3CF3, a.values, b.values); + case 110: + return _mm512_mask_blend_ps(0x3CFC, a.values, b.values); + case 111: + return _mm512_mask_blend_ps(0x3CFF, a.values, b.values); + case 112: + return _mm512_mask_blend_ps(0x3F00, a.values, b.values); + case 113: + return _mm512_mask_blend_ps(0x3F03, a.values, b.values); + case 114: + return _mm512_mask_blend_ps(0x3F0C, a.values, b.values); + case 115: + return _mm512_mask_blend_ps(0x3F0F, a.values, b.values); + case 116: + return _mm512_mask_blend_ps(0x3F30, a.values, b.values); + case 117: + return _mm512_mask_blend_ps(0x3F33, a.values, b.values); + case 118: + return _mm512_mask_blend_ps(0x3F3C, a.values, b.values); + case 119: + return _mm512_mask_blend_ps(0x3F3F, a.values, b.values); + case 120: + return _mm512_mask_blend_ps(0x3FC0, a.values, b.values); + case 121: + return _mm512_mask_blend_ps(0x3FC3, a.values, b.values); + case 122: + return _mm512_mask_blend_ps(0x3FCC, a.values, b.values); + case 123: + return _mm512_mask_blend_ps(0x3FCF, a.values, b.values); + case 124: + return _mm512_mask_blend_ps(0x3FF0, a.values, b.values); + case 125: + return _mm512_mask_blend_ps(0x3FF3, a.values, b.values); + case 126: + return _mm512_mask_blend_ps(0x3FFC, a.values, b.values); + case 127: + return _mm512_mask_blend_ps(0x3FFF, a.values, b.values); + case 128: + return _mm512_mask_blend_ps(0xC000, a.values, b.values); + case 129: + return _mm512_mask_blend_ps(0xC003, a.values, b.values); + case 130: + return _mm512_mask_blend_ps(0xC00C, a.values, b.values); + case 131: + return _mm512_mask_blend_ps(0xC00F, a.values, b.values); + case 132: + return _mm512_mask_blend_ps(0xC030, a.values, b.values); + case 133: + return _mm512_mask_blend_ps(0xC033, a.values, b.values); + case 134: + return _mm512_mask_blend_ps(0xC03C, a.values, b.values); + case 135: + return _mm512_mask_blend_ps(0xC03F, a.values, b.values); + case 136: + return _mm512_mask_blend_ps(0xC0C0, a.values, b.values); + case 137: + return _mm512_mask_blend_ps(0xC0C3, a.values, b.values); + case 138: + return _mm512_mask_blend_ps(0xC0CC, a.values, b.values); + case 139: + return _mm512_mask_blend_ps(0xC0CF, a.values, b.values); + case 140: + return _mm512_mask_blend_ps(0xC0F0, a.values, b.values); + case 141: + return _mm512_mask_blend_ps(0xC0F3, a.values, b.values); + case 142: + return _mm512_mask_blend_ps(0xC0FC, a.values, b.values); + case 143: + return _mm512_mask_blend_ps(0xC0FF, a.values, b.values); + case 144: + return _mm512_mask_blend_ps(0xC300, a.values, b.values); + case 145: + return _mm512_mask_blend_ps(0xC303, a.values, b.values); + case 146: + return _mm512_mask_blend_ps(0xC30C, a.values, b.values); + case 147: + return _mm512_mask_blend_ps(0xC30F, a.values, b.values); + case 148: + return _mm512_mask_blend_ps(0xC330, a.values, b.values); + case 149: + return _mm512_mask_blend_ps(0xC333, a.values, b.values); + case 150: + return _mm512_mask_blend_ps(0xC33C, a.values, b.values); + case 151: + return _mm512_mask_blend_ps(0xC33F, a.values, b.values); + case 152: + return _mm512_mask_blend_ps(0xC3C0, a.values, b.values); + case 153: + return _mm512_mask_blend_ps(0xC3C3, a.values, b.values); + case 154: + return _mm512_mask_blend_ps(0xC3CC, a.values, b.values); + case 155: + return _mm512_mask_blend_ps(0xC3CF, a.values, b.values); + case 156: + return _mm512_mask_blend_ps(0xC3F0, a.values, b.values); + case 157: + return _mm512_mask_blend_ps(0xC3F3, a.values, b.values); + case 158: + return _mm512_mask_blend_ps(0xC3FC, a.values, b.values); + case 159: + return _mm512_mask_blend_ps(0xC3FF, a.values, b.values); + case 160: + return _mm512_mask_blend_ps(0xCC00, a.values, b.values); + case 161: + return _mm512_mask_blend_ps(0xCC03, a.values, b.values); + case 162: + return _mm512_mask_blend_ps(0xCC0C, a.values, b.values); + case 163: + return _mm512_mask_blend_ps(0xCC0F, a.values, b.values); + case 164: + return _mm512_mask_blend_ps(0xCC30, a.values, b.values); + case 165: + return _mm512_mask_blend_ps(0xCC33, a.values, b.values); + case 166: + return _mm512_mask_blend_ps(0xCC3C, a.values, b.values); + case 167: + return _mm512_mask_blend_ps(0xCC3F, a.values, b.values); + case 168: + return _mm512_mask_blend_ps(0xCCC0, a.values, b.values); + case 169: + return _mm512_mask_blend_ps(0xCCC3, a.values, b.values); + case 170: + return _mm512_mask_blend_ps(0xCCCC, a.values, b.values); + case 171: + return _mm512_mask_blend_ps(0xCCCF, a.values, b.values); + case 172: + return _mm512_mask_blend_ps(0xCCF0, a.values, b.values); + case 173: + return _mm512_mask_blend_ps(0xCCF3, a.values, b.values); + case 174: + return _mm512_mask_blend_ps(0xCCFC, a.values, b.values); + case 175: + return _mm512_mask_blend_ps(0xCCFF, a.values, b.values); + case 176: + return _mm512_mask_blend_ps(0xCF00, a.values, b.values); + case 177: + return _mm512_mask_blend_ps(0xCF03, a.values, b.values); + case 178: + return _mm512_mask_blend_ps(0xCF0C, a.values, b.values); + case 179: + return _mm512_mask_blend_ps(0xCF0F, a.values, b.values); + case 180: + return _mm512_mask_blend_ps(0xCF30, a.values, b.values); + case 181: + return _mm512_mask_blend_ps(0xCF33, a.values, b.values); + case 182: + return _mm512_mask_blend_ps(0xCF3C, a.values, b.values); + case 183: + return _mm512_mask_blend_ps(0xCF3F, a.values, b.values); + case 184: + return _mm512_mask_blend_ps(0xCFC0, a.values, b.values); + case 185: + return _mm512_mask_blend_ps(0xCFC3, a.values, b.values); + case 186: + return _mm512_mask_blend_ps(0xCFCC, a.values, b.values); + case 187: + return _mm512_mask_blend_ps(0xCFCF, a.values, b.values); + case 188: + return _mm512_mask_blend_ps(0xCFF0, a.values, b.values); + case 189: + return _mm512_mask_blend_ps(0xCFF3, a.values, b.values); + case 190: + return _mm512_mask_blend_ps(0xCFFC, a.values, b.values); + case 191: + return _mm512_mask_blend_ps(0xCFFF, a.values, b.values); + case 192: + return _mm512_mask_blend_ps(0xF000, a.values, b.values); + case 193: + return _mm512_mask_blend_ps(0xF003, a.values, b.values); + case 194: + return _mm512_mask_blend_ps(0xF00C, a.values, b.values); + case 195: + return _mm512_mask_blend_ps(0xF00F, a.values, b.values); + case 196: + return _mm512_mask_blend_ps(0xF030, a.values, b.values); + case 197: + return _mm512_mask_blend_ps(0xF033, a.values, b.values); + case 198: + return _mm512_mask_blend_ps(0xF03C, a.values, b.values); + case 199: + return _mm512_mask_blend_ps(0xF03F, a.values, b.values); + case 200: + return _mm512_mask_blend_ps(0XF0C0, a.values, b.values); + case 201: + return _mm512_mask_blend_ps(0xF0C3, a.values, b.values); + case 202: + return _mm512_mask_blend_ps(0xF0CC, a.values, b.values); + case 203: + return _mm512_mask_blend_ps(0xF0CF, a.values, b.values); + case 204: + return _mm512_mask_blend_ps(0xF0F0, a.values, b.values); + case 205: + return _mm512_mask_blend_ps(0xF0F3, a.values, b.values); + case 206: + return _mm512_mask_blend_ps(0xF0FC, a.values, b.values); + case 207: + return _mm512_mask_blend_ps(0xF0FF, a.values, b.values); + case 208: + return _mm512_mask_blend_ps(0XF300, a.values, b.values); + case 209: + return _mm512_mask_blend_ps(0xF303, a.values, b.values); + case 210: + return _mm512_mask_blend_ps(0xF30C, a.values, b.values); + case 211: + return _mm512_mask_blend_ps(0xF30F, a.values, b.values); + case 212: + return _mm512_mask_blend_ps(0xF330, a.values, b.values); + case 213: + return _mm512_mask_blend_ps(0xF333, a.values, b.values); + case 214: + return _mm512_mask_blend_ps(0XF33C, a.values, b.values); + case 215: + return _mm512_mask_blend_ps(0xF33F, a.values, b.values); + case 216: + return _mm512_mask_blend_ps(0xF3C0, a.values, b.values); + case 217: + return _mm512_mask_blend_ps(0xF3C3, a.values, b.values); + case 218: + return _mm512_mask_blend_ps(0xF3CC, a.values, b.values); + case 219: + return _mm512_mask_blend_ps(0xF3CF, a.values, b.values); + case 220: + return _mm512_mask_blend_ps(0xF3F0, a.values, b.values); + case 221: + return _mm512_mask_blend_ps(0xF3F3, a.values, b.values); + case 222: + return _mm512_mask_blend_ps(0xF3FC, a.values, b.values); + case 223: + return _mm512_mask_blend_ps(0XF3FF, a.values, b.values); + case 224: + return _mm512_mask_blend_ps(0xFC00, a.values, b.values); + case 225: + return _mm512_mask_blend_ps(0xFC03, a.values, b.values); + case 226: + return _mm512_mask_blend_ps(0xFC0C, a.values, b.values); + case 227: + return _mm512_mask_blend_ps(0xFC0F, a.values, b.values); + case 228: + return _mm512_mask_blend_ps(0xFC30, a.values, b.values); + case 229: + return _mm512_mask_blend_ps(0xFC33, a.values, b.values); + case 230: + return _mm512_mask_blend_ps(0xFC3C, a.values, b.values); + case 231: + return _mm512_mask_blend_ps(0xFC3F, a.values, b.values); + case 232: + return _mm512_mask_blend_ps(0xFCC0, a.values, b.values); + case 233: + return _mm512_mask_blend_ps(0xFCC3, a.values, b.values); + case 234: + return _mm512_mask_blend_ps(0xFCCC, a.values, b.values); + case 235: + return _mm512_mask_blend_ps(0xFCCF, a.values, b.values); + case 236: + return _mm512_mask_blend_ps(0xFCF0, a.values, b.values); + case 237: + return _mm512_mask_blend_ps(0xFCF3, a.values, b.values); + case 238: + return _mm512_mask_blend_ps(0xFCFC, a.values, b.values); + case 239: + return _mm512_mask_blend_ps(0xFCFF, a.values, b.values); + case 240: + return _mm512_mask_blend_ps(0xFF00, a.values, b.values); + case 241: + return _mm512_mask_blend_ps(0xFF03, a.values, b.values); + case 242: + return _mm512_mask_blend_ps(0xFF0C, a.values, b.values); + case 243: + return _mm512_mask_blend_ps(0xFF0F, a.values, b.values); + case 244: + return _mm512_mask_blend_ps(0xFF30, a.values, b.values); + case 245: + return _mm512_mask_blend_ps(0xFF33, a.values, b.values); + case 246: + return _mm512_mask_blend_ps(0xFF3C, a.values, b.values); + case 247: + return _mm512_mask_blend_ps(0xFF3F, a.values, b.values); + case 248: + return _mm512_mask_blend_ps(0xFFC0, a.values, b.values); + case 249: + return _mm512_mask_blend_ps(0xFFC3, a.values, b.values); + case 250: + return _mm512_mask_blend_ps(0xFFCC, a.values, b.values); + case 251: + return _mm512_mask_blend_ps(0xFFCF, a.values, b.values); + case 252: + return _mm512_mask_blend_ps(0xFFF0, a.values, b.values); + case 253: + return _mm512_mask_blend_ps(0xFFF3, a.values, b.values); + case 254: + return _mm512_mask_blend_ps(0xFFFC, a.values, b.values); + default: break; + } + return b; + } + static Vectorized> blendv(const Vectorized>& a, + const Vectorized>& b, + const Vectorized>& mask) { + // convert c10::complex index mask to V index mask: xy -> xxyy + auto mask_ = _mm512_unpacklo_ps(mask.values, mask.values); + auto all_ones = _mm512_set1_epi32(0xFFFFFFFF); + auto mmask = _mm512_cmp_epi32_mask(_mm512_castps_si512(mask_), all_ones, _MM_CMPINT_EQ); + return _mm512_mask_blend_ps(mmask, a.values, b.values); + } + template + static Vectorized> arange(c10::complex base = 0., + step_t step = static_cast(1)) { + return Vectorized>(base, + base + step, + base + c10::complex(2)*step, + base + c10::complex(3)*step, + base + c10::complex(4)*step, + base + c10::complex(5)*step, + base + c10::complex(6)*step, + base + c10::complex(7)*step); + } + static Vectorized> set(const Vectorized>& a, + const Vectorized>& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + } + return b; + } + static Vectorized> loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return _mm512_loadu_ps(reinterpret_cast(ptr)); + + __at_align__ float tmp_values[2*size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(2*size())) { + tmp_values[i] = 0.0; + } + std::memcpy( + tmp_values, + reinterpret_cast(ptr), + count * sizeof(c10::complex)); + return _mm512_load_ps(tmp_values); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + _mm512_storeu_ps(reinterpret_cast(ptr), values); + } else if (count > 0) { + float tmp_values[2*size()]; + _mm512_storeu_ps(reinterpret_cast(tmp_values), values); + std::memcpy(ptr, tmp_values, count * sizeof(c10::complex)); + } + } + // AVX512 doesn't have horizontal add & horizontal sub instructions. + // TODO: hadd_pd() & hsub_pd() may have scope for improvement. + static inline __m512 hadd_ps(__m512 a, __m512 b) { + __m512i idx1 = _mm512_set_epi32(30, 14, 28, 12, 26, 10, 24, 8, 22, 6, 20, 4, 18, 2, 16, 0); + __m512i idx2 = _mm512_set_epi32(31, 15, 29, 13, 27, 11, 25, 9, 23, 7, 21, 5, 19, 3, 17, 1); + return _mm512_add_ps(_mm512_mask_permutex2var_ps(a, 0xffff, idx1, b), + _mm512_mask_permutex2var_ps(a, 0xffff, idx2, b)); + } + static inline __m512 hsub_ps(__m512 a, __m512 b) { + __m512i idx1 = _mm512_set_epi32(30, 14, 28, 12, 26, 10, 24, 8, 22, 6, 20, 4, 18, 2, 16, 0); + __m512i idx2 = _mm512_set_epi32(31, 15, 29, 13, 27, 11, 25, 9, 23, 7, 21, 5, 19, 3, 17, 1); + return _mm512_sub_ps(_mm512_mask_permutex2var_ps(a, 0xffff, idx1, b), + _mm512_mask_permutex2var_ps(a, 0xffff, idx2, b)); + } + const c10::complex& operator[](int idx) const = delete; + c10::complex& operator[](int idx) = delete; + Vectorized> map(c10::complex (*const f)(const c10::complex &)) const { + __at_align__ c10::complex tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + __m512 abs_2_() const { + auto val_2 = _mm512_mul_ps(values, values); // a*a b*b + auto ret = hadd_ps(val_2, val_2); // a*a+b*b a*a+b*b + return ret; + } + __m512 abs_() const { + auto real = _mm512_moveldup_ps(values); // real real + auto imag = _mm512_movehdup_ps(values); // imag imag + return Sleef_hypotf16_u05(real, imag); // abs abs + } + Vectorized> abs() const { + const __m512 real_mask = _mm512_castsi512_ps(_mm512_setr_epi32(0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000)); + return _mm512_and_ps(abs_(), real_mask); // abs 0 + } + __m512 angle_() const { + //angle = atan2(b/a) + auto b_a = _mm512_permute_ps(values, 0xB1); // b a + return Sleef_atan2f16_u10(values, b_a); // 90-angle angle + } + Vectorized> angle() const { + const __m512 real_mask = _mm512_castsi512_ps(_mm512_setr_epi32(0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000)); + auto angle = _mm512_permute_ps(angle_(), 0xB1); // angle 90-angle + return _mm512_and_ps(angle, real_mask); // angle 0 + } + Vectorized> sgn() const { + auto abs = abs_(); + auto zero = _mm512_setzero_ps(); + auto mask = _mm512_cmp_ps_mask(abs, zero, _CMP_EQ_OQ); + auto div = _mm512_div_ps(values, abs); + return _mm512_mask_blend_ps(mask, div, zero); + } + __m512 real_() const { + const __m512 real_mask = _mm512_castsi512_ps(_mm512_setr_epi32(0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, + 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000)); + return _mm512_and_ps(values, real_mask); + } + Vectorized> real() const { + return real_(); + } + __m512 imag_() const { + const __m512 imag_mask = _mm512_castsi512_ps(_mm512_setr_epi32(0x00000000, 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, + 0x00000000, 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, + 0x00000000, 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, + 0x00000000, 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF)); + return _mm512_and_ps(values, imag_mask); + } + Vectorized> imag() const { + return _mm512_permute_ps(imag_(), 0xB1); //b a + } + __m512 conj_() const { + const __m512 sign_mask = _mm512_setr_ps(0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, + 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0); + return _mm512_xor_ps(values, sign_mask); // a -b + } + Vectorized> conj() const { + return conj_(); + } + Vectorized> log() const { + // Most trigonomic ops use the log() op to improve complex number performance. + return map(std::log); + } + Vectorized> log2() const { + const __m512 log2_ = _mm512_set1_ps(std::log(2)); + return _mm512_div_ps(log(), log2_); + } + Vectorized> log10() const { + const __m512 log10_ = _mm512_set1_ps(std::log(10)); + return _mm512_div_ps(log(), log10_); + } + Vectorized> log1p() const { + return map(std::log1p); + } + Vectorized> asin() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // // asin(x) + // // = -i*ln(iz + sqrt(1 -z^2)) + // // = -i*ln((ai - b) + sqrt(1 - (a + bi)*(a + bi))) + // // = -i*ln((-b + ai) + sqrt(1 - (a**2 - b**2) - 2*abi)) + // const __m512 one = _mm512_set1_ps(1); + + // auto conj = conj_(); + // auto b_a = _mm512_permute_ps(conj, 0xB1); //-b a + // auto ab = _mm512_mul_ps(conj, b_a); //-ab -ab + // auto im = _mm512_add_ps(ab, ab); //-2ab -2ab + + // auto val_2 = _mm512_mul_ps(values, values); // a*a b*b + // auto re = hsub_ps(val_2, _mm512_permute_ps(val_2, 0xB1)); // a*a-b*b b*b-a*a + // re = _mm512_sub_ps(one, re); + + // auto root = Vectorized(_mm512_mask_blend_ps(0xAAAA, re, im)).sqrt(); //sqrt(re + i*im) + // auto ln = Vectorized(_mm512_add_ps(b_a, root)).log(); //ln(iz + sqrt()) + // return Vectorized(_mm512_permute_ps(ln.values, 0xB1)).conj(); //-i*ln() + return map(std::asin); + } + Vectorized> acos() const { + return map(std::acos); + } + Vectorized> atan() const; + Vectorized> atanh() const { + return map(std::atanh); + } + Vectorized> exp() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //exp(a + bi) + // // = exp(a)*(cos(b) + sin(b)i) + // auto exp = Sleef_expf16_u10(values); //exp(a) exp(b) + // exp = _mm512_mask_blend_ps(0xAAAA, exp, _mm512_permute_ps(exp, 0xB1)); //exp(a) exp(a) + + // auto sin_cos = Sleef_sincosf16_u10(values); //[sin(a), cos(a)] [sin(b), cos(b)] + // auto cos_sin = _mm512_mask_blend_ps(0xAAAA, _mm512_permute_ps(sin_cos.y, 0xB1), + // sin_cos.x); //cos(b) sin(b) + // return _mm512_mul_ps(exp, cos_sin); + return map(std::exp); + } + Vectorized> exp2() const { + // Use identity 2**x = exp(log(2) * x) + const __m512 ln_2 = _mm512_set1_ps(c10::ln_2); + Vectorized> scaled_values = _mm512_mul_ps(values, ln_2); + return scaled_values.exp(); + } + Vectorized> expm1() const { + return map(std::expm1); + } + Vectorized> sin() const { + return map(std::sin); + } + Vectorized> sinh() const { + return map(std::sinh); + } + Vectorized> cos() const { + return map(std::cos); + } + Vectorized> cosh() const { + return map(std::cosh); + } + Vectorized> ceil() const { + return _mm512_ceil_ps(values); + } + Vectorized> floor() const { + return _mm512_floor_ps(values); + } + Vectorized> neg() const { + auto zero = _mm512_setzero_ps(); + return _mm512_sub_ps(zero, values); + } + Vectorized> round() const { + return _mm512_roundscale_ps(values, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + } + Vectorized> tan() const { + return map(std::tan); + } + Vectorized> tanh() const { + return map(std::tanh); + } + Vectorized> trunc() const { + return _mm512_roundscale_ps(values, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + } + Vectorized> sqrt() const { + return map(std::sqrt); + } + Vectorized> reciprocal() const; + Vectorized> rsqrt() const { + return sqrt().reciprocal(); + } + Vectorized> pow(const Vectorized> &exp) const { + __at_align__ c10::complex x_tmp[size()]; + __at_align__ c10::complex y_tmp[size()]; + store(x_tmp); + exp.store(y_tmp); + for (const auto i : c10::irange(size())) { + x_tmp[i] = std::pow(x_tmp[i], y_tmp[i]); + } + return loadu(x_tmp); + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized> operator==(const Vectorized>& other) const { + auto mask = _mm512_cmp_ps_mask(values, other.values, _CMP_EQ_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vector, mask, 0xFFFFFFFF)); + } + Vectorized> operator!=(const Vectorized>& other) const { + auto mask = _mm512_cmp_ps_mask(values, other.values, _CMP_NEQ_UQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vector, mask, 0xFFFFFFFF)); + } + Vectorized> operator<(const Vectorized>& other [[maybe_unused]]) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator<=(const Vectorized>& other [[maybe_unused]]) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator>(const Vectorized>& other [[maybe_unused]]) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + Vectorized> operator>=(const Vectorized>& other [[maybe_unused]]) const { + TORCH_CHECK(false, "not supported for complex numbers"); + } + + Vectorized> eq(const Vectorized>& other) const; + Vectorized> ne(const Vectorized>& other) const; +}; + +template <> Vectorized> inline operator+(const Vectorized> &a, + const Vectorized> &b) { + return _mm512_add_ps(a, b); +} + +template <> Vectorized> inline operator-(const Vectorized> &a, + const Vectorized> &b) { + return _mm512_sub_ps(a, b); +} + +template <> Vectorized> inline operator*(const Vectorized> &a, + const Vectorized> &b) { + //(a + bi) * (c + di) = (ac - bd) + (ad + bc)i + const __m512 sign_mask = _mm512_setr_ps(0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, + 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0); + auto ac_bd = _mm512_mul_ps(a, b); //ac bd + + auto d_c = _mm512_permute_ps(b, 0xB1); //d c + d_c = _mm512_xor_ps(sign_mask, d_c); //d -c + auto ad_bc = _mm512_mul_ps(a, d_c); //ad -bc + + auto ret = Vectorized>::hsub_ps(ac_bd, ad_bc); //ac - bd ad + bc + return ret; +} + +template <> Vectorized> inline operator/(const Vectorized> &a, + const Vectorized> &b) { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //re + im*i = (a + bi) / (c + di) + // auto mask = _mm512_set1_ps(-0.f); + // auto fabs_cd = _mm512_andnot_ps(mask, b); // |c| |d| + // auto fabs_dc = _mm512_permute_ps(fabs_cd, 0xB1); // |d| |c| + // auto scale = _mm512_rcp14_ps(_mm512_max_ps(fabs_cd, fabs_dc)); // 1/sc 1/sc + // auto a2 = _mm512_mul_ps(a, scale); // a/sc b/sc + // auto b2 = _mm512_mul_ps(b, scale); // c/sc d/sc + // auto acbd2 = _mm512_mul_ps(a2, b2); + + // const __m512 sign_mask = _mm512_setr_ps(-0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, + // -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0); + // auto dc2 = _mm512_permute_ps(b2, 0xB1); // d/sc c/sc + // dc2 = _mm512_xor_ps(sign_mask, dc2); // -d/|c,d| c/sc + // auto adbc2 = _mm512_mul_ps(a2, dc2); //-ad/sc^2 bc/sc^2 + // auto res2 = Vectorized>::hadd_ps(acbd2, adbc2); //(ac+bd)/sc^2 (bc-ad)/sc^2 + + // // get the denominator + // auto denom2 = Vectorized>(b2).abs_2_(); // (c^2+d^2)/sc^2 (c^2+d^2)/sc^2 + // res2 = _mm512_div_ps(res2, denom2); + // return res2; + __at_align__ c10::complex tmp1[Vectorized>::size()]; + __at_align__ c10::complex tmp2[Vectorized>::size()]; + __at_align__ c10::complex out[Vectorized>::size()]; + a.store(tmp1); + b.store(tmp2); + for (const auto i : c10::irange(Vectorized>::size())) { + out[i] = tmp1[i] / tmp2[i]; + } + return _mm512_loadu_ps(reinterpret_cast(out)); +} + +// reciprocal. Implement this here so we can use multiplication. +inline Vectorized> Vectorized>::reciprocal() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // //re + im*i = (a + bi) / (c + di) + // //re = (ac + bd)/abs_2() = c/abs_2() + // //im = (bc - ad)/abs_2() = d/abs_2() + // const __m512 sign_mask = _mm512_setr_ps(0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, + // 0.0, -0.0, 0.0, -0.0, 0.0, -0.0, 0.0, -0.0); + // auto c_d = _mm512_xor_ps(sign_mask, values); //c -d + // return _mm512_div_ps(c_d, abs_2_()); + __at_align__ c10::complex tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = c10::complex(1) / tmp[i]; + } + return loadu(tmp); +} + +inline Vectorized> Vectorized>::atan() const { + // TODO: The vectorized implementation requires special handling for the case where real number/imag number is 0/Inf/NaN. + // // atan(x) = i/2 * ln((i + z)/(i - z)) + // const __m512 i = _mm512_setr_ps(0.0, 1.0, 0.0, 1.0, 0.0, 1.0, 0.0, 1.0, + // 0.0, 1.0, 0.0, 1.0, 0.0, 1.0, 0.0, 1.0); + // const Vectorized i_half = _mm512_setr_ps(0.0, 0.5, 0.0, 0.5, 0.0, 0.5, 0.0, 0.5, + // 0.0, 0.5, 0.0, 0.5, 0.0, 0.5, 0.0, 0.5); + + // auto sum = Vectorized(_mm512_add_ps(i, values)); // a 1+b + // auto sub = Vectorized(_mm512_sub_ps(i, values)); // -a 1-b + // auto ln = (sum/sub).log(); // ln((i + z)/(i - z)) + // return i_half*ln; // i/2*ln() + return map(std::atan); +} + +template <> +Vectorized> inline maximum(const Vectorized>& a, + const Vectorized>& b) { + auto zero_vector = _mm512_set1_epi32(0); + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + auto mask = _mm512_cmp_ps_mask(abs_a, abs_b, _CMP_LT_OQ); + auto max = _mm512_mask_blend_ps(mask, a, b); + // Exploit the fact that all-ones is a NaN. + auto isnan_mask = _mm512_cmp_ps_mask(abs_a, abs_b, _CMP_UNORD_Q); + auto isnan = _mm512_mask_set1_epi32(zero_vector, isnan_mask, 0xFFFFFFFF); + return _mm512_or_ps(max, _mm512_castsi512_ps(isnan)); +} + +template <> +Vectorized> inline minimum(const Vectorized>& a, + const Vectorized>& b) { + auto zero_vector = _mm512_set1_epi32(0); + auto abs_a = a.abs_2_(); + auto abs_b = b.abs_2_(); + auto mask = _mm512_cmp_ps_mask(abs_a, abs_b, _CMP_GT_OQ); + auto min = _mm512_mask_blend_ps(mask, a, b); + // Exploit the fact that all-ones is a NaN. + auto isnan_mask = _mm512_cmp_ps_mask(abs_a, abs_b, _CMP_UNORD_Q); + auto isnan = _mm512_mask_set1_epi32(zero_vector, isnan_mask, 0xFFFFFFFF); + return _mm512_or_ps(min, _mm512_castsi512_ps(isnan)); +} + +template <> +Vectorized> inline operator&(const Vectorized>& a, + const Vectorized>& b) { + return _mm512_and_ps(a, b); +} + +template <> +Vectorized> inline operator|(const Vectorized>& a, + const Vectorized>& b) { + return _mm512_or_ps(a, b); +} + +template <> +Vectorized> inline operator^(const Vectorized>& a, + const Vectorized>& b) { + return _mm512_xor_ps(a, b); +} + +inline Vectorized> Vectorized>::eq( + const Vectorized>& other) const { + auto eq = (*this == other); // compares real and imag individually + // If both real numbers and imag numbers are equal, then the complex numbers are equal + return (eq.real() & eq.imag()) & Vectorized>(_mm512_set1_ps(1.0f)); +} + +inline Vectorized> Vectorized>::ne( + const Vectorized>& other) const { + auto ne = (*this != other); // compares real and imag individually + // If either real numbers or imag numbers are not equal, then the complex numbers are not equal + return (ne.real() | ne.imag()) & Vectorized>(_mm512_set1_ps(1.0f)); +} + +#endif + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_convert.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_convert.h new file mode 100644 index 0000000000000000000000000000000000000000..af4801cccf488debf5e1f58c5d5d6a2d39307046 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_convert.h @@ -0,0 +1,297 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX512) && !defined(_MSC_VER) + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + __m512 value; + cvtbf16_fp32(_mm512_castsi512_si256(src[0]), value); + result[0] = value; + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN result; + __m512 value; + cvtfp16_fp32(_mm512_castsi512_si256(src[0]), value); + result[0] = value; + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + result[0] = _mm512_castsi256_si512(cvtfp32_bf16(src[0])); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + result[0] = convert_float_bfloat16(src[0], src[1]); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + VectorizedN result; + std::tie(result[0], result[1]) = convert_bfloat16_float(src[0]); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN result; + result[0] = _mm512_castsi256_si512(cvtfp32_fp16(src[0])); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN result; + result[0] = convert_float_half(src[0], src[1]); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN result; + std::tie(result[0], result[1]) = convert_half_float(src[0]); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto low = _mm512_cvtepi64_ps(src[0]); + auto high = _mm512_cvtepi64_ps(src[1]); + return Vectorized( + _mm512_insertf32x8(_mm512_castps256_ps512(low), high, 1)); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + at::vec::VectorizedN result; + result[0] = _mm512_cvt_roundps_epi64( + _mm512_castps512_ps256(src[0]), _MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC); + result[1] = _mm512_cvt_roundps_epi64( + _mm512_extractf32x8_ps(src[0], 1), + _MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto low = _mm512_cvtepi64_epi32(src[0]); + auto high = _mm512_cvtepi64_epi32(src[1]); + return Vectorized( + _mm512_inserti32x8(_mm512_castsi256_si512(low), high, 1)); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + at::vec::VectorizedN result; + result[0] = _mm512_cvtepi32_epi64(_mm512_castsi512_si256(src[0])); + result[1] = _mm512_cvtepi32_epi64(_mm512_extracti32x8_epi32(src[0], 1)); + return result; + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto src128 = _mm512_castsi512_si128(src[0]); + return Vectorized(_mm512_cvtepi8_epi32(src128)); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto src128 = _mm512_castsi512_si128(src[0]); + return Vectorized(_mm512_cvtepu8_epi32(src128)); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + return Vectorized(_mm512_cvttps_epi32(src[0])); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + return Vectorized(_mm512_cvtepi32_ps(src[0])); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto src256 = _mm512_castsi512_si256(src[0]); + return Vectorized(_mm512_cvtepu8_epi16(src256)); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto src128 = _mm512_cvtepi32_epi8(src[0]); + return Vectorized(_mm512_castsi128_si512(src128)); + } +}; + +template <> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + auto src256 = _mm512_cvtepi16_epi8(src[0]); + return Vectorized(_mm512_castsi256_si512(src256)); + } +}; + +template +struct VecConvert< + dst_t, + 1, + src_t, + 1, + typename std::enable_if_t< + (is_reduced_floating_point_v && is_8bit_integer_v) || + (is_reduced_floating_point_v && is_8bit_integer_v), + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + VectorizedN tmp_fp32 = VecConvert::apply(src); + return VecConvert::apply(tmp_fp32); + } +}; + +template +struct VecConvert< + dst_t, + 1, + float, + 2, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + at::vec::Vectorized vec1 = convert_float_to_int8(src[0]); + at::vec::Vectorized vec2 = convert_float_to_int8(src[1]); + __m128 lane2 = _mm512_castps512_ps128(_mm512_castsi512_ps(vec2)); + __m512 result = _mm512_insertf32x4(_mm512_castsi512_ps(vec1), lane2, 1); // Insert lane2 into the second 128-bit lane + return at::vec::Vectorized(_mm512_castps_si512(result)); + } +}; + +template +struct VecConvert< + dst_t, + 1, + float, + 1, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + return convert_float_to_int8(src[0]); + } +}; + +template +struct VecConvert< + float, + 2, + src_t, + 1, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + __m512i src2 = _mm512_castsi128_si512( + _mm_castps_si128( + _mm512_extractf32x4_ps(_mm512_castsi512_ps(src[0]), 1) // Extract the second 128-bit lane + ) + ); + return VectorizedN(convert_int8_to_float(src[0]), convert_int8_to_float(src2)); + } +}; + +template +struct VecConvert< + float, + 1, + src_t, + 1, + typename std::enable_if_t, + void>> { + static inline VectorizedN apply(const VectorizedN& src) { + return convert_int8_to_float(src[0]); + } +}; + +template +struct VecConvert< + dst_t, + 1, + int64_t, + 2, + std::enable_if_t< + std::is_same_v || + std::is_same_v>> { + static inline VectorizedN apply( + const VectorizedN& src) { + return VecConvert::apply( + VecConvert::apply(src)); + } +}; + +#endif + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_double.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_double.h new file mode 100644 index 0000000000000000000000000000000000000000..4d2554f231d4a985e2b8e2640f9793a9aa6a6952 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_double.h @@ -0,0 +1,475 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#if (defined(CPU_CAPABILITY_AVX512)) +#define SLEEF_STATIC_LIBS +#include +#endif + + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX512) + +template <> class Vectorized { +private: + static constexpr __m512i zero_vector {0, 0, 0, 0, 0, 0, 0, 0}; +public: + // values needs to be public for compilation with clang + // as vec512.h uses it + __m512d values; + using value_type = double; + using size_type = int; + static constexpr size_type size() { + return 8; + } + Vectorized() {} + Vectorized(__m512d v) : values(v) {} + Vectorized(double val) { + values = _mm512_set1_pd(val); + } + Vectorized(double val1, double val2, double val3, double val4, + double val5, double val6, double val7, double val8) { + values = _mm512_setr_pd(val1, val2, val3, val4, val5, val6, val7, val8); + } + operator __m512d() const { + return values; + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + return _mm512_mask_blend_pd(mask, a.values, b.values); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + auto all_ones = _mm512_set1_epi64(0xFFFFFFFFFFFFFFFF); + auto mmask = _mm512_cmp_epi64_mask(_mm512_castpd_si512(mask.values), all_ones, _MM_CMPINT_EQ); + return _mm512_mask_blend_pd(mmask, a.values, b.values); + } + template + static Vectorized arange(double base = 0., step_t step = static_cast(1)) { + return Vectorized(base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, + base + 7 * step); + } + static Vectorized set(const Vectorized& a, const Vectorized& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return _mm512_loadu_pd(reinterpret_cast(ptr)); + + __mmask8 mask = (1ULL << count) - 1; + return _mm512_maskz_loadu_pd(mask, ptr); + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + _mm512_storeu_pd(reinterpret_cast(ptr), values); + } else if (count > 0) { + __mmask8 mask = (1ULL << count) - 1; + _mm512_mask_storeu_pd(reinterpret_cast(ptr), mask, values); + } + } + const double& operator[](int idx) const = delete; + double& operator[](int idx) = delete; + int zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit and others are translated to 0-bit + __mmask8 cmp = _mm512_cmp_pd_mask(values, _mm512_set1_pd(0.0), _CMP_EQ_OQ); + return static_cast(cmp); + } + Vectorized isnan() const { + auto cmp_mask = _mm512_cmp_pd_mask(values, _mm512_set1_pd(0.0), _CMP_UNORD_Q); + return _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vector, cmp_mask, + 0xFFFFFFFFFFFFFFFF)); + } + bool has_inf_nan() const { + __m512d self_sub = _mm512_sub_pd(values, values); + return (_mm512_movepi8_mask(_mm512_castpd_si512(self_sub)) & 0x7777777777777777) != 0; + } + Vectorized map(double (*const f)(double)) const { + __at_align__ double tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + Vectorized abs() const { + auto mask = _mm512_set1_pd(-0.f); + return _mm512_andnot_pd(mask, values); + } + Vectorized angle() const { + const auto zero_vec = _mm512_castsi512_pd(zero_vector); + const auto nan_vec = _mm512_set1_pd(NAN); + const auto not_nan_mask = _mm512_cmp_pd_mask(values, values, _CMP_EQ_OQ); + const auto not_nan = _mm512_mask_set1_epi64(zero_vector, not_nan_mask, + 0xFFFFFFFFFFFFFFFF); + const auto nan_mask = _mm512_cmp_pd_mask(_mm512_castsi512_pd(not_nan), + zero_vec, _CMP_EQ_OQ); + const auto pi = _mm512_set1_pd(c10::pi); + + const auto neg_mask = _mm512_cmp_pd_mask(values, zero_vec, _CMP_LT_OQ); + auto angle = _mm512_mask_blend_pd(neg_mask, zero_vec, pi); + angle = _mm512_mask_blend_pd(nan_mask, angle, nan_vec); + return angle; + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm512_set1_pd(0); + } + Vectorized conj() const { + return *this; + } + Vectorized acos() const { + return Vectorized(Sleef_acosd8_u10(values)); + } + Vectorized acosh() const { + return Vectorized(Sleef_acoshd8_u10(values)); + } + Vectorized asin() const { + return Vectorized(Sleef_asind8_u10(values)); + } + Vectorized asinh() const { + return Vectorized(Sleef_asinhd8_u10(values)); + } + Vectorized atan() const { + return Vectorized(Sleef_atand8_u10(values)); + } + Vectorized atanh() const { + return Vectorized(Sleef_atanhd8_u10(values)); + } + Vectorized atan2(const Vectorized &b) const { + return Vectorized(Sleef_atan2d8_u10(values, b)); + } + Vectorized copysign(const Vectorized &sign) const { + return Vectorized(Sleef_copysignd8(values, sign)); + } + Vectorized erf() const { + return Vectorized(Sleef_erfd8_u10(values)); + } + Vectorized erfc() const { + return Vectorized(Sleef_erfcd8_u15(values)); + } + Vectorized erfinv() const { + return map(calc_erfinv); + } + Vectorized exp() const { + return Vectorized(Sleef_expd8_u10(values)); + } + Vectorized exp2() const { + return Vectorized(Sleef_exp2d8_u10(values)); + } + Vectorized expm1() const { + return Vectorized(Sleef_expm1d8_u10(values)); + } + Vectorized exp_u20() const { + return exp(); + } + Vectorized fmod(const Vectorized& q) const { + return Vectorized(Sleef_fmodd8(values, q)); + } + Vectorized hypot(const Vectorized &b) const { + return Vectorized(Sleef_hypotd8_u05(values, b)); + } + Vectorized i0() const { + return map(calc_i0); + } + Vectorized i0e() const { + return map(calc_i0e); + } + Vectorized digamma() const { + return map(calc_digamma); + } + Vectorized igamma(const Vectorized &x) const { + __at_align__ double tmp[size()]; + __at_align__ double tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (const auto i : c10::irange(size())) { + tmp[i] = calc_igamma(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized igammac(const Vectorized &x) const { + __at_align__ double tmp[size()]; + __at_align__ double tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (const auto i : c10::irange(size())) { + tmp[i] = calc_igammac(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized log() const { + return Vectorized(Sleef_logd8_u10(values)); + } + Vectorized log2() const { + return Vectorized(Sleef_log2d8_u10(values)); + } + Vectorized log10() const { + return Vectorized(Sleef_log10d8_u10(values)); + } + Vectorized log1p() const { + return Vectorized(Sleef_log1pd8_u10(values)); + } + Vectorized sin() const { + return Vectorized(Sleef_sind8_u10(values)); + } + Vectorized sinh() const { + return Vectorized(Sleef_sinhd8_u10(values)); + } + Vectorized cos() const { + return Vectorized(Sleef_cosd8_u10(values)); + } + Vectorized cosh() const { + return Vectorized(Sleef_coshd8_u10(values)); + } + Vectorized ceil() const { + return _mm512_ceil_pd(values); + } + Vectorized floor() const { + return _mm512_floor_pd(values); + } + Vectorized frac() const; + Vectorized neg() const { + return _mm512_xor_pd(_mm512_set1_pd(-0.), values); + } + Vectorized nextafter(const Vectorized &b) const { + return Vectorized(Sleef_nextafterd8(values, b)); + } + Vectorized round() const { + return _mm512_roundscale_pd(values, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + } + Vectorized tan() const { + return Vectorized(Sleef_tand8_u10(values)); + } + Vectorized tanh() const { + return Vectorized(Sleef_tanhd8_u10(values)); + } + Vectorized trunc() const { + return _mm512_roundscale_pd(values, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + } + Vectorized lgamma() const { + return Vectorized(Sleef_lgammad8_u10(values)); + } + Vectorized sqrt() const { + return _mm512_sqrt_pd(values); + } + Vectorized reciprocal() const { + return _mm512_div_pd(_mm512_set1_pd(1), values); + } + Vectorized rsqrt() const { + return _mm512_div_pd(_mm512_set1_pd(1), _mm512_sqrt_pd(values)); + } + Vectorized pow(const Vectorized &b) const { + return Vectorized(Sleef_powd8_u10(values, b)); + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized operator==(const Vectorized& other) const { + auto cmp_mask = _mm512_cmp_pd_mask(values, other.values, _CMP_EQ_OQ); + return _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vector, cmp_mask, + 0xFFFFFFFFFFFFFFFF)); + } + + Vectorized operator!=(const Vectorized& other) const { + auto cmp_mask = _mm512_cmp_pd_mask(values, other.values, _CMP_NEQ_UQ); + return _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vector, cmp_mask, + 0xFFFFFFFFFFFFFFFF)); + } + + Vectorized operator<(const Vectorized& other) const { + auto cmp_mask = _mm512_cmp_pd_mask(values, other.values, _CMP_LT_OQ); + return _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vector, cmp_mask, + 0xFFFFFFFFFFFFFFFF)); + } + + Vectorized operator<=(const Vectorized& other) const { + auto cmp_mask = _mm512_cmp_pd_mask(values, other.values, _CMP_LE_OQ); + return _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vector, cmp_mask, + 0xFFFFFFFFFFFFFFFF)); + } + + Vectorized operator>(const Vectorized& other) const { + auto cmp_mask = _mm512_cmp_pd_mask(values, other.values, _CMP_GT_OQ); + return _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vector, cmp_mask, + 0xFFFFFFFFFFFFFFFF)); + } + + Vectorized operator>=(const Vectorized& other) const { + auto cmp_mask = _mm512_cmp_pd_mask(values, other.values, _CMP_GE_OQ); + return _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vector, cmp_mask, + 0xFFFFFFFFFFFFFFFF)); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; +}; + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm512_add_pd(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm512_sub_pd(a, b); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return _mm512_mul_pd(a, b); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return _mm512_div_pd(a, b); +} + +// frac. Implement this here so we can use subtraction. +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + auto zero_vec = _mm512_set1_epi64(0); + Vectorized max = _mm512_max_pd(a, b); + auto isnan_mask = _mm512_cmp_pd_mask(a, b, _CMP_UNORD_Q); + auto isnan = _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vec, isnan_mask, + 0xFFFFFFFFFFFFFFFF)); + // Exploit the fact that all-ones is a NaN. + return _mm512_or_pd(max, isnan); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + auto zero_vec = _mm512_set1_epi64(0); + Vectorized min = _mm512_min_pd(a, b); + auto isnan_mask = _mm512_cmp_pd_mask(a, b, _CMP_UNORD_Q); + auto isnan = _mm512_castsi512_pd(_mm512_mask_set1_epi64(zero_vec, isnan_mask, + 0xFFFFFFFFFFFFFFFF)); + // Exploit the fact that all-ones is a NaN. + return _mm512_or_pd(min, isnan); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min, const Vectorized& max) { + return _mm512_min_pd(max, _mm512_max_pd(min, a)); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + return _mm512_max_pd(min, a); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + return _mm512_min_pd(max, a); +} + +template <> +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return _mm512_and_pd(a, b); +} + +template <> +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return _mm512_or_pd(a, b); +} + +template <> +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return _mm512_xor_pd(a, b); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0); +} + +template <> +inline void convert(const double* src, double* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + _mm512_storeu_pd(dst + i, _mm512_loadu_pd(src + i)); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = src[i]; + } +} + +template <> +Vectorized inline fmadd(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return _mm512_fmadd_pd(a, b, c); +} + +template <> +Vectorized inline fmsub(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return _mm512_fmsub_pd(a, b, c); +} + +#endif + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_float.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_float.h new file mode 100644 index 0000000000000000000000000000000000000000..43a8e5c48cbeedb21b629c26f3a2f4c80376ef7c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_float.h @@ -0,0 +1,732 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#if defined(CPU_CAPABILITY_AVX512) +#define SLEEF_STATIC_LIBS +#include +#endif + + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX512) + +template <> class Vectorized { +private: + static constexpr __m512i zero_vec {0, 0, 0, 0, 0, 0, 0, 0}; +public: + __m512 values; + using value_type = float; + using size_type = int; + static constexpr size_type size() { + return 16; + } + Vectorized() {} + Vectorized(__m512 v) : values(v) {} + Vectorized(float val) { + values = _mm512_set1_ps(val); + } + Vectorized(float val1, float val2, float val3, float val4, + float val5, float val6, float val7, float val8, + float val9, float val10, float val11, float val12, + float val13, float val14, float val15, float val16) { + values = _mm512_setr_ps(val1, val2, val3, val4, val5, val6, val7, val8, + val9, val10, val11, val12, val13, val14, val15, val16); + } + Vectorized(const float (&arr)[16]) + : Vectorized(arr[0], arr[1], arr[2], arr[3], arr[4], arr[5], arr[6], arr[7], + arr[8], arr[9], arr[10], arr[11], arr[12], arr[13], arr[14], arr[15]) {} + operator __m512() const { + return values; + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + return _mm512_mask_blend_ps(mask, a.values, b.values); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + auto all_ones = _mm512_set1_epi32(0xFFFFFFFF); + auto mmask = _mm512_cmp_epi32_mask(_mm512_castps_si512(mask.values), all_ones, _MM_CMPINT_EQ); + return _mm512_mask_blend_ps(mmask, a.values, b.values); + } + template + static Vectorized arange(float base = 0.f, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step, + base + 8 * step, base + 9 * step, base + 10 * step, base + 11 * step, + base + 12 * step, base + 13 * step, base + 14 * step, base + 15 * step); + } + static Vectorized set(const Vectorized& a, const Vectorized& b, + int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + case 8: + return blend<255>(a, b); + case 9: + return blend<511>(a, b); + case 10: + return blend<1023>(a, b); + case 11: + return blend<2047>(a, b); + case 12: + return blend<4095>(a, b); + case 13: + return blend<8191>(a, b); + case 14: + return blend<16383>(a, b); + case 15: + return blend<32767>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr, int64_t count = size()) { + if (count == size()) + return _mm512_loadu_ps(reinterpret_cast(ptr)); + + __mmask16 mask = (1ULL << count) - 1; + return _mm512_maskz_loadu_ps(mask, ptr); + } + void store(void* ptr, int64_t count = size()) const { + if (count == size()) { + _mm512_storeu_ps(reinterpret_cast(ptr), values); + } else if (count > 0) { + __mmask16 mask = (1ULL << count) - 1; + _mm512_mask_storeu_ps(reinterpret_cast(ptr), mask, values); + } + } + const float& operator[](int idx) const = delete; + float& operator[](int idx) = delete; + int zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit and others are translated to 0-bit + __mmask16 cmp = _mm512_cmp_ps_mask(values, _mm512_set1_ps(0.0), _CMP_EQ_OQ); + return static_cast(cmp); + } + Vectorized isnan() const { + auto mask = _mm512_cmp_ps_mask(values, _mm512_set1_ps(0.0), _CMP_UNORD_Q); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, mask, + 0xFFFFFFFF)); + } + bool has_inf_nan() const { + __m512 self_sub = _mm512_sub_ps(values, values); + return (_mm512_movepi8_mask(_mm512_castps_si512(self_sub)) & 0x7777777777777777) != 0; + } + Vectorized map(float (*const f)(float)) const { + __at_align__ float tmp[size()]; + store(tmp); + for (const auto i : c10::irange(size())) { + tmp[i] = f(tmp[i]); + } + return loadu(tmp); + } + Vectorized abs() const { + auto mask = _mm512_set1_ps(-0.f); + return _mm512_andnot_ps(mask, values); + } + Vectorized angle() const { + __m512 zero_vec = _mm512_set1_ps(0.f); + const auto nan_vec = _mm512_set1_ps(NAN); + const auto not_nan_mask = _mm512_cmp_ps_mask(values, values, _CMP_EQ_OQ); + const auto not_nan_vec = _mm512_mask_set1_epi32(_mm512_castps_si512(zero_vec), + not_nan_mask, 0xFFFFFFFF); + const auto nan_mask = _mm512_cmp_ps_mask(_mm512_castsi512_ps(not_nan_vec), + zero_vec, _CMP_EQ_OQ); + const auto pi = _mm512_set1_ps(c10::pi); + + const auto neg_mask = _mm512_cmp_ps_mask(values, zero_vec, _CMP_LT_OQ); + auto angle = _mm512_mask_blend_ps(neg_mask, zero_vec, pi); + angle = _mm512_mask_blend_ps(nan_mask, angle, nan_vec); + return angle; + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm512_set1_ps(0); + } + Vectorized conj() const { + return *this; + } + Vectorized acos() const { + return Vectorized(Sleef_acosf16_u10(values)); + } + Vectorized acosh() const { + return Vectorized(Sleef_acoshf16_u10(values)); + } + Vectorized asin() const { + return Vectorized(Sleef_asinf16_u10(values)); + } + Vectorized asinh() const { + return Vectorized(Sleef_asinhf16_u10(values)); + } + Vectorized atan() const { + return Vectorized(Sleef_atanf16_u10(values)); + } + Vectorized atanh() const { + return Vectorized(Sleef_atanhf16_u10(values)); + } + Vectorized atan2(const Vectorized &b) const { + return Vectorized(Sleef_atan2f16_u10(values, b)); + } + Vectorized copysign(const Vectorized &sign) const { + return Vectorized(Sleef_copysignf16(values, sign)); + } + Vectorized erf() const { + // constants + const auto neg_zero_vec = _mm512_set1_ps(-0.f); + const auto one_vec = _mm512_set1_ps(1.0f); + const auto p = _mm512_set1_ps(0.3275911f); + const auto p1 = _mm512_set1_ps(0.254829592f); + const auto p2 = _mm512_set1_ps(-0.284496736f); + const auto p3 = _mm512_set1_ps(1.421413741f); + const auto p4 = _mm512_set1_ps(-1.453152027f); + const auto p5 = _mm512_set1_ps(1.061405429f); + // sign(x) + auto sign_mask = _mm512_and_ps(neg_zero_vec, values); + auto abs_vec = _mm512_abs_ps(values); + // t = 1 / (p * abs(x) + 1) + auto tmp0 = _mm512_fmadd_ps(p, abs_vec, one_vec); + auto t = _mm512_div_ps(one_vec, tmp0); + // r = p5 * t ^ 4 + p4 * t ^ 3 + p3 * t ^ 2 + p2 * t + p1 + auto tmp1 = _mm512_fmadd_ps(p5, t, p4); + auto tmp2 = _mm512_fmadd_ps(tmp1, t, p3); + auto tmp3 = _mm512_fmadd_ps(tmp2, t, p2); + auto r = _mm512_fmadd_ps(tmp3, t, p1); + // - exp(- x * x) + auto pow_2 = _mm512_mul_ps(values, values); + auto neg_pow_2 = _mm512_xor_ps(neg_zero_vec, pow_2); + // auto tmp4 = exp(neg_pow_2); + auto tmp4 = Vectorized(Sleef_expf16_u10(neg_pow_2)); + auto tmp5 = _mm512_xor_ps(neg_zero_vec, tmp4); + // erf(x) = sign(x) * (1 - r * t * exp(- x * x)) + auto tmp6 = _mm512_mul_ps(tmp5, t); + auto tmp7 = _mm512_fmadd_ps(tmp6, r, one_vec); + return _mm512_xor_ps(sign_mask, tmp7); + } + Vectorized erfc() const { + return Vectorized(Sleef_erfcf16_u15(values)); + } + Vectorized erfinv() const { + return map(calc_erfinv); + } + Vectorized exp() const { + return Vectorized(Sleef_expf16_u10(values)); + } + Vectorized exp2() const { + return Vectorized(Sleef_exp2f16_u10(values)); + } + Vectorized expm1() const { + return Vectorized(Sleef_expm1f16_u10(values)); + } + Vectorized exp_u20() const { + // A faster version of exp with ULP=20 + const __m512 vec_factorial_1 = + _mm512_set1_ps(0.999999701f); // 1/factorial(1) + const __m512 vec_factorial_2 = + _mm512_set1_ps(0.499991506f); // 1/factorial(2) + const __m512 vec_factorial_3 = + _mm512_set1_ps(0.166676521f); // 1/factorial(3) + const __m512 vec_factorial_4 = + _mm512_set1_ps(0.0418978221f); // 1/factorial(4) + const __m512 vec_factorial_5 = + _mm512_set1_ps(0.00828929059f); // 1/factorial(5) + const __m512 vec_exp_log2ef = + _mm512_castsi512_ps(_mm512_set1_epi32(0x3fb8aa3b)); // log2(e) + const __m512 vec_half = _mm512_set1_ps(0.5f); + const __m512 vec_one = _mm512_set1_ps(1.f); + const __m512 vec_zero = _mm512_set1_ps(0.f); + const __m512 vec_two = _mm512_set1_ps(2.f); + const __m512 vec_ln2f = _mm512_castsi512_ps(_mm512_set1_epi32(0x3f317218)); // ln(2) + const __m512 vec_ln_flt_min = _mm512_castsi512_ps(_mm512_set1_epi32(0xc2aeac50)); + const __m512 vec_ln_flt_max = _mm512_castsi512_ps(_mm512_set1_epi32(0x42b17218)); + const __m512i vec_127 = _mm512_set1_epi32(0x0000007f); + const int n_mantissa_bits = 23; + + // exp(x) = + // = exp(n * ln(2) + r) // divide x by ln(2) and get quot and rem + // = 2^n * exp(r) // simplify the exp(n*ln(2)) expression + + auto less_ln_flt_min_mask = + _mm512_cmp_ps_mask(values, vec_ln_flt_min, 1 /*_CMP_LT_OS*/); + auto vec_src = _mm512_min_ps(values, vec_ln_flt_max); + vec_src = _mm512_max_ps(vec_src, vec_ln_flt_min); + + // fx = floorf(x * log2ef + 0.5) + auto vec_fx = _mm512_fmadd_ps(vec_src, vec_exp_log2ef, vec_half); + auto vec_fx_i = _mm512_cvt_roundps_epi32( + vec_fx, _MM_FROUND_TO_NEG_INF | _MM_FROUND_NO_EXC); + vec_fx = _mm512_cvtepi32_ps(vec_fx_i); + + // x = x - fx * ln2 + auto vec_exp_poly = _mm512_fnmadd_ps(vec_fx, vec_ln2f, vec_src); + + // compute polynomial + auto vec_res = + _mm512_fmadd_ps(vec_exp_poly, vec_factorial_5, vec_factorial_4); + vec_res = _mm512_fmadd_ps(vec_exp_poly, vec_res, vec_factorial_3); + vec_res = _mm512_fmadd_ps(vec_exp_poly, vec_res, vec_factorial_2); + vec_res = _mm512_fmadd_ps(vec_exp_poly, vec_res, vec_factorial_1); + vec_res = _mm512_fmadd_ps(vec_exp_poly, vec_res, vec_one); + + // compute 2^(n-1) + auto vec_exp_number = _mm512_sub_ps(vec_fx, vec_one); + auto vec_exp_number_i = _mm512_cvtps_epi32(vec_exp_number); + auto vec_two_pow_n_i = _mm512_add_epi32(vec_exp_number_i, vec_127); + vec_two_pow_n_i = _mm512_slli_epi32(vec_two_pow_n_i, n_mantissa_bits); + auto vec_two_pow_n = _mm512_castsi512_ps(vec_two_pow_n_i); + vec_two_pow_n = + _mm512_mask_blend_ps(less_ln_flt_min_mask, vec_two_pow_n, vec_zero); + + // y = y * 2^n + vec_res = _mm512_mul_ps(vec_res, vec_two_pow_n); + vec_res = _mm512_mul_ps(vec_res, vec_two); + return vec_res; + } + Vectorized fmod(const Vectorized& q) const { + return Vectorized(Sleef_fmodf16(values, q)); + } + Vectorized log() const { + return Vectorized(Sleef_logf16_u10(values)); + } + Vectorized log2() const { + return Vectorized(Sleef_log2f16_u10(values)); + } + Vectorized log10() const { + return Vectorized(Sleef_log10f16_u10(values)); + } + Vectorized log1p() const { + return Vectorized(Sleef_log1pf16_u10(values)); + } + Vectorized frac() const; + Vectorized sin() const { + return Vectorized(Sleef_sinf16_u35(values)); + } + Vectorized sinh() const { + return Vectorized(Sleef_sinhf16_u10(values)); + } + Vectorized cos() const { + return Vectorized(Sleef_cosf16_u35(values)); + } + Vectorized cosh() const { + return Vectorized(Sleef_coshf16_u10(values)); + } + Vectorized ceil() const { + return _mm512_ceil_ps(values); + } + Vectorized floor() const { + return _mm512_floor_ps(values); + } + Vectorized hypot(const Vectorized &b) const { + return Vectorized(Sleef_hypotf16_u05(values, b)); + } + Vectorized i0() const { + return map(calc_i0); + } + Vectorized i0e() const { + return map(calc_i0e); + } + Vectorized digamma() const { + return map(calc_digamma); + } + Vectorized igamma(const Vectorized &x) const { + __at_align__ float tmp[size()]; + __at_align__ float tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (const auto i : c10::irange(size())) { + tmp[i] = calc_igamma(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized igammac(const Vectorized &x) const { + __at_align__ float tmp[size()]; + __at_align__ float tmp_x[size()]; + store(tmp); + x.store(tmp_x); + for (const auto i : c10::irange(size())) { + tmp[i] = calc_igammac(tmp[i], tmp_x[i]); + } + return loadu(tmp); + } + Vectorized neg() const { + return _mm512_xor_ps(_mm512_set1_ps(-0.f), values); + } + Vectorized nextafter(const Vectorized &b) const { + return Vectorized(Sleef_nextafterf16(values, b)); + } + Vectorized round() const { + return _mm512_roundscale_ps(values, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + } + Vectorized tan() const { + return Vectorized(Sleef_tanf16_u10(values)); + } + Vectorized tanh() const { + return Vectorized(Sleef_tanhf16_u10(values)); + } + Vectorized trunc() const { + return _mm512_roundscale_ps(values, (_MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC)); + } + Vectorized lgamma() const { + return Vectorized(Sleef_lgammaf16_u10(values)); + } + Vectorized sqrt() const { + return _mm512_sqrt_ps(values); + } + Vectorized reciprocal() const { + return _mm512_div_ps(_mm512_set1_ps(1), values); + } + Vectorized rsqrt() const { + return _mm512_div_ps(_mm512_set1_ps(1), _mm512_sqrt_ps(values)); + } + Vectorized pow(const Vectorized &b) const { + return Vectorized(Sleef_powf16_u10(values, b)); + } + float reduce_add() const { + return _mm512_reduce_add_ps(values); + } + float reduce_max() const { + return _mm512_reduce_max_ps(values); + } + // Comparison using the _CMP_**_OQ predicate. + // `O`: get false if an operand is NaN + // `Q`: do not raise if an operand is NaN + Vectorized operator==(const Vectorized& other) const { + auto mask = _mm512_cmp_ps_mask(values, other.values, _CMP_EQ_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, mask, + 0xFFFFFFFF)); + } + + Vectorized operator!=(const Vectorized& other) const { + auto mask = _mm512_cmp_ps_mask(values, other.values, _CMP_NEQ_UQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, mask, + 0xFFFFFFFF)); + } + + Vectorized operator<(const Vectorized& other) const { + auto mask = _mm512_cmp_ps_mask(values, other.values, _CMP_LT_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, mask, + 0xFFFFFFFF)); + } + + Vectorized operator<=(const Vectorized& other) const { + auto mask = _mm512_cmp_ps_mask(values, other.values, _CMP_LE_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, mask, + 0xFFFFFFFF)); + } + + Vectorized operator>(const Vectorized& other) const { + auto mask = _mm512_cmp_ps_mask(values, other.values, _CMP_GT_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, mask, + 0xFFFFFFFF)); + } + + Vectorized operator>=(const Vectorized& other) const { + auto mask = _mm512_cmp_ps_mask(values, other.values, _CMP_GE_OQ); + return _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, mask, + 0xFFFFFFFF)); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm512_add_ps(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm512_sub_ps(a, b); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return _mm512_mul_ps(a, b); +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return _mm512_div_ps(a, b); +} + +// frac. Implement this here so we can use subtraction +inline Vectorized Vectorized::frac() const { + return *this - this->trunc(); +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + auto zero_vec = _mm512_set1_epi32(0); + auto max = _mm512_max_ps(a, b); + auto isnan_mask = _mm512_cmp_ps_mask(a, b, _CMP_UNORD_Q); + auto isnan = _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, isnan_mask, + 0xFFFFFFFF)); + // Exploit the fact that all-ones is a NaN. + return _mm512_or_ps(max, isnan); +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + auto zero_vec = _mm512_set1_epi32(0); + auto min = _mm512_min_ps(a, b); + auto isnan_mask = _mm512_cmp_ps_mask(a, b, _CMP_UNORD_Q); + auto isnan = _mm512_castsi512_ps(_mm512_mask_set1_epi32(zero_vec, isnan_mask, + 0xFFFFFFFF)); + // Exploit the fact that all-ones is a NaN. + return _mm512_or_ps(min, isnan); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min, const Vectorized& max) { + return _mm512_min_ps(max, _mm512_max_ps(min, a)); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max) { + return _mm512_min_ps(max, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min) { + return _mm512_max_ps(min, a); +} + +template <> +Vectorized inline operator&(const Vectorized& a, const Vectorized& b) { + return _mm512_and_ps(a, b); +} + +template <> +Vectorized inline operator|(const Vectorized& a, const Vectorized& b) { + return _mm512_or_ps(a, b); +} + +template <> +Vectorized inline operator^(const Vectorized& a, const Vectorized& b) { + return _mm512_xor_ps(a, b); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1.0f); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1.0f); +} + +template <> +inline void convert(const float* src, float* dst, int64_t n) { + int64_t i; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + _mm512_storeu_ps(dst + i, _mm512_loadu_ps(src + i)); + } +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (; i < n; i++) { + dst[i] = src[i]; + } +} + +template <> +Vectorized inline fmadd(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return _mm512_fmadd_ps(a, b, c); +} + +template <> +Vectorized inline fmsub(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return _mm512_fmsub_ps(a, b, c); +} + +// TODO: rewrite with ATEN vectorized (need to add unpack and shuffle) +// Used by Inductor CPP codegen for micro gemm +// Code referred to FBGEMM: +// https://github.com/pytorch/FBGEMM/blob/39a423e4ad1a04b77fea81c7d09c3e6f8984fae9/src/UtilsAvx512.cc#L230-L304 +// kernel for transposing mxn where m, n <= 16 +// (M + 1) / 2 * 2 + (M + 3) / 4 * 4 + (M + 7) / 8 * 8 + N instructions +inline void transpose_block(at::vec::VectorizedN &input, int M=16, int N=16) { + TORCH_CHECK(M <= 16 && N <= 16, "transpose_block expects M, N <= 16."); + // unpacking and interleaving 32-bit elements + __m512 temp[16]; + int i; + for (i = 0; i < (M + 1) / 2; ++i) { + temp[2 * i] = _mm512_unpacklo_ps(input[2 * i], input[2 * i + 1]); + temp[2 * i + 1] = _mm512_unpackhi_ps(input[2 * i], input[2 * i + 1]); + } + for (i = i * 2; i < 16; ++i) { + temp[i] = _mm512_setzero_ps(); + } + + // unpacking and interleaving 64-bit elements + for (i = 0; i < (M + 3) / 4; ++i) { + input[4 * i] = _mm512_castpd_ps(_mm512_unpacklo_pd( + _mm512_castps_pd(temp[4 * i]), _mm512_castps_pd(temp[4 * i + 2]))); + input[4 * i + 1] = _mm512_castpd_ps(_mm512_unpackhi_pd( + _mm512_castps_pd(temp[4 * i]), _mm512_castps_pd(temp[4 * i + 2]))); + input[4 * i + 2] = _mm512_castpd_ps(_mm512_unpacklo_pd( + _mm512_castps_pd(temp[4 * i + 1]), _mm512_castps_pd(temp[4 * i + 3]))); + input[4 * i + 3] = _mm512_castpd_ps(_mm512_unpackhi_pd( + _mm512_castps_pd(temp[4 * i + 1]), _mm512_castps_pd(temp[4 * i + 3]))); + } + + // shuffle 128-bits (composed of 4 32-bit elements) + for (i = 0; i < (M + 7) / 8; ++i) { + temp[8 * i] = _mm512_shuffle_f32x4(input[8 * i], input[8 * i + 4], 0x88); + temp[8 * i + 1] = + _mm512_shuffle_f32x4(input[8 * i + 1], input[8 * i + 5], 0x88); + temp[8 * i + 2] = + _mm512_shuffle_f32x4(input[8 * i + 2], input[8 * i + 6], 0x88); + temp[8 * i + 3] = + _mm512_shuffle_f32x4(input[8 * i + 3], input[8 * i + 7], 0x88); + temp[8 * i + 4] = + _mm512_shuffle_f32x4(input[8 * i], input[8 * i + 4], 0xdd); + temp[8 * i + 5] = + _mm512_shuffle_f32x4(input[8 * i + 1], input[8 * i + 5], 0xdd); + temp[8 * i + 6] = + _mm512_shuffle_f32x4(input[8 * i + 2], input[8 * i + 6], 0xdd); + temp[8 * i + 7] = + _mm512_shuffle_f32x4(input[8 * i + 3], input[8 * i + 7], 0xdd); + } + + for (i = 0; i < N; ++i) { + if (i < 8) { + input[i] = _mm512_shuffle_f32x4(temp[i], temp[8 + i], 0x88); + } else { + input[i] = _mm512_shuffle_f32x4(temp[i - 8], temp[i], 0xdd); + } + } +} + +// TODO(jgong5): rewrite with ATEN vectorized (need to add unpack and shuffle) +// Used by Inductor CPP codegen +// Code referred to FBGEMM: +// https://github.com/pytorch/FBGEMM/blob/39a423e4ad1a04b77fea81c7d09c3e6f8984fae9/src/UtilsAvx512.cc#L230-L304 +// kernel for transposing mxn where m, n <= 16 +// M + (M + 1) / 2 * 2 + (M + 3) / 4 * 4 + (M + 7) / 8 * 8 + 2 * N instructions +inline void transpose_mxn_16x16(const float* src, int64_t ld_src, float* dst, int64_t ld_dst, int M, int N) { + TORCH_CHECK(M <= 16 && N <= 16, "transpose_mxn expects M, N <= 16."); + // load from src to registers + at::vec::VectorizedN input; + int i; + if (N == 16) { + for (i = 0; i < M; ++i) { + input[i] = _mm512_loadu_ps(&src[i * ld_src]); + } + } else { + __mmask16 src_mask = (1 << N) - 1; + for (i = 0; i < M; ++i) { + input[i] = _mm512_maskz_loadu_ps(src_mask, &src[i * ld_src]); + } + } + for (; i < 16; ++i) { + // Not really needed but to avoid uninitialized variable warning. + // Shouldn't be much overhead because xor can be executed in parallel with + // other instructions. + input[i] = _mm512_setzero_ps(); + } + + transpose_block(input, M, N); + + // store from registers to dst + if (M == 16) { + for (i = 0; i < N; ++i) { + _mm512_storeu_ps(&dst[i * ld_dst], input[i]); + } + } else { + __mmask16 dst_mask = (1 << M) - 1; + for (i = 0; i < N; ++i) { + _mm512_mask_storeu_ps(&dst[i * ld_dst], dst_mask, input[i]); + } + } +} + +template<> +inline void transpose_mxn(const float* src, int64_t ld_src, float* dst, int64_t ld_dst, int M, int N) { + int64_t i = 0; + for (; i < M / 16 * 16; i += 16) { + int64_t j = 0; + for (; j < N / 16 * 16; j += 16) { + transpose_mxn_16x16( + src + i * ld_src + j, ld_src, dst + j * ld_dst + i, ld_dst, 16, 16); + } + // handle remainder j + int nrem = N - j; + if (nrem > 0) { + transpose_mxn_16x16( + src + i * ld_src + j, ld_src, dst + j * ld_dst + i, ld_dst, 16, nrem); + } + } + // handle remainder i + int mrem = M - i; + if (mrem > 0) { + int j = 0; + for (; j < N / 16 * 16; j += 16) { + transpose_mxn_16x16( + src + i * ld_src + j, ld_src, dst + j * ld_dst + i, ld_dst, mrem, 16); + } + // handle remainder j + int nrem = N - j; + transpose_mxn_16x16( + src + i * ld_src + j, ld_src, dst + j * ld_dst + i, ld_dst, mrem, nrem); + } +} + +template , int> = 0> +inline void transpose_mxn(const float* src, int64_t ld_src, float* dst, int64_t ld_dst) { + transpose_mxn(src, ld_src, dst, ld_dst, M, N); +} + +#endif + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_int.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_int.h new file mode 100644 index 0000000000000000000000000000000000000000..aa19977e332f7404987c28af5970427be22e8fb0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_int.h @@ -0,0 +1,1478 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include +#include + + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +#ifdef CPU_CAPABILITY_AVX512 + +struct Vectorizedi { +protected: + __m512i values; + static constexpr __m512i zero_vector {0, 0, 0, 0, 0, 0, 0, 0}; + static inline __m512i invert(const __m512i& v) { + const auto ones = _mm512_set1_epi64(-1); + return _mm512_xor_si512(ones, v); + } +public: + Vectorizedi() {} + Vectorizedi(__m512i v) : values(v) {} + operator __m512i() const { + return values; + } +}; + +#else + +struct Vectorizedi {}; // dummy definition to make Vectorizedi always defined + +#endif // CPU_CAPABILITY_AVX512 + +#ifdef CPU_CAPABILITY_AVX512 + +template <> +class Vectorized : public Vectorizedi { +private: + static const Vectorized ones; +public: + using value_type = int64_t; + using size_type = int; + static constexpr size_type size() { + return 8; + } + using Vectorizedi::Vectorizedi; + Vectorized() {} + Vectorized(int64_t v) { values = _mm512_set1_epi64(v); } + Vectorized(int64_t val1, int64_t val2, int64_t val3, int64_t val4, + int64_t val5, int64_t val6, int64_t val7, int64_t val8) { + values = _mm512_setr_epi64(val1, val2, val3, val4, + val5, val6, val7, val8); + } + template + static Vectorized blend(Vectorized a, Vectorized b) { + return _mm512_mask_blend_epi64(mask, a.values, b.values); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + auto msb_one = _mm512_set1_epi64(0xFFFFFFFFFFFFFFFF); + auto mask_ = _mm512_cmp_epi64_mask(mask, msb_one, _MM_CMPINT_EQ); + return _mm512_mask_blend_epi64(mask_, a.values, b.values); + } + template + static Vectorized arange(int64_t base = 0, step_t step = static_cast(1)) { + return Vectorized(base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step); + } + static Vectorized + set(Vectorized a, Vectorized b, int64_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr) { + return _mm512_loadu_si512(reinterpret_cast(ptr)); + } + static Vectorized loadu(const void* ptr, int64_t count) { + if (count == size()) { + return _mm512_loadu_si512(reinterpret_cast(ptr)); + } else { + __mmask8 mask = (1ULL << count) - 1; + return _mm512_maskz_loadu_epi64(mask, ptr); + } + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + // ptr need not to be aligned here. See + // https://software.intel.com/content/www/us/en/develop/documentation/cpp-compiler-developer-guide-and-reference/top/compiler-reference/intrinsics/intrinsics-for-intel-advanced-vector-extensions/intrinsics-for-load-and-store-operations-1/mm512-storeu-si512.html + _mm512_storeu_si512(reinterpret_cast<__m512i*>(ptr), values); + } else if (count > 0) { + __mmask8 mask = (1ULL << count) - 1; + _mm512_mask_storeu_epi64(ptr, mask, values); + } + } + const int64_t& operator[](int idx) const = delete; + int64_t& operator[](int idx) = delete; + Vectorized abs() const { + auto is_larger_mask = _mm512_cmpgt_epi64_mask(zero_vector, values); + auto is_larger = _mm512_mask_set1_epi64(zero_vector, is_larger_mask, 0xFFFFFFFFFFFFFFFF); + auto inverse = _mm512_xor_si512(values, is_larger); + return _mm512_sub_epi64(inverse, is_larger); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm512_set1_epi64(0); + } + Vectorized conj() const { + return *this; + } + Vectorized neg() const; + Vectorized operator==(const Vectorized& other) const { + auto mask = _mm512_cmpeq_epi64_mask(values, other.values); + return _mm512_mask_set1_epi64(zero_vector, mask, 0xFFFFFFFFFFFFFFFF); + } + Vectorized operator!=(const Vectorized& other) const { + auto mask = _mm512_cmpneq_epi64_mask(values, other.values); + return _mm512_mask_set1_epi64(zero_vector, mask, 0xFFFFFFFFFFFFFFFF); + } + Vectorized operator<(const Vectorized& other) const { + auto mask = _mm512_cmplt_epi64_mask(values, other.values); + return _mm512_mask_set1_epi64(zero_vector, mask, 0xFFFFFFFFFFFFFFFF); + } + Vectorized operator<=(const Vectorized& other) const { + auto mask = _mm512_cmple_epi64_mask(values, other.values); + return _mm512_mask_set1_epi64(zero_vector, mask, 0xFFFFFFFFFFFFFFFF); + } + Vectorized operator>(const Vectorized& other) const { + auto mask = _mm512_cmpgt_epi64_mask(values, other.values); + return _mm512_mask_set1_epi64(zero_vector, mask, 0xFFFFFFFFFFFFFFFF); + } + Vectorized operator>=(const Vectorized& other) const { + auto mask = _mm512_cmpge_epi64_mask(values, other.values); + return _mm512_mask_set1_epi64(zero_vector, mask, 0xFFFFFFFFFFFFFFFF); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +class Vectorized : public Vectorizedi { +private: + static constexpr __m512i zero_vector {0, 0, 0, 0, 0, 0, 0, 0}; + static const Vectorized ones; +public: + using value_type = int32_t; + static constexpr int size() { + return 16; + } + using Vectorizedi::Vectorizedi; + Vectorized() {} + Vectorized(int32_t v) { values = _mm512_set1_epi32(v); } + Vectorized(int32_t val1, int32_t val2, int32_t val3, int32_t val4, + int32_t val5, int32_t val6, int32_t val7, int32_t val8, + int32_t val9, int32_t val10, int32_t val11, int32_t val12, + int32_t val13, int32_t val14, int32_t val15, int32_t val16) { + values = _mm512_setr_epi32(val1, val2, val3, val4, val5, val6, val7, val8, + val9, val10, val11, val12, val13, val14, val15, val16); + } + template + static Vectorized blend(Vectorized a, Vectorized b) { + return _mm512_mask_blend_epi32(mask, a.values, b.values); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + auto msb_one = _mm512_set1_epi32(0xFFFFFFFF); + auto mask_ = _mm512_cmp_epi32_mask(mask, msb_one, _MM_CMPINT_EQ); + return _mm512_mask_blend_epi32(mask_, a.values, b.values); + } + template + static Vectorized arange(int32_t base = 0, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step, + base + 8 * step, base + 9 * step, base + 10 * step, base + 11 * step, + base + 12 * step, base + 13 * step, base + 14 * step, base + 15 * step); + } + static Vectorized + set(Vectorized a, Vectorized b, int32_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<1>(a, b); + case 2: + return blend<3>(a, b); + case 3: + return blend<7>(a, b); + case 4: + return blend<15>(a, b); + case 5: + return blend<31>(a, b); + case 6: + return blend<63>(a, b); + case 7: + return blend<127>(a, b); + case 8: + return blend<255>(a, b); + case 9: + return blend<511>(a, b); + case 10: + return blend<1023>(a, b); + case 11: + return blend<2047>(a, b); + case 12: + return blend<4095>(a, b); + case 13: + return blend<8191>(a, b); + case 14: + return blend<16383>(a, b); + case 15: + return blend<32767>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr) { + return _mm512_loadu_si512(reinterpret_cast(ptr)); + } + static Vectorized loadu(const void* ptr, int32_t count) { + if (count == size()) { + return _mm512_loadu_si512(reinterpret_cast(ptr)); + } else { + __mmask16 mask = (1ULL << count) - 1; + return _mm512_maskz_loadu_epi32(mask, ptr); + } + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + // ptr need not to be aligned here. See + // https://software.intel.com/content/www/us/en/develop/documentation/cpp-compiler-developer-guide-and-reference/top/compiler-reference/intrinsics/intrinsics-for-intel-advanced-vector-extensions/intrinsics-for-load-and-store-operations-1/mm512-storeu-si512.html + _mm512_storeu_si512(reinterpret_cast<__m512i*>(ptr), values); + } else if (count > 0) { + __mmask16 mask = (1ULL << count) - 1; + _mm512_mask_storeu_epi32(ptr, mask, values); + } + } + const int32_t& operator[](int idx) const = delete; + int32_t& operator[](int idx) = delete; + Vectorized abs() const { + return _mm512_abs_epi32(values); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm512_set1_epi32(0); + } + Vectorized conj() const { + return *this; + } + Vectorized neg() const; + int32_t reduce_add() const { + return _mm512_reduce_add_epi32(values); + } + int32_t reduce_max() const { + return _mm512_reduce_max_epi32(values); + } + Vectorized operator==(const Vectorized& other) const { + auto mask = _mm512_cmpeq_epi32_mask(values, other.values); + return _mm512_mask_set1_epi32(zero_vector, mask, 0xFFFFFFFF); + } + Vectorized operator!=(const Vectorized& other) const { + auto mask = _mm512_cmpneq_epi32_mask(values, other.values); + return _mm512_mask_set1_epi32(zero_vector, mask, 0xFFFFFFFF); + } + Vectorized operator<(const Vectorized& other) const { + auto mask = _mm512_cmplt_epi32_mask(values, other.values); + return _mm512_mask_set1_epi32(zero_vector, mask, 0xFFFFFFFF); + } + Vectorized operator<=(const Vectorized& other) const { + auto mask = _mm512_cmple_epi32_mask(values, other.values); + return _mm512_mask_set1_epi32(zero_vector, mask, 0xFFFFFFFF); + } + Vectorized operator>(const Vectorized& other) const { + auto mask = _mm512_cmpgt_epi32_mask(values, other.values); + return _mm512_mask_set1_epi32(zero_vector, mask, 0xFFFFFFFF); + } + Vectorized operator>=(const Vectorized& other) const { + auto mask = _mm512_cmpge_epi32_mask(values, other.values); + return _mm512_mask_set1_epi32(zero_vector, mask, 0xFFFFFFFF); + } + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +inline void convert(const int32_t *src, float *dst, int64_t n) { + int64_t i; + // int32_t and float have same size +#ifndef _MSC_VER +# pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + auto input_vec = _mm512_loadu_si512(reinterpret_cast(src + i)); + auto output_vec = _mm512_cvtepi32_ps(input_vec); + _mm512_storeu_ps(reinterpret_cast(dst + i), output_vec); + } +#ifndef _MSC_VER +# pragma unroll +#endif + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +template <> +inline void convert(const int32_t *src, double *dst, int64_t n) { + int64_t i; + // int32_t has half the size of double +#ifndef _MSC_VER +# pragma unroll +#endif + for (i = 0; i <= (n - Vectorized::size()); i += Vectorized::size()) { + auto input_256_vec = _mm256_loadu_si256(reinterpret_cast(src + i)); + auto output_vec = _mm512_cvtepi32_pd(input_256_vec); + _mm512_storeu_pd(reinterpret_cast(dst + i), output_vec); + } +#ifndef _MSC_VER +# pragma unroll +#endif + for (; i < n; i++) { + dst[i] = static_cast(src[i]); + } +} + +template <> +class Vectorized : public Vectorizedi { +private: + static const Vectorized ones; + static constexpr __m512i zero_vector {0, 0, 0, 0, 0, 0, 0, 0}; +public: + using value_type = int16_t; + static constexpr int size() { + return 32; + } + using Vectorizedi::Vectorizedi; + Vectorized() {} + Vectorized(int16_t v) { values = _mm512_set1_epi16(v); } + Vectorized(int16_t val1, int16_t val2, int16_t val3, int16_t val4, + int16_t val5, int16_t val6, int16_t val7, int16_t val8, + int16_t val9, int16_t val10, int16_t val11, int16_t val12, + int16_t val13, int16_t val14, int16_t val15, int16_t val16, + int16_t val17, int16_t val18, int16_t val19, int16_t val20, + int16_t val21, int16_t val22, int16_t val23, int16_t val24, + int16_t val25, int16_t val26, int16_t val27, int16_t val28, + int16_t val29, int16_t val30, int16_t val31, int16_t val32) { + values = _mm512_set_epi16(val32, val31, val30, val29, val28, val27, val26, val25, + val24, val23, val22, val21, val20, val19, val18, val17, + val16, val15, val14, val13, val12, val11, val10, val9, + val8, val7, val6, val5, val4, val3, val2, val1); + } + template + static Vectorized blend(Vectorized a, Vectorized b) { + return _mm512_mask_blend_epi16(mask, a.values, b.values); + } + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + auto msb_one = _mm512_set1_epi16(0xFFFF); + auto mask_ = _mm512_cmp_epi16_mask(mask, msb_one, _MM_CMPINT_EQ); + return _mm512_mask_blend_epi16(mask_, a.values, b.values); + } + template + static Vectorized arange(int16_t base = 0, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step, + base + 8 * step, base + 9 * step, base + 10 * step, base + 11 * step, + base + 12 * step, base + 13 * step, base + 14 * step, base + 15 * step, + base + 16 * step, base + 17 * step, base + 18 * step, base + 19 * step, + base + 20 * step, base + 21 * step, base + 22 * step, base + 23 * step, + base + 24 * step, base + 25 * step, base + 26 * step, base + 27 * step, + base + 28 * step, base + 29 * step, base + 30 * step, base + 31 * step + ); + } + static Vectorized + set(Vectorized a, Vectorized b, int16_t count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<0x1>(a, b); + case 2: + return blend<0x3>(a, b); + case 3: + return blend<0x7>(a, b); + case 4: + return blend<0xF>(a, b); + case 5: + return blend<0x1F>(a, b); + case 6: + return blend<0x3F>(a, b); + case 7: + return blend<0x7F>(a, b); + case 8: + return blend<0xFF>(a, b); + case 9: + return blend<0x1FF>(a, b); + case 10: + return blend<0x3FF>(a, b); + case 11: + return blend<0x7FF>(a, b); + case 12: + return blend<0xFFF>(a, b); + case 13: + return blend<0x1FFF>(a, b); + case 14: + return blend<0x3FFF>(a, b); + case 15: + return blend<0x7FFF>(a, b); + case 16: + return blend<0xFFFF>(a, b); + case 17: + return blend<0x1FFFF>(a, b); + case 18: + return blend<0x3FFFF>(a, b); + case 19: + return blend<0x7FFFF>(a, b); + case 20: + return blend<0xFFFFF>(a, b); + case 21: + return blend<0x1FFFFF>(a, b); + case 22: + return blend<0x3FFFFF>(a, b); + case 23: + return blend<0x7FFFFF>(a, b); + case 24: + return blend<0xFFFFFF>(a, b); + case 25: + return blend<0x1FFFFFF>(a, b); + case 26: + return blend<0x3FFFFFF>(a, b); + case 27: + return blend<0x7FFFFFF>(a, b); + case 28: + return blend<0xFFFFFFF>(a, b); + case 29: + return blend<0x1FFFFFFF>(a, b); + case 30: + return blend<0x3FFFFFFF>(a, b); + case 31: + return blend<0x7FFFFFFF>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr) { + return _mm512_loadu_si512(reinterpret_cast(ptr)); + } + static Vectorized loadu(const void* ptr, int16_t count) { + if (count == size()) { + return _mm512_loadu_si512(reinterpret_cast(ptr)); + } else { + __mmask32 mask = (1ULL << count) - 1; + return _mm512_maskz_loadu_epi16(mask, ptr); + } + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + // ptr need not to be aligned here. See + // https://software.intel.com/content/www/us/en/develop/documentation/cpp-compiler-developer-guide-and-reference/top/compiler-reference/intrinsics/intrinsics-for-intel-advanced-vector-extensions/intrinsics-for-load-and-store-operations-1/mm512-storeu-si512.html + _mm512_storeu_si512(reinterpret_cast<__m512i*>(ptr), values); + } else if (count > 0) { + __mmask32 mask = (1ULL << count) - 1; + _mm512_mask_storeu_epi16(ptr, mask, values); + } + } + const int16_t& operator[](int idx) const = delete; + int16_t& operator[](int idx) = delete; + Vectorized abs() const { + return _mm512_abs_epi16(values); + } + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm512_set1_epi16(0); + } + Vectorized conj() const { + return *this; + } + Vectorized neg() const; + Vectorized operator==(const Vectorized& other) const { + auto mask = _mm512_cmpeq_epi16_mask(values, other.values); + return _mm512_mask_set1_epi16(zero_vector, mask, 0xFFFF); + } + Vectorized operator!=(const Vectorized& other) const { + auto mask = _mm512_cmpneq_epi16_mask(values, other.values); + return _mm512_mask_set1_epi16(zero_vector, mask, 0xFFFF); + } + Vectorized operator<(const Vectorized& other) const { + auto mask = _mm512_cmplt_epi16_mask(values, other.values); + return _mm512_mask_set1_epi16(zero_vector, mask, 0xFFFF); + } + Vectorized operator<=(const Vectorized& other) const { + auto mask = _mm512_cmple_epi16_mask(values, other.values); + return _mm512_mask_set1_epi16(zero_vector, mask, 0xFFFF); + } + Vectorized operator>(const Vectorized& other) const { + auto mask = _mm512_cmpgt_epi16_mask(values, other.values); + return _mm512_mask_set1_epi16(zero_vector, mask, 0xFFFF); + } + Vectorized operator>=(const Vectorized& other) const { + auto mask = _mm512_cmpge_epi16_mask(values, other.values); + return _mm512_mask_set1_epi16(zero_vector, mask, 0xFFFF); + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template +class Vectorized8 : public Vectorizedi { + static_assert( + std::is_same_v || std::is_same_v, + "Only int8_t/uint8_t are supported"); +protected: + static constexpr __m512i zero_vector {0, 0, 0, 0, 0, 0, 0, 0}; + static const Vectorized ones; +public: + using value_type = T; + static constexpr int size() { + return 64; + } + using Vectorizedi::Vectorizedi; + Vectorized8() {} + Vectorized8(T v) { values = _mm512_set1_epi8(v); } + Vectorized8(T val1, T val2, T val3, T val4, + T val5, T val6, T val7, T val8, + T val9, T val10, T val11, T val12, + T val13, T val14, T val15, T val16, + T val17, T val18, T val19, T val20, + T val21, T val22, T val23, T val24, + T val25, T val26, T val27, T val28, + T val29, T val30, T val31, T val32, + T val33, T val34, T val35, T val36, + T val37, T val38, T val39, T val40, + T val41, T val42, T val43, T val44, + T val45, T val46, T val47, T val48, + T val49, T val50, T val51, T val52, + T val53, T val54, T val55, T val56, + T val57, T val58, T val59, T val60, + T val61, T val62, T val63, T val64){ + values = _mm512_set_epi8(val64, val63, val62, val61, val60, val59, val58, val57, + val56, val55, val54, val53,val52, val51, val50, val49, + val48, val47, val46, val45, val44, val43, val42, val41, + val40, val39, val38, val37, val36, val35, val34, val33, + val32, val31, val30, val29, val28, val27, val26, val25, + val24, val23, val22, val21, val20, val19, val18, val17, + val16, val15, val14, val13, val12, val11, val10, val9, + val8, val7, val6, val5, val4, val3, val2, val1); + } + template + static Vectorized blend(Vectorized a, Vectorized b) { + return _mm512_mask_blend_epi8(mask, a.values, b.values); + } + template + static Vectorized arange(T base = 0, step_t step = static_cast(1)) { + return Vectorized( + base, base + step, base + 2 * step, base + 3 * step, + base + 4 * step, base + 5 * step, base + 6 * step, base + 7 * step, + base + 8 * step, base + 9 * step, base + 10 * step, base + 11 * step, + base + 12 * step, base + 13 * step, base + 14 * step, base + 15 * step, + base + 16 * step, base + 17 * step, base + 18 * step, base + 19 * step, + base + 20 * step, base + 21 * step, base + 22 * step, base + 23 * step, + base + 24 * step, base + 25 * step, base + 26 * step, base + 27 * step, + base + 28 * step, base + 29 * step, base + 30 * step, base + 31 * step, + base + 32 * step, base + 33 * step, base + 34 * step, base + 35 * step, + base + 36 * step, base + 37 * step, base + 38 * step, base + 39 * step, + base + 40 * step, base + 41 * step, base + 42 * step, base + 43 * step, + base + 44 * step, base + 45 * step, base + 46 * step, base + 47 * step, + base + 48 * step, base + 49 * step, base + 50 * step, base + 51 * step, + base + 52 * step, base + 53 * step, base + 54 * step, base + 55 * step, + base + 56 * step, base + 57 * step, base + 58 * step, base + 59 * step, + base + 60 * step, base + 61 * step, base + 62 * step, base + 63 * step); + } + static Vectorized + set(Vectorized a, Vectorized b, T count = size()) { + switch (count) { + case 0: + return a; + case 1: + return blend<0x1>(a, b); + case 2: + return blend<0x3>(a, b); + case 3: + return blend<0x7>(a, b); + case 4: + return blend<0xF>(a, b); + case 5: + return blend<0x1F>(a, b); + case 6: + return blend<0x3F>(a, b); + case 7: + return blend<0x7F>(a, b); + case 8: + return blend<0xFF>(a, b); + case 9: + return blend<0x1FF>(a, b); + case 10: + return blend<0x3FF>(a, b); + case 11: + return blend<0x7FF>(a, b); + case 12: + return blend<0xFFF>(a, b); + case 13: + return blend<0x1FFF>(a, b); + case 14: + return blend<0x3FFF>(a, b); + case 15: + return blend<0x7FFF>(a, b); + case 16: + return blend<0xFFFF>(a, b); + case 17: + return blend<0x1FFFF>(a, b); + case 18: + return blend<0x3FFFF>(a, b); + case 19: + return blend<0x7FFFF>(a, b); + case 20: + return blend<0xFFFFF>(a, b); + case 21: + return blend<0x1FFFFF>(a, b); + case 22: + return blend<0x3FFFFF>(a, b); + case 23: + return blend<0x7FFFFF>(a, b); + case 24: + return blend<0xFFFFFF>(a, b); + case 25: + return blend<0x1FFFFFF>(a, b); + case 26: + return blend<0x3FFFFFF>(a, b); + case 27: + return blend<0x7FFFFFF>(a, b); + case 28: + return blend<0xFFFFFFF>(a, b); + case 29: + return blend<0x1FFFFFFF>(a, b); + case 30: + return blend<0x3FFFFFFF>(a, b); + case 31: + return blend<0x7FFFFFFF>(a, b); + case 32: + return blend<0xFFFFFFFF>(a, b); + case 33: + return blend<0x1FFFFFFFF>(a, b); + case 34: + return blend<0x3FFFFFFFF>(a, b); + case 35: + return blend<0x7FFFFFFFF>(a, b); + case 36: + return blend<0xFFFFFFFFF>(a, b); + case 37: + return blend<0x1FFFFFFFFF>(a, b); + case 38: + return blend<0x3FFFFFFFFF>(a, b); + case 39: + return blend<0x7FFFFFFFFF>(a, b); + case 40: + return blend<0xFFFFFFFFFF>(a, b); + case 41: + return blend<0x1FFFFFFFFFF>(a, b); + case 42: + return blend<0x3FFFFFFFFFF>(a, b); + case 43: + return blend<0x7FFFFFFFFFF>(a, b); + case 44: + return blend<0xFFFFFFFFFFF>(a, b); + case 45: + return blend<0x1FFFFFFFFFFF>(a, b); + case 46: + return blend<0x3FFFFFFFFFFF>(a, b); + case 47: + return blend<0x7FFFFFFFFFFF>(a, b); + case 48: + return blend<0xFFFFFFFFFFFF>(a, b); + case 49: + return blend<0x1FFFFFFFFFFFF>(a, b); + case 50: + return blend<0x3FFFFFFFFFFFF>(a, b); + case 51: + return blend<0x7FFFFFFFFFFFF>(a, b); + case 52: + return blend<0xFFFFFFFFFFFFF>(a, b); + case 53: + return blend<0x1FFFFFFFFFFFFF>(a, b); + case 54: + return blend<0x3FFFFFFFFFFFFF>(a, b); + case 55: + return blend<0x7FFFFFFFFFFFFF>(a, b); + case 56: + return blend<0xFFFFFFFFFFFFFF>(a, b); + case 57: + return blend<0x1FFFFFFFFFFFFFF>(a, b); + case 58: + return blend<0x3FFFFFFFFFFFFFF>(a, b); + case 59: + return blend<0x7FFFFFFFFFFFFFF>(a, b); + case 60: + return blend<0xFFFFFFFFFFFFFFF>(a, b); + case 61: + return blend<0x1FFFFFFFFFFFFFFF>(a, b); + case 62: + return blend<0x3FFFFFFFFFFFFFFF>(a, b); + case 63: + return blend<0x7FFFFFFFFFFFFFFF>(a, b); + } + return b; + } + static Vectorized loadu(const void* ptr) { + return _mm512_loadu_si512(reinterpret_cast(ptr)); + } + static Vectorized loadu_one_fourth(const void* ptr) { + // Fast path if only load element number of 16. + // Note: We didn't merge it as fast path of loadu(const void* ptr, T count), + // Because loadu(const void* ptr, T count) requires zero initialization for upper 384 bits. + // However, by using _mm512_castsi128_si512, the upper 384 bits of the result are undefined. + // TODO We can use _mm512_zextsi128_si512 in the furture, + // since gcc 9.3 doesn't support it now. + __m128i input_128 = _mm_loadu_si128(reinterpret_cast(ptr)); + return _mm512_castsi128_si512(input_128); + } + static Vectorized loadu(const void* ptr, T count) { + if (count == size()) { + return _mm512_loadu_si512(reinterpret_cast(ptr)); + } else if (count == 16) { + // Fast path if only load element number of 16 + return loadu_one_fourth(ptr); + } else { + __mmask64 mask = (1ULL << count) - 1; + return _mm512_maskz_loadu_epi8(mask, ptr); + } + } + void store(void* ptr, int count = size()) const { + if (count == size()) { + // ptr need not to be aligned here. See + // https://software.intel.com/content/www/us/en/develop/documentation/cpp-compiler-developer-guide-and-reference/top/compiler-reference/intrinsics/intrinsics-for-intel-advanced-vector-extensions/intrinsics-for-load-and-store-operations-1/mm512-storeu-si512.html + _mm512_storeu_si512(reinterpret_cast<__m512i*>(ptr), values); + } else if (count > 0) { + if (count == 16) { + // Fast path if only store element number of 16 + _mm_storeu_si128( + reinterpret_cast<__m128i*>(ptr), + _mm512_castsi512_si128(values)); + } else { + __mmask64 mask = (1ULL << count) - 1; + _mm512_mask_storeu_epi8(ptr, mask, values); + } + } + } + const T& operator[](int idx) const = delete; + T& operator[](int idx) = delete; + Vectorized real() const { + return *this; + } + Vectorized imag() const { + return _mm512_set1_epi8(0); + } + Vectorized conj() const { + return *this; + } +}; + +template<> +class Vectorized: public Vectorized8 { +public: + using Vectorized8::Vectorized8; + + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + auto msb_one = _mm512_set1_epi8(0xFF); + auto mask_ = _mm512_cmp_epi8_mask(mask, msb_one, _MM_CMPINT_EQ); + return _mm512_mask_blend_epi8(mask_, a.values, b.values); + } + + Vectorized neg() const; + + Vectorized abs() const { + return _mm512_abs_epi8(values); + } + + Vectorized operator==(const Vectorized& other) const { + auto mask = _mm512_cmpeq_epi8_mask(values, other.values); + return _mm512_mask_set1_epi8(zero_vector, mask, 0xFF); + } + Vectorized operator!=(const Vectorized& other) const { + auto mask = _mm512_cmpneq_epi8_mask(values, other.values); + return _mm512_mask_set1_epi8(zero_vector, mask, 0xFF); + } + Vectorized operator<(const Vectorized& other) const { + auto mask = _mm512_cmplt_epi8_mask(values, other.values); + return _mm512_mask_set1_epi8(zero_vector, mask, 0xFF); + } + Vectorized operator<=(const Vectorized& other) const { + auto mask = _mm512_cmple_epi8_mask(values, other.values); + return _mm512_mask_set1_epi8(zero_vector, mask, 0xFF); + } + Vectorized operator>(const Vectorized& other) const { + return other < *this; + } + Vectorized operator>=(const Vectorized& other) const { + return other <= *this; + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template<> +class Vectorized: public Vectorized8 { +public: + using Vectorized8::Vectorized8; + + static Vectorized blendv(const Vectorized& a, const Vectorized& b, + const Vectorized& mask) { + auto msb_one = _mm512_set1_epi8(0xFF); + auto mask_ = _mm512_cmp_epu8_mask(mask, msb_one, _MM_CMPINT_EQ); + return _mm512_mask_blend_epi8(mask_, a.values, b.values); + } + + Vectorized neg() const; + + Vectorized abs() const { + return *this; + } + + Vectorized operator==(const Vectorized& other) const { + auto mask = _mm512_cmpeq_epu8_mask(values, other.values); + return _mm512_mask_set1_epi8(zero_vector, mask, 0xFF); + } + Vectorized operator!=(const Vectorized& other) const { + auto mask = _mm512_cmpneq_epu8_mask(values, other.values); + return _mm512_mask_set1_epi8(zero_vector, mask, 0xFF); + } + Vectorized operator<(const Vectorized& other) const { + auto mask = _mm512_cmplt_epu8_mask(values, other.values); + return _mm512_mask_set1_epi8(zero_vector, mask, 0xFF); + } + Vectorized operator<=(const Vectorized& other) const { + auto mask = _mm512_cmple_epu8_mask(values, other.values); + return _mm512_mask_set1_epi8(zero_vector, mask, 0xFF); + } + Vectorized operator>(const Vectorized& other) const { + return other < *this; + } + Vectorized operator>=(const Vectorized& other) const { + return other <= *this; + } + + Vectorized eq(const Vectorized& other) const; + Vectorized ne(const Vectorized& other) const; + Vectorized gt(const Vectorized& other) const; + Vectorized ge(const Vectorized& other) const; + Vectorized lt(const Vectorized& other) const; + Vectorized le(const Vectorized& other) const; +}; + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm512_add_epi64(a, b); +} + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm512_add_epi32(a, b); +} + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm512_add_epi16(a, b); +} + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm512_add_epi8(a, b); +} + +template <> +Vectorized inline operator+(const Vectorized& a, const Vectorized& b) { + return _mm512_add_epi8(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm512_sub_epi64(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm512_sub_epi32(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm512_sub_epi16(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm512_sub_epi8(a, b); +} + +template <> +Vectorized inline operator-(const Vectorized& a, const Vectorized& b) { + return _mm512_sub_epi8(a, b); +} + +// Negation. Defined here so we can utilize operator- +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +inline Vectorized Vectorized::neg() const { + return Vectorized(0) - *this; +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return _mm512_mullo_epi64(a, b); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return _mm512_mullo_epi32(a, b); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + return _mm512_mullo_epi16(a, b); +} + +template +Vectorized inline int_elementwise_binary_512(const Vectorized& a, const Vectorized& b, Op op) { + T values_a[Vectorized::size()]; + T values_b[Vectorized::size()]; + a.store(values_a); + b.store(values_b); + for (int i = 0; i != Vectorized::size(); i++) { + values_a[i] = op(values_a[i], values_b[i]); + } + return Vectorized::loadu(values_a); +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + // We don't have an instruction for multiplying int8_t +#ifndef CPU_CAPABILITY_AVX512 + return int_elementwise_binary_512(a, b, std::multiplies()); +#else + __m512i mask00FF = _mm512_set1_epi16(0x00FF); + __m512i a_lo = _mm512_srai_epi16(_mm512_slli_epi16(a, 8), 8); + __m512i b_lo = _mm512_srai_epi16(_mm512_slli_epi16(b, 8), 8); + __m512i a_hi = _mm512_srai_epi16(a, 8); + __m512i b_hi = _mm512_srai_epi16(b, 8); + __m512i res_lo = _mm512_and_si512(_mm512_mullo_epi16(a_lo, b_lo), mask00FF); + __m512i res_hi = _mm512_slli_epi16(_mm512_mullo_epi16(a_hi, b_hi), 8); + __m512i res = _mm512_or_si512(res_hi, res_lo); + return res; +#endif +} + +template <> +Vectorized inline operator*(const Vectorized& a, const Vectorized& b) { + // We don't have an instruction for multiplying uint8_t +#ifndef CPU_CAPABILITY_AVX512 + return int_elementwise_binary_512(a, b, std::multiplies()); +#else + __m512i mask00FF = _mm512_set1_epi16(0x00FF); + __m512i a_lo = _mm512_and_si512 (a, mask00FF); + __m512i b_lo = _mm512_and_si512 (b, mask00FF); + __m512i a_hi = _mm512_srli_epi16(a, 8); + __m512i b_hi = _mm512_srli_epi16(b, 8); + __m512i res_lo = _mm512_and_si512(_mm512_mullo_epi16(a_lo, b_lo), mask00FF); + __m512i res_hi = _mm512_slli_epi16(_mm512_mullo_epi16(a_hi, b_hi), 8); + __m512i res = _mm512_or_si512(res_hi, res_lo); + return res; +#endif +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return _mm512_min_epi64(a, b); +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return _mm512_min_epi32(a, b); +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return _mm512_min_epi16(a, b); +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return _mm512_min_epi8(a, b); +} + +template <> +Vectorized inline minimum(const Vectorized& a, const Vectorized& b) { + return _mm512_min_epu8(a, b); +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return _mm512_max_epi64(a, b); +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return _mm512_max_epi32(a, b); +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return _mm512_max_epi16(a, b); +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return _mm512_max_epi8(a, b); +} + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return _mm512_max_epu8(a, b); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { + return _mm512_min_epi64(max_val, _mm512_max_epi64(a, min_val)); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { + return _mm512_min_epi32(max_val, _mm512_max_epi32(a, min_val)); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { + return _mm512_min_epi16(max_val, _mm512_max_epi16(a, min_val)); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { + return _mm512_min_epi8(max_val, _mm512_max_epi8(a, min_val)); +} + +template <> +Vectorized inline clamp(const Vectorized& a, const Vectorized& min_val, const Vectorized& max_val) { + return _mm512_min_epu8(max_val, _mm512_max_epu8(a, min_val)); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { + return _mm512_min_epi64(max_val, a); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { + return _mm512_min_epi32(max_val, a); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { + return _mm512_min_epi16(max_val, a); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { + return _mm512_min_epi8(max_val, a); +} + +template <> +Vectorized inline clamp_max(const Vectorized& a, const Vectorized& max_val) { + return _mm512_min_epu8(max_val, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { + return _mm512_max_epi64(min_val, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { + return _mm512_max_epi32(min_val, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { + return _mm512_max_epi16(min_val, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { + return _mm512_max_epi8(min_val, a); +} + +template <> +Vectorized inline clamp_min(const Vectorized& a, const Vectorized& min_val) { + return _mm512_max_epu8(min_val, a); +} + +template +std::enable_if_t || std::is_same_v), Vectorized> +inline convert_to_int32(const T* ptr, int count=Vectorized::size()) { + return Vectorized::loadu(ptr, count); +} + +template +std::enable_if_t, Vectorized> +inline convert_to_int32(const int8_t* ptr, int count=Vectorized::size()) { + if (count == Vectorized::size()) { + return _mm512_cvtepi8_epi32(_mm_loadu_si128(reinterpret_cast(ptr))); + } else { + auto a = Vectorized::loadu(ptr, count); + return _mm512_cvtepi8_epi32(_mm512_castsi512_si128(a)); + } +} + +template +std::enable_if_t, Vectorized> +inline convert_to_int32(const uint8_t* ptr, int count=Vectorized::size()) { + if (count == Vectorized::size()) { + return _mm512_cvtepu8_epi32(_mm_loadu_si128(reinterpret_cast(ptr))); + } else { + auto a = Vectorized::loadu(ptr, count); + return _mm512_cvtepu8_epi32(_mm512_castsi512_si128(a)); + } +} + +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_512(a, b, std::divides()); +} +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_512(a, b, std::divides()); +} +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_512(a, b, std::divides()); +} +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_512(a, b, std::divides()); +} +template <> +Vectorized inline operator/(const Vectorized& a, const Vectorized& b) { + return int_elementwise_binary_512(a, b, std::divides()); +} + +template>::value, int> = 0> +inline Vectorized operator&(const Vectorized& a, const Vectorized& b) { + return _mm512_and_si512(a, b); +} +template>::value, int> = 0> +inline Vectorized operator|(const Vectorized& a, const Vectorized& b) { + return _mm512_or_si512(a, b); +} +template>::value, int> = 0> +inline Vectorized operator^(const Vectorized& a, const Vectorized& b) { + return _mm512_xor_si512(a, b); +} +template>::value, int> = 0> +inline Vectorized operator~(const Vectorized& a) { + return _mm512_xor_si512(a, _mm512_set1_epi32(-1)); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +inline Vectorized Vectorized::eq(const Vectorized& other) const { + return (*this == other) & Vectorized(1); +} + +inline Vectorized Vectorized::ne(const Vectorized& other) const { + return (*this != other) & Vectorized(1); +} + +inline Vectorized Vectorized::gt(const Vectorized& other) const { + return (*this > other) & Vectorized(1); +} + +inline Vectorized Vectorized::ge(const Vectorized& other) const { + return (*this >= other) & Vectorized(1); +} + +inline Vectorized Vectorized::lt(const Vectorized& other) const { + return (*this < other) & Vectorized(1); +} + +inline Vectorized Vectorized::le(const Vectorized& other) const { + return (*this <= other) & Vectorized(1); +} + +template || std::is_same_v, int> = 0> +Vectorized inline shift_512_8(const Vectorized& a, const Vectorized& b) { + // No vector instruction for shifting int8_t/uint8_t, so emulating + // it instead. + + // Control masks for shuffle operation, treating 512 bits as an + // array of 8-bit elements, and considering pairs of neighboring + // elements. Specifially, a mask named "ctl_M_N" (M,N in [0,1], and + // M!=N) is set so that shuffle will move element with index M from + // input pair into element with index N in output pair, and element + // with index M in output pair will be set to all 0s. + __m512i ctl_0_1 = _mm512_set_epi8(62, 0x80, 60, 0x80, 58, 0x80, 56, 0x80, + 54, 0x80, 52, 0x80, 50, 0x80, 48, 0x80, + 46, 0x80, 44, 0x80, 42, 0x80, 40, 0x80, + 38, 0x80, 36, 0x80, 34, 0x80, 32, 0x80, + 30, 0x80, 28, 0x80, 26, 0x80, 24, 0x80, + 22, 0x80, 20, 0x80, 18, 0x80, 16, 0x80, + 14, 0x80, 12, 0x80, 10, 0x80, 8, 0x80, + 6, 0x80, 4, 0x80, 2, 0x80, 0, 0x80); + __m512i ctl_1_0 = _mm512_set_epi8(0x80, 63, 0x80, 61, 0x80, 59, 0x80, 57, + 0x80, 55, 0x80, 53, 0x80, 51, 0x80, 49, + 0x80, 47, 0x80, 45, 0x80, 43, 0x80, 41, + 0x80, 39, 0x80, 37, 0x80, 35, 0x80, 33, + 0x80, 31, 0x80, 29, 0x80, 27, 0x80, 25, + 0x80, 23, 0x80, 21, 0x80, 19, 0x80, 17, + 0x80, 15, 0x80, 13, 0x80, 11, 0x80, 9, + 0x80, 7, 0x80, 5, 0x80, 3, 0x80, 1); + + // Masks for bitwise and operation, treating 512 bits as an array of + // 8-bit elements, and considering them in pairs of neighboring + // elements. A mask named "keep_M" (M in [0,1]) is set so that + // bitwise and will copy element with index M from input pair into + // element with the same index in output pair, while the other + // element in output pair will be set to all 0s. + __m512i keep_0 = _mm512_set1_epi16(0xFF); + __m512i keep_1 = _mm512_set1_epi16(0xFF00); + + // Take each 8-bit element with idx%2==0 from input array to be + // shifted and extend it to 16 bits so that 0s are added to the + // right. Then, perform shifting on this 16-bit number. Upper 8 + // bits will be proper result of shifting original 8-bit number, so + // write them to result array, into the same position from which + // corresponding input element is taken. Also, make sure that + // result array elements with idx%2!=0 are set to all 0s. + // + // Note that number of bits to shift for is extended to 16 bits by + // adding 0s to the left. That means this number is not properly + // sign-extended for negative values. However, number of bits to + // shift is treated as an unsigned integer by respective shift + // intrinsics anyway so if negative then either with or without + // proper sign extension, it will be interpreted as a number greater + // than 32, and the shifting result will be the same. + __m512i a0 = _mm512_shuffle_epi8(a, ctl_0_1); + __m512i b0 = _mm512_and_si512(b, keep_0); + __m512i c0; + if (left_shift) + c0 = _mm512_sllv_epi16(a0, b0); + else + if constexpr (std::is_same_v) + c0 = _mm512_srav_epi16(a0, b0); + else + c0 = _mm512_srlv_epi16(a0, b0); + c0 = _mm512_shuffle_epi8(c0, ctl_1_0); + + // Peform shifting the same way for input array elements with + // idx%2==1. + __m512i a1 = _mm512_and_si512(a, keep_1); + __m512i b1 = _mm512_shuffle_epi8(b, ctl_1_0); + __m512i c1; + if (left_shift) + c1 = _mm512_sllv_epi16(a1, b1); + else + if constexpr (std::is_same_v) + c1 = _mm512_srav_epi16(a1, b1); + else + c1 = _mm512_srlv_epi16(a1, b1); + c1 = _mm512_and_si512(c1, keep_1); + + // Merge partial results into the final result. + __m512i c = _mm512_or_si512(c0, c1); + + return c; +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return _mm512_sllv_epi64(a, b); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return _mm512_sllv_epi32(a, b); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return _mm512_sllv_epi16(a, b); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return shift_512_8(a, b); +} + +template <> +Vectorized inline operator<<(const Vectorized& a, const Vectorized& b) { + return shift_512_8(a, b); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return _mm512_srav_epi64(a, b); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return _mm512_srav_epi32(a, b); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return _mm512_srav_epi16(a, b); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return shift_512_8(a, b); +} + +template <> +Vectorized inline operator>>(const Vectorized& a, const Vectorized& b) { + return shift_512_8(a, b); +} + +#endif + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_mask.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_mask.h new file mode 100644 index 0000000000000000000000000000000000000000..d32e1da1cf72c01be6c926568f1284e7320f6a13 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_mask.h @@ -0,0 +1,393 @@ +#pragma once + +#include +#include +#include + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX512) && !defined(_MSC_VER) + +template +struct VecMaskLoad< + T, + dst_n, + mask_t, + mask_n, + typename std::enable_if_t< + (mask_n == dst_n * 2 && dst_n >= 1) && + (std::is_same_v || std::is_same_v), + void>> { + static inline VectorizedN apply( + const T* ptr, + const VecMask& vec_mask) { + at::vec::Vectorized zero_vec(0); + auto all_ones = _mm512_set1_epi32(0xFFFFFFFF); + VectorizedN tmp_vec; + VectorizedN result; + for (int i = 0; i < dst_n; i++) { + tmp_vec[0] = vec_mask[2 * i]; + tmp_vec[1] = vec_mask[2 * i + 1]; + auto int64_mask = VecMask(tmp_vec).template cast(); + auto int_mask = int64_mask.template cast()[0]; + auto mmask = _mm512_cmp_epi32_mask(int_mask, all_ones, _MM_CMPINT_EQ); + if constexpr (std::is_same_v) { + result[i] = Vectorized(_mm512_mask_loadu_ps( + zero_vec, mmask, ptr + i * Vectorized::size())); + } else { + result[i] = Vectorized(_mm512_mask_loadu_epi32( + zero_vec, mmask, ptr + i * Vectorized::size())); + } + } + return result; + } +}; + +template +struct VecMaskLoad< + T, + dst_n, + mask_t, + dst_n, + typename std::enable_if_t< + std::is_same_v || std::is_same_v, + void>> { + static inline VectorizedN apply( + const T* ptr, + const VecMask& vec_mask) { + at::vec::Vectorized zero_vec(0); + auto all_ones = _mm512_set1_epi32(0xFFFFFFFF); + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < dst_n; i++) { + auto tmp_mask = VecMask(vec_mask[i]); + auto int_mask = tmp_mask.template cast()[0]; + auto mmask = _mm512_cmp_epi32_mask(int_mask, all_ones, _MM_CMPINT_EQ); + if constexpr (std::is_same_v) { + result[i] = Vectorized(_mm512_mask_loadu_ps( + zero_vec, mmask, ptr + i * Vectorized::size())); + } else { + result[i] = Vectorized(_mm512_mask_loadu_epi32( + zero_vec, mmask, ptr + i * Vectorized::size())); + } + } + return result; + } +}; + +template +struct VecMaskLoad< + data_t, + dst_n, + mask_t, + dst_n, + std::enable_if_t< + std::is_same_v || + std::is_same_v>> { + static inline VectorizedN apply( + const data_t* ptr, + const VecMask& vec_mask) { + auto all_ones = _mm512_set1_epi32(0xFFFFFFFF); + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < dst_n; i++) { + auto tmp_mask = VecMask(vec_mask[i]); + auto int_mask = tmp_mask.template cast(); + auto mmask0 = _mm512_cmp_epi32_mask(int_mask[0], all_ones, _MM_CMPINT_EQ); + auto mmask1 = _mm512_cmp_epi32_mask(int_mask[1], all_ones, _MM_CMPINT_EQ); + auto zero = _mm256_set1_epi16(0); + auto temp0 = _mm256_mask_loadu_epi16( + zero, mmask0, ptr + (2 * i) * Vectorized::size()); + auto temp1 = _mm256_mask_loadu_epi16( + zero, mmask1, ptr + (2 * i + 1) * Vectorized::size()); + result[i] = Vectorized( + _mm512_inserti32x8(_mm512_castsi256_si512(temp0), temp1, 1)); + } + return result; + } +}; + +template +struct VecMaskLoad< + data_t, + dst_n, + mask_t, + mask_n, + typename std::enable_if_t< + (mask_n == 2 * dst_n && dst_n >= 1) && + (std::is_same_v || std::is_same_v)>> { + static inline VectorizedN apply( + const data_t* ptr, + const VecMask& vec_mask) { + auto all_ones = _mm512_set1_epi32(0xFFFFFFFF); + VectorizedN result; + VectorizedN tmp_vec; + for (int i = 0; i < dst_n; i++) { + tmp_vec[0] = vec_mask[2 * i]; + tmp_vec[1] = vec_mask[2 * i + 1]; + auto int_mask = VecMask(tmp_vec).template cast(); + auto mmask0 = _mm512_cmp_epi32_mask(int_mask[0], all_ones, _MM_CMPINT_EQ); + auto mmask1 = _mm512_cmp_epi32_mask(int_mask[1], all_ones, _MM_CMPINT_EQ); + auto zero = _mm256_set1_epi16(0); + auto temp0 = _mm256_mask_loadu_epi16( + zero, mmask0, ptr + (2 * i) * Vectorized::size()); + auto temp1 = _mm256_mask_loadu_epi16( + zero, mmask1, ptr + (2 * i + 1) * Vectorized::size()); + result[i] = Vectorized( + _mm512_inserti32x8(_mm512_castsi256_si512(temp0), temp1, 1)); + } + return result; + } +}; + +template +struct VecMaskLoad< + data_t, + 1, + mask_t, + 1, + std::enable_if_t< + std::is_same_v || + std::is_same_v>> { + static inline VectorizedN apply( + const data_t* ptr, + const VecMask& vec_mask) { + auto all_ones = _mm512_set1_epi32(0xFFFFFFFF); + auto int_mask = vec_mask.template cast()[0]; + auto mmask = _mm512_cmp_epi32_mask(int_mask, all_ones, _MM_CMPINT_EQ); + auto zero = _mm_set1_epi8(0); + auto temp = _mm_mask_loadu_epi8(zero, mmask, ptr); + return Vectorized( + _mm512_inserti64x2(_mm512_set1_epi32(0), temp, 0)); + } +}; + +template +struct VecMaskLoad< + data_t, + 2, + mask_t, + 1, + std::enable_if_t< + std::is_same_v || + std::is_same_v>> { + static inline VectorizedN apply( + const data_t* ptr, + const VecMask& vec_mask) { + auto all_ones = _mm512_set1_epi32(0xFFFFFFFF); + at::vec::Vectorized zero_vec(0); + auto int_mask = vec_mask.template cast()[0]; + auto mmask = _mm512_cmp_epi32_mask(int_mask, all_ones, _MM_CMPINT_EQ); + at::vec::VectorizedN result; + if constexpr (std::is_same_v) { + result[0] = _mm512_mask_loadu_pd(zero_vec, (__mmask8)mmask, ptr); + result[1] = + _mm512_mask_loadu_pd(zero_vec, (__mmask8)(mmask >> 8), ptr + 8); + } else { + result[0] = _mm512_mask_loadu_epi64(zero_vec, (__mmask8)mmask, ptr); + result[1] = + _mm512_mask_loadu_epi64(zero_vec, (__mmask8)(mmask >> 8), ptr + 8); + } + return result; + } +}; + +template +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result[i] = _mm512_castsi512_ps(vec_mask[i]); + } + return result; + } +}; + +template +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result[i] = _mm512_castps_si512(vec_mask[i]); + } + return result; + } +}; + +template +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result[i] = _mm512_castpd_si512(vec_mask[i]); + } + return result; + } +}; + +template +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result[i] = _mm512_castsi512_pd(vec_mask[i]); + } + return result; + } +}; + +template +struct VecMaskCast< + int64_t, + dst_n, + mask_t, + mask_n, + typename std::enable_if_t< + (dst_n == 2 * mask_n) && + (std::is_same_v || std::is_same_v), + void>> { + static inline VecMask apply( + const VecMask& vec_mask) { + VectorizedN result; + auto int_mask = vec_mask.template cast(); +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < mask_n; ++i) { + auto int64_vec = + convert(VectorizedN(int_mask[i])); + result[2 * i] = int64_vec[0]; + result[2 * i + 1] = int64_vec[1]; + } + return VecMask(result); + } +}; + +template +struct VecMaskCast< + dst_t, + dst_n, + int64_t, + mask_n, + typename std::enable_if_t< + (mask_n == 2 * dst_n) && + (std::is_same_v || std::is_same_v), + void>> { + static inline VecMask apply( + const VecMask& vec_mask) { + VectorizedN result; + VectorizedN int64_vec; + for (int i = 0; i < dst_n; ++i) { + int64_vec[0] = vec_mask[2 * i]; + int64_vec[1] = vec_mask[2 * i + 1]; + result[i] = convert(int64_vec); + } + return VecMask(result).template cast(); + } +}; + +template <> +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + auto int64_mask = VecMaskCast::apply(vec_mask); + return VecMaskCast::apply(int64_mask); + } +}; + +template <> +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + auto int64_mask = VecMaskCast::apply(vec_mask); + return VecMaskCast::apply(int64_mask); + } +}; + +template <> +inline bool VecMask::all_zero() const { + __mmask16 mask = _mm512_test_epi32_mask(mask_[0], mask_[0]); + return mask == 0; +} + +template <> +inline bool VecMask::is_masked(int i) const { + return _mm512_movepi32_mask(mask_[0]) & (1 << i); +} + +template <> +inline bool VecMask::all_masked() const { + __mmask16 mask = _mm512_movepi32_mask(mask_[0]); + return mask == 0xffff; +} + +template +struct VecMaskCheck { + static inline bool all_zero(const VectorizedN& vec_mask) { + bool all_zero = true; + for (int i = 0; i < N; ++i) { + all_zero = + all_zero && (_mm512_test_epi64_mask(vec_mask[i], vec_mask[i]) == 0); + if (!all_zero) { + return all_zero; + } + } + return all_zero; + } + + static inline bool is_masked(const VectorizedN& vec_mask, int i) { + for (int j = 0; j < N; ++j) { + if (i < (j + 1) * 8) { + return _mm512_movepi64_mask(vec_mask[j]) & (1 << (i - j * 8)); + } + } + return false; + } + + static inline bool all_masked(const VectorizedN& vec_mask) { + bool all_masked = true; + for (int i = 0; i < N; ++i) { + all_masked = all_masked && (_mm512_movepi64_mask(vec_mask[i]) == 0xff); + if (!all_masked) { + return all_masked; + } + } + return all_masked; + } +}; + +#define VEC_MASK_METHOD_WITH_CAST_TO_INT( \ + T, N, return_type, method, args_def, args) \ + template <> \ + inline return_type VecMask::method args_def const { \ + return cast().method args; \ + } + +VEC_MASK_METHOD_WITH_CAST_TO_INT(float, 1, bool, all_zero, (), ()) +VEC_MASK_METHOD_WITH_CAST_TO_INT(int64_t, 2, bool, all_zero, (), ()) +VEC_MASK_METHOD_WITH_CAST_TO_INT(float, 1, bool, is_masked, (int i), (i)) +VEC_MASK_METHOD_WITH_CAST_TO_INT(int64_t, 2, bool, is_masked, (int i), (i)) +VEC_MASK_METHOD_WITH_CAST_TO_INT(float, 1, bool, all_masked, (), ()) +VEC_MASK_METHOD_WITH_CAST_TO_INT(int64_t, 2, bool, all_masked, (), ()) + +#undef VEC_MASK_DEFINE_METHOD_WITH_CAST_TO_INT + +#endif + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_qint.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_qint.h new file mode 100644 index 0000000000000000000000000000000000000000..ec14ef51601b5984e36ce9756097804a6f28295f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec512/vec512_qint.h @@ -0,0 +1,1409 @@ +#pragma once + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] + +#include +#include +#include + +#include +#include +#include +#include + +#include +#include + +// This file defines Vectorized<> for the quantized types. +// +// +// Currently, we simply use these classes as efficient converters between +// the quantized types and Vectorized, usually in bandwidth-bound cases +// where doing the arithmetic in full-precision is acceptable (e.g. +// elementwise operators). +// +// +// Conversions are as follows: +// Vectorized -> 4x Vectorized +// Vectorized -> 4x Vectorized +// Vectorized -> 1x Vectorized +// +// The size of the returned float vector is specified by the special +// constexpr function float_num_vecs. The type of the value returned +// from dequantize (and expected as an argument to quantize) is +// specified by float_vec_return_type. +// +// When writing kernels with these vectors, it is expected that floating- +// point operations will be carried out in a loop over Vectorized::float_num_vecs +// iterations. + +namespace at { +namespace vec { +inline namespace CPU_CAPABILITY { + +#if defined(CPU_CAPABILITY_AVX512) + +#ifdef _MSC_VER +__declspec(align(64)) struct Vectorizedqi { + protected: + __m512i vals; +#else +struct Vectorizedqi { + protected: + __m512i vals __attribute__((aligned(64))); +#endif + + public: + Vectorizedqi() {} + Vectorizedqi(__m512i v) : vals(v) {} + operator __m512i() const { + return vals; + } +}; + + +template +__m512i pack_saturate_and_clamp( + __m512i first, + __m512i second, + T min_val, + T max_val); + +template <> +inline __m512i pack_saturate_and_clamp( + __m512i first [[maybe_unused]], + __m512i second [[maybe_unused]], + int32_t min_val [[maybe_unused]], + int32_t max_val [[maybe_unused]]) { + // This function is for linkage only, will not be used + TORCH_CHECK(false, "pack_saturate_and_clamp is not supported"); + return __m512i{}; +} + +template <> +inline __m512i pack_saturate_and_clamp( + __m512i first, + __m512i second, + int8_t min_val, + int8_t max_val) { + __m512i packed_and_sat = _mm512_packs_epi16(first, second); + return _mm512_max_epi8( + _mm512_set1_epi8(min_val), + _mm512_min_epi8(packed_and_sat, _mm512_set1_epi8(max_val))); +} + +template <> +inline __m512i pack_saturate_and_clamp( + __m512i first, + __m512i second, + uint8_t min_val, + uint8_t max_val) { + __m512i packed_and_sat = _mm512_packus_epi16(first, second); + return _mm512_max_epu8( + _mm512_set1_epi8(min_val), + _mm512_min_epu8(packed_and_sat, _mm512_set1_epi8(max_val))); +} + +template +typename std::enable_if_t || std::is_same_v, at::vec::Vectorized> +inline convert_int8_to_float(at::vec::Vectorized src) { + // Note: this function only convert inputs number of elements equal to at::vec::Vectorized.size() + // Only handle first 16*8 bits + __m128i input_128 = _mm512_castsi512_si128(src); + // Convert from 16*uint8/int8 to 16*int32 + __m512i input_512_extended; + if constexpr (std::is_same_v) + input_512_extended = _mm512_cvtepu8_epi32(input_128); + else + input_512_extended = _mm512_cvtepi8_epi32(input_128); + // Convert from 16*int32 to 16*float32 + return _mm512_cvtepi32_ps(input_512_extended); +} + +template +typename std::enable_if_t || std::is_same_v, at::vec::Vectorized> +inline convert_float_to_int8(at::vec::Vectorized src) { + // Convert from float32 to int32 with truncation + __m512i x_values_int32 = _mm512_cvttps_epi32(src); + + // Convert from int32 to int16 using signed saturation + __m512i xy_packed_v = _mm512_packs_epi32(x_values_int32, x_values_int32); + + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + + // Convert from int16 to uint8/int8 using unsigned saturation + __m512i xyzw_clamped_v = pack_saturate_and_clamp( + xy_packed_v, xy_packed_v, min_val, max_val); + __m512i permute_mask_v = + _mm512_set_epi32(0x0f, 0x0b, 0x07, 0x03, 0x0e, 0x0a, 0x06, 0x02, + 0x0d, 0x09, 0x05, 0x01, 0x0c, 0x08, 0x04, 0x00); + return _mm512_permutexvar_epi32(permute_mask_v, xyzw_clamped_v); +} + +template +__FORCE_INLINE void QuantizeAvx512( + const float* src, + T* dst, + int len, + float inverse_scale, + int64_t zero_point) { + constexpr int VLEN = 16; + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + const __m512i min_v = _mm512_set1_epi32(min_val); + const __m512i max_v = _mm512_set1_epi32(max_val); + // This is the largest int32 value < int32_max exactly representable in float + constexpr int32_t int32_float_max_val = + std::numeric_limits::max() - 127; + int i = 0; + __m512 inverse_scale_v = _mm512_set1_ps(inverse_scale); + // clang-format off + static const __m512i shuffle_mask_v = _mm512_set_epi8( + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0x0c, 0x08, 0x04, 0x00, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0x0c, 0x08, 0x04, 0x00, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0x0c, 0x08, 0x04, 0x00, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0xff, 0xff, 0xff, 0xff, + 0x0c, 0x08, 0x04, 0x00); + // clang-format on + __m512i permute_mask_v = + _mm512_set_epi32(0x0f, 0x0b, 0x07, 0x03, 0x0e, 0x0a, 0x06, 0x02, + 0x0d, 0x09, 0x05, 0x01, 0x0c, 0x08, 0x04, 0x00); + __m512i permute_mask_l8_v = + _mm512_set_epi32(0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, + 0x00, 0x00, 0x00, 0x00, 0x0c, 0x08, 0x04, 0x00); + int len_aligned = len / (VLEN * 4) * (VLEN * 4); + for (; i < len_aligned; i += 4 * VLEN) { + // x + __m512 x_vals = _mm512_load_ps(src + i); + __m512 x_transformed_v = _mm512_mul_ps(x_vals, inverse_scale_v); + // If the floating point value is greater than int32_max, + // _mm512_cvtps_epi32 converts them to -ve. Clip at int32_float_max_val to + // Clip at int32_float_max_val to avoid this. + x_transformed_v = + _mm512_min_ps(x_transformed_v, _mm512_set1_ps(int32_float_max_val)); + // y + __m512 y_vals = _mm512_load_ps(src + i + VLEN); + __m512 y_transformed_v = _mm512_mul_ps(y_vals, inverse_scale_v); + y_transformed_v = + _mm512_min_ps(y_transformed_v, _mm512_set1_ps(int32_float_max_val)); + // z + __m512 z_vals = _mm512_load_ps(src + i + 2 * VLEN); + __m512 z_transformed_v = _mm512_mul_ps(z_vals, inverse_scale_v); + z_transformed_v = + _mm512_min_ps(z_transformed_v, _mm512_set1_ps(int32_float_max_val)); + // w + __m512 w_vals = _mm512_load_ps(src + i + 3 * VLEN); + __m512 w_transformed_v = _mm512_mul_ps(w_vals, inverse_scale_v); + w_transformed_v = + _mm512_min_ps(w_transformed_v, _mm512_set1_ps(int32_float_max_val)); + + __m512i x_rounded_v = _mm512_cvtps_epi32(x_transformed_v); + __m512i y_rounded_v = _mm512_cvtps_epi32(y_transformed_v); + __m512i z_rounded_v = _mm512_cvtps_epi32(z_transformed_v); + __m512i w_rounded_v = _mm512_cvtps_epi32(w_transformed_v); + + // add zero point + x_rounded_v = _mm512_add_epi32(x_rounded_v, _mm512_set1_epi32(zero_point)); + y_rounded_v = _mm512_add_epi32(y_rounded_v, _mm512_set1_epi32(zero_point)); + z_rounded_v = _mm512_add_epi32(z_rounded_v, _mm512_set1_epi32(zero_point)); + w_rounded_v = _mm512_add_epi32(w_rounded_v, _mm512_set1_epi32(zero_point)); + + __m512i xy_packed_v = _mm512_packs_epi32(x_rounded_v, y_rounded_v); + __m512i zw_packed_v = _mm512_packs_epi32(z_rounded_v, w_rounded_v); + __m512i xyzw_clamped_v = + pack_saturate_and_clamp(xy_packed_v, zw_packed_v, min_val, max_val); + + xyzw_clamped_v = + _mm512_permutexvar_epi32(permute_mask_v, xyzw_clamped_v); + _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst + i), xyzw_clamped_v); + } + + // Additional 8-lane AVX512 version to take advantage when len is smaller + // based on fbgemm::QuantizeAvx2 (https://github.com/pytorch/FBGEMM) + for (; i < len / VLEN * VLEN; i += VLEN) { + __m512 x_vals = _mm512_load_ps(src + i); + __m512 x_transformed_v = _mm512_mul_ps(x_vals, inverse_scale_v); + x_transformed_v = + _mm512_min_ps(x_transformed_v, _mm512_set1_ps(int32_float_max_val)); + __m512i x_rounded_v = _mm512_cvtps_epi32(x_transformed_v); + x_rounded_v = _mm512_add_epi32(x_rounded_v, _mm512_set1_epi32(zero_point)); + __m512i x_clipped_v = + _mm512_max_epi32(min_v, _mm512_min_epi32(max_v, x_rounded_v)); + + x_clipped_v = _mm512_shuffle_epi8(x_clipped_v, shuffle_mask_v); + x_clipped_v = _mm512_permutexvar_epi32(permute_mask_l8_v, x_clipped_v); + _mm_storeu_si128( + reinterpret_cast<__m128i*>(dst + i), + _mm512_castsi512_si128(x_clipped_v)); + } + + for (; i < len; ++i) { + float transformed = src[i] * inverse_scale; + + // Not exactly the same behavior as the vectorized code. + // The vectorized code above always rounds to even in halfway cases + // (https://software.intel.com/en-us/node/523819), but std::nearbyint + // does the same only when the current rounding mode is FE_TONEAREST. + // However, in practice, this should not be a problem because most cases + // use the default rounding mode FE_TONEAREST. + // Note that we cannot implement the same behavior as the vectorized code + // using std::round because it does rounding away from zero in halfway + // cases. + transformed = zero_point + std::nearbyint(transformed); + float clipped = + std::min(std::max(transformed, float(min_val)), float(max_val)); + dst[i] = clipped; + } +} + +template<> +struct Vectorized : public Vectorizedqi { + using size_type = int; + static constexpr size_type size() { + return 16; + } + + static constexpr int float_num_vecs() { + return 1; + } + + static constexpr int int_num_vecs() { + return 1; + } + + using float_vec_return_type = std::array, 1>; + using int_vec_return_type = std::array, 1>; + using value_type = c10::qint32::underlying; + + public: + using Vectorizedqi::Vectorizedqi; + Vectorized() {} + + Vectorized(__m512i vals_) { vals = vals_;} + + // Broadcast constructor + Vectorized(const c10::qint32& val) { + value_type uw = val.val_; + vals = _mm512_set1_epi32(uw); + } + + void store(void* ptr, int count = size()) const { + if (count != size()) { + memcpy(ptr, &vals, count * sizeof(value_type)); + } else { + _mm512_storeu_si512((__m512i*)ptr, vals); + } + } + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return loadu(tmp_values); + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_zp_premul) const { + __m512 float_vals = _mm512_cvtepi32_ps(vals); + return {vec::fmadd(scale, Vectorized(float_vals), scale_zp_premul)}; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + __m512 float_vals = _mm512_cvtepi32_ps(vals); + return {(Vectorized(float_vals) - zero_point) * scale}; + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale [[maybe_unused]]) { + Vectorized retval; + auto rhs_data = (__m512)rhs[0]; + at::native::quantize_vec( + scale, zero_point, (float*)&rhs_data, (c10::qint32*)&retval.vals, 16); + return retval; + } + + Vectorized maximum(Vectorized b) const { + return _mm512_max_epi32(vals, b.vals); + } + + Vectorized minimum(Vectorized b) const { + return _mm512_min_epi32(vals, b.vals); + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + return _mm512_min_epi32( + _mm512_max_epi32(vals, zero_point.vals), q_six.vals); + } + + int_vec_return_type widening_subtract(Vectorized b) const { + return {_mm512_sub_epi32(vals, b)}; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + __m512 multiplier_v = _mm512_set1_ps(multiplier); + __m512i zero_point_v = _mm512_set1_epi32(zero_point); + + __m512 scaled = _mm512_mul_ps(_mm512_cvtepi32_ps(inp[0]), multiplier_v); + __m512i rounded = _mm512_cvtps_epi32(scaled); + return _mm512_add_epi32(rounded, zero_point_v); + } + + private: + // Load from memory constructor + Vectorized(const void* ptr) { + vals = _mm512_loadu_si512((const __m512i*)ptr); + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline operator*( + const Vectorized& a, + const Vectorized& b) { + return _mm512_mullo_epi32(a, b); +} + +template <> +Vectorized inline operator+( + const Vectorized& a, + const Vectorized& b) { + return _mm512_add_epi32(a, b); +} + +/* + * Convert values from int32 back to int8/uint8 + */ +template +__m512i RequantizeAvx512( + const std::array, 4>& inp, + __m512 multiplier, + __m512i zp) { + static_assert( + std::is_same_v || std::is_same_v, + "Only int8_t/uint8_t are supported"); + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + __m512i permute_mask_v = + _mm512_set_epi32(0x0f, 0x0b, 0x07, 0x03, 0x0e, 0x0a, 0x06, 0x02, + 0x0d, 0x09, 0x05, 0x01, 0x0c, 0x08, 0x04, 0x00); + __m512 x_scaled_v = _mm512_mul_ps(_mm512_cvtepi32_ps(inp[0]), multiplier); + __m512 y_scaled_v = _mm512_mul_ps(_mm512_cvtepi32_ps(inp[1]), multiplier); + __m512 z_scaled_v = _mm512_mul_ps(_mm512_cvtepi32_ps(inp[2]), multiplier); + __m512 w_scaled_v = _mm512_mul_ps(_mm512_cvtepi32_ps(inp[3]), multiplier); + + __m512i x_rounded_v = _mm512_cvtps_epi32(x_scaled_v); + __m512i y_rounded_v = _mm512_cvtps_epi32(y_scaled_v); + __m512i z_rounded_v = _mm512_cvtps_epi32(z_scaled_v); + __m512i w_rounded_v = _mm512_cvtps_epi32(w_scaled_v); + + /* Add zero point */ + __m512i x_v = _mm512_add_epi32(x_rounded_v, zp); + __m512i y_v = _mm512_add_epi32(y_rounded_v, zp); + __m512i z_v = _mm512_add_epi32(z_rounded_v, zp); + __m512i w_v = _mm512_add_epi32(w_rounded_v, zp); + + /* Pack to int16_t and saturate */ + __m512i xy_packed_v = _mm512_packs_epi32(x_v, y_v); + __m512i zw_packed_v = _mm512_packs_epi32(z_v, w_v); + + __m512i xyzw_clamped_v = + pack_saturate_and_clamp(xy_packed_v, zw_packed_v, min_val, max_val); + + /* + * xyzw_clamped_v has results in the following layout so we need to + * permute: x0-3 y0-3 z0-3 w0-3 x4-7 y4-7 z4-7 w4-7 x8-11 y8-11 z8-11 w8-11 x12-15 y12-15 z12-15 w12-15 + */ + xyzw_clamped_v = _mm512_permutexvar_epi32(permute_mask_v, xyzw_clamped_v); + return xyzw_clamped_v; +} + +template<> +struct Vectorized : public Vectorizedqi { + static constexpr int size() { + return 64; + } + + static constexpr int float_num_vecs() { + return 4; + } + + static constexpr int int_num_vecs() { + return 4; + } + + using float_vec_return_type = std::array, 4>; + using int_vec_return_type = std::array, 4>; + using value_type = typename c10::qint8::underlying; + + public: + using Vectorizedqi::Vectorizedqi; + + Vectorized() {} + Vectorized(__m512i vals_) { vals = vals_;} + + // Broadcast constructor + Vectorized(const c10::qint8& val) { + value_type uw = val.val_; + vals = _mm512_set1_epi8(uw); + } + + // This is needed because the compiler emits awful code for the default + // constructor for moving the enum + Vectorized(const Vectorized& other) : Vectorizedqi(other.vals) { } + + // This is added to avoid error: definition of implicit copy assignment operator + // for 'Vectorized' is deprecated because it has a user-declared + // copy constructor [-Werror,-Wdeprecated-copy] + Vectorized& operator=(const Vectorized&) = default; + + void store(void* ptr, int count = size()) const { + if (count != size()) { + memcpy(ptr, &vals, count * sizeof(value_type)); + } else { + _mm512_storeu_si512((__m512i*)ptr, vals); + } + } + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return loadu(tmp_values); + } + + private: + __m512i cvtepi8_epi32(__m128i epi8_vals) const { + return _mm512_cvtepi8_epi32(epi8_vals); + } + + public: + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_neg_zp_premul) const { + #if defined(_MSC_VER) && !defined(__clang__) + __m128i int_val0 = _mm_set_epi64x(vals.m512i_u64[1], vals.m512i_u64[0]); + __m128i int_val1 = _mm_set_epi64x(vals.m512i_u64[3], vals.m512i_u64[2]); + __m128i int_val2 = _mm_set_epi64x(vals.m512i_u64[5], vals.m512i_u64[4]); + __m128i int_val3 = _mm_set_epi64x(vals.m512i_u64[7], vals.m512i_u64[6]); + #else + __m128i int_val0 = _mm_set_epi64x(vals[1], vals[0]); + __m128i int_val1 = _mm_set_epi64x(vals[3], vals[2]); + __m128i int_val2 = _mm_set_epi64x(vals[5], vals[4]); + __m128i int_val3 = _mm_set_epi64x(vals[7], vals[6]); + #endif + + __m512 float_val0 = _mm512_cvtepi32_ps(cvtepi8_epi32(int_val0)); + __m512 float_val1 = _mm512_cvtepi32_ps(cvtepi8_epi32(int_val1)); + __m512 float_val2 = _mm512_cvtepi32_ps(cvtepi8_epi32(int_val2)); + __m512 float_val3 = _mm512_cvtepi32_ps(cvtepi8_epi32(int_val3)); + + auto val0 = + vec::fmadd(scale, Vectorized(float_val0), scale_neg_zp_premul); + auto val1 = + vec::fmadd(scale, Vectorized(float_val1), scale_neg_zp_premul); + auto val2 = + vec::fmadd(scale, Vectorized(float_val2), scale_neg_zp_premul); + auto val3 = + vec::fmadd(scale, Vectorized(float_val3), scale_neg_zp_premul); + return {val0, val1, val2, val3}; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + #if defined(_MSC_VER) && !defined(__clang__) + __m128i int_val0 = _mm_set_epi64x(vals.m512i_u64[1], vals.m512i_u64[0]); + __m128i int_val1 = _mm_set_epi64x(vals.m512i_u64[3], vals.m512i_u64[2]); + __m128i int_val2 = _mm_set_epi64x(vals.m512i_u64[5], vals.m512i_u64[4]); + __m128i int_val3 = _mm_set_epi64x(vals.m512i_u64[7], vals.m512i_u64[6]); + #else + __m128i int_val0 = _mm_set_epi64x(vals[1], vals[0]); + __m128i int_val1 = _mm_set_epi64x(vals[3], vals[2]); + __m128i int_val2 = _mm_set_epi64x(vals[5], vals[4]); + __m128i int_val3 = _mm_set_epi64x(vals[7], vals[6]); + #endif + + __m512 float_val0 = _mm512_cvtepi32_ps(cvtepi8_epi32(int_val0)); + __m512 float_val1 = _mm512_cvtepi32_ps(cvtepi8_epi32(int_val1)); + __m512 float_val2 = _mm512_cvtepi32_ps(cvtepi8_epi32(int_val2)); + __m512 float_val3 = _mm512_cvtepi32_ps(cvtepi8_epi32(int_val3)); + + auto val0 = (Vectorized(float_val0) - zero_point) * scale; + auto val1 = (Vectorized(float_val1) - zero_point) * scale; + auto val2 = (Vectorized(float_val2) - zero_point) * scale; + auto val3 = (Vectorized(float_val3) - zero_point) * scale; + return {val0, val1, val2, val3}; + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + auto* rhs_data = (float*)rhs.data(); + int8_t quantized_values[64]; + QuantizeAvx512( + rhs_data, quantized_values, 64, inverse_scale, zero_point); + return Vectorized::loadu(quantized_values); + } + + Vectorized maximum(Vectorized b) const { + return _mm512_max_epi8(vals, b.vals); + } + + Vectorized minimum(Vectorized b) const { + return _mm512_min_epi8(vals, b.vals); + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + return _mm512_min_epi8( + _mm512_max_epi8(vals, zero_point.vals), q_six.vals); + } + + int_vec_return_type widening_subtract(Vectorized b) const { + #if defined(_MSC_VER) && !defined(__clang__) + __m128i int_val0 = _mm_set_epi64x(vals.m512i_u64[1], vals.m512i_u64[0]); + __m128i int_val1 = _mm_set_epi64x(vals.m512i_u64[3], vals.m512i_u64[2]); + __m128i int_val2 = _mm_set_epi64x(vals.m512i_u64[5], vals.m512i_u64[4]); + __m128i int_val3 = _mm_set_epi64x(vals.m512i_u64[7], vals.m512i_u64[6]); + #else + __m128i int_val0 = _mm_set_epi64x(vals[1], vals[0]); + __m128i int_val1 = _mm_set_epi64x(vals[3], vals[2]); + __m128i int_val2 = _mm_set_epi64x(vals[5], vals[4]); + __m128i int_val3 = _mm_set_epi64x(vals[7], vals[6]); + #endif + + __m512i int32_val0 = cvtepi8_epi32(int_val0); + __m512i int32_val1 = cvtepi8_epi32(int_val1); + __m512i int32_val2 = cvtepi8_epi32(int_val2); + __m512i int32_val3 = cvtepi8_epi32(int_val3); + + #if defined(_MSC_VER) && !defined(__clang__) + __m128i int_b0 = _mm_set_epi64x(b.vals.m512i_u64[1], b.vals.m512i_u64[0]); + __m128i int_b1 = _mm_set_epi64x(b.vals.m512i_u64[3], b.vals.m512i_u64[2]); + __m128i int_b2 = _mm_set_epi64x(b.vals.m512i_u64[5], b.vals.m512i_u64[4]); + __m128i int_b3 = _mm_set_epi64x(b.vals.m512i_u64[7], b.vals.m512i_u64[6]); + #else + __m128i int_b0 = _mm_set_epi64x(b.vals[1], b.vals[0]); + __m128i int_b1 = _mm_set_epi64x(b.vals[3], b.vals[2]); + __m128i int_b2 = _mm_set_epi64x(b.vals[5], b.vals[4]); + __m128i int_b3 = _mm_set_epi64x(b.vals[7], b.vals[6]); + #endif + + __m512i int32_b0 = cvtepi8_epi32(int_b0); + __m512i int32_b1 = cvtepi8_epi32(int_b1); + __m512i int32_b2 = cvtepi8_epi32(int_b2); + __m512i int32_b3 = cvtepi8_epi32(int_b3); + + __m512i res_0 = _mm512_sub_epi32(int32_val0, int32_b0); + __m512i res_1 = _mm512_sub_epi32(int32_val1, int32_b1); + __m512i res_2 = _mm512_sub_epi32(int32_val2, int32_b2); + __m512i res_3 = _mm512_sub_epi32(int32_val3, int32_b3); + + return {Vectorized(res_0), + Vectorized(res_1), + Vectorized(res_2), + Vectorized(res_3)}; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + __m512 multiplier_v = _mm512_set1_ps(multiplier); + __m512i zero_point_v = _mm512_set1_epi32(zero_point); + return RequantizeAvx512(inp, multiplier_v, zero_point_v); + } + + private: + // Load from memory constructor + Vectorized(const void* ptr) { + vals = _mm512_loadu_si512((const __m512i*)ptr); + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template<> +struct Vectorized : public Vectorizedqi { + static constexpr int size() { + return 64; + } + + static constexpr int float_num_vecs() { + return 4; + } + + static constexpr int int_num_vecs() { + return 4; + } + + using float_vec_return_type = std::array, 4>; + using int_vec_return_type = std::array, 4>; + using value_type = typename c10::quint8::underlying; + + public: + using Vectorizedqi::Vectorizedqi; + Vectorized() {} + + Vectorized(__m512i vals_) { vals = vals_;} + + // Broadcast constructor + Vectorized(const c10::quint8& val) { + value_type uw = val.val_; + vals = _mm512_set1_epi8(uw); + } + + Vectorized(const Vectorized& other) : Vectorizedqi(other.vals) { } + + // This is added to avoid error: definition of implicit copy assignment operator + // for 'Vectorized' is deprecated because it has a user-declared + // copy constructor [-Werror,-Wdeprecated-copy] + Vectorized& operator=(const Vectorized&) = default; + + void store(void* ptr, int count = size()) const { + if (count != size()) { + memcpy(ptr, &vals, count * sizeof(value_type)); + } else { + _mm512_storeu_si512((__m512i*)ptr, vals); + } + } + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return loadu(tmp_values); + } + + private: + __m512i cvtepu8_epi32(__m128i epu8_vals) const { + return _mm512_cvtepu8_epi32(epu8_vals); + } + + public: + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_zp_premul) const { + #if defined(_MSC_VER) && !defined(__clang__) + __m128i int_val0 = _mm_set_epi64x(vals.m512i_u64[1], vals.m512i_u64[0]); + __m128i int_val1 = _mm_set_epi64x(vals.m512i_u64[3], vals.m512i_u64[2]); + __m128i int_val2 = _mm_set_epi64x(vals.m512i_u64[5], vals.m512i_u64[4]); + __m128i int_val3 = _mm_set_epi64x(vals.m512i_u64[7], vals.m512i_u64[6]); + #else + __m128i int_val0 = _mm_set_epi64x(vals[1], vals[0]); + __m128i int_val1 = _mm_set_epi64x(vals[3], vals[2]); + __m128i int_val2 = _mm_set_epi64x(vals[5], vals[4]); + __m128i int_val3 = _mm_set_epi64x(vals[7], vals[6]); + #endif + + __m512 float_val0 = _mm512_cvtepi32_ps(cvtepu8_epi32(int_val0)); + __m512 float_val1 = _mm512_cvtepi32_ps(cvtepu8_epi32(int_val1)); + __m512 float_val2 = _mm512_cvtepi32_ps(cvtepu8_epi32(int_val2)); + __m512 float_val3 = _mm512_cvtepi32_ps(cvtepu8_epi32(int_val3)); + + auto val0 = + vec::fmadd(scale, Vectorized(float_val0), scale_zp_premul); + auto val1 = + vec::fmadd(scale, Vectorized(float_val1), scale_zp_premul); + auto val2 = + vec::fmadd(scale, Vectorized(float_val2), scale_zp_premul); + auto val3 = + vec::fmadd(scale, Vectorized(float_val3), scale_zp_premul); + + return {val0, val1, val2, val3}; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + #if defined(_MSC_VER) && !defined(__clang__) + __m128i int_val0 = _mm_set_epi64x(vals.m512i_u64[1], vals.m512i_u64[0]); + __m128i int_val1 = _mm_set_epi64x(vals.m512i_u64[3], vals.m512i_u64[2]); + __m128i int_val2 = _mm_set_epi64x(vals.m512i_u64[5], vals.m512i_u64[4]); + __m128i int_val3 = _mm_set_epi64x(vals.m512i_u64[7], vals.m512i_u64[6]); + #else + __m128i int_val0 = _mm_set_epi64x(vals[1], vals[0]); + __m128i int_val1 = _mm_set_epi64x(vals[3], vals[2]); + __m128i int_val2 = _mm_set_epi64x(vals[5], vals[4]); + __m128i int_val3 = _mm_set_epi64x(vals[7], vals[6]); + #endif + + __m512 float_val0 = _mm512_cvtepi32_ps(cvtepu8_epi32(int_val0)); + __m512 float_val1 = _mm512_cvtepi32_ps(cvtepu8_epi32(int_val1)); + __m512 float_val2 = _mm512_cvtepi32_ps(cvtepu8_epi32(int_val2)); + __m512 float_val3 = _mm512_cvtepi32_ps(cvtepu8_epi32(int_val3)); + + auto val0 = (Vectorized(float_val0) - zero_point) * scale; + auto val1 = (Vectorized(float_val1) - zero_point) * scale; + auto val2 = (Vectorized(float_val2) - zero_point) * scale; + auto val3 = (Vectorized(float_val3) - zero_point) * scale; + + return {val0, val1, val2, val3}; + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale) { + auto* rhs_data = (float*)rhs.data(); + uint8_t quantized_values[64]; + QuantizeAvx512( + rhs_data, quantized_values, 64, inverse_scale, zero_point); + return Vectorized::loadu(quantized_values); + } + + Vectorized maximum(Vectorized b) const { + return _mm512_max_epu8(vals, b.vals); + } + + Vectorized minimum(Vectorized b) const { + return _mm512_min_epu8(vals, b.vals); + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + return _mm512_min_epu8( + _mm512_max_epu8(vals, zero_point.vals), q_six.vals); + } + + int_vec_return_type widening_subtract(Vectorized b) const { + #if defined(_MSC_VER) && !defined(__clang__) + __m128i int_val0 = _mm_set_epi64x(vals.m512i_u64[1], vals.m512i_u64[0]); + __m128i int_val1 = _mm_set_epi64x(vals.m512i_u64[3], vals.m512i_u64[2]); + __m128i int_val2 = _mm_set_epi64x(vals.m512i_u64[5], vals.m512i_u64[4]); + __m128i int_val3 = _mm_set_epi64x(vals.m512i_u64[7], vals.m512i_u64[6]); + #else + __m128i int_val0 = _mm_set_epi64x(vals[1], vals[0]); + __m128i int_val1 = _mm_set_epi64x(vals[3], vals[2]); + __m128i int_val2 = _mm_set_epi64x(vals[5], vals[4]); + __m128i int_val3 = _mm_set_epi64x(vals[7], vals[6]); + #endif + + __m512i int32_val0 = cvtepu8_epi32(int_val0); + __m512i int32_val1 = cvtepu8_epi32(int_val1); + __m512i int32_val2 = cvtepu8_epi32(int_val2); + __m512i int32_val3 = cvtepu8_epi32(int_val3); + + #if defined(_MSC_VER) && !defined(__clang__) + __m128i int_b0 = _mm_set_epi64x(b.vals.m512i_u64[1], b.vals.m512i_u64[0]); + __m128i int_b1 = _mm_set_epi64x(b.vals.m512i_u64[3], b.vals.m512i_u64[2]); + __m128i int_b2 = _mm_set_epi64x(b.vals.m512i_u64[5], b.vals.m512i_u64[4]); + __m128i int_b3 = _mm_set_epi64x(b.vals.m512i_u64[7], b.vals.m512i_u64[6]); + #else + __m128i int_b0 = _mm_set_epi64x(b.vals[1], b.vals[0]); + __m128i int_b1 = _mm_set_epi64x(b.vals[3], b.vals[2]); + __m128i int_b2 = _mm_set_epi64x(b.vals[5], b.vals[4]); + __m128i int_b3 = _mm_set_epi64x(b.vals[7], b.vals[6]); + #endif + + __m512i int32_b0 = cvtepu8_epi32(int_b0); + __m512i int32_b1 = cvtepu8_epi32(int_b1); + __m512i int32_b2 = cvtepu8_epi32(int_b2); + __m512i int32_b3 = cvtepu8_epi32(int_b3); + + __m512i res_0 = _mm512_sub_epi32(int32_val0, int32_b0); + __m512i res_1 = _mm512_sub_epi32(int32_val1, int32_b1); + __m512i res_2 = _mm512_sub_epi32(int32_val2, int32_b2); + __m512i res_3 = _mm512_sub_epi32(int32_val3, int32_b3); + return {Vectorized(res_0), + Vectorized(res_1), + Vectorized(res_2), + Vectorized(res_3)}; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + __m512 multiplier_v = _mm512_set1_ps(multiplier); + __m512i zero_point_v = _mm512_set1_epi32(zero_point); + return RequantizeAvx512(inp, multiplier_v, zero_point_v); + } + + private: + + // Load from memory constructor + Vectorized(const void* ptr) { + vals = _mm512_loadu_si512((const __m512i*)ptr); + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +#else + +// NOTE: These are low-performance implementations that we fall back on. + +template < + typename T, + typename float_vec_return_type_, + typename int_vec_return_type_, + int size_> +struct VectorizedQuantizedConverter { + static constexpr int size() { + return size_; + } + + static constexpr int float_num_vecs() { + return size() / 8; + } + + static constexpr int int_num_vecs() { + return size() / 8; + } + + using float_vec_return_type = float_vec_return_type_; + using int_vec_return_type = int_vec_return_type_; + + using value_type = typename T::underlying; + std::array vals; + + VectorizedQuantizedConverter(T val) { + for (const auto i : c10::irange(size())) { + vals[i] = val.val_; + } + } + + VectorizedQuantizedConverter(const void* ptr) { + memcpy(vals.data(), ptr, sizeof(value_type) * size()); + } + + void store(void* ptr, int count = size()) const { + memcpy(ptr, vals.data(), count * sizeof(value_type)); + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point, + Vectorized scale_zp_premul [[maybe_unused]]) const { + float_vec_return_type rv; + for (const auto i : c10::irange(float_num_vecs())) { + float tmp_vals[16]; + for (const auto j : c10::irange(16)) { + tmp_vals[j] = at::native::dequantize_val( + scale[j], zero_point[j], T(vals[16 * i + j])); + } + rv[i] = Vectorized(tmp_vals[0], + tmp_vals[1], + tmp_vals[2], + tmp_vals[3], + tmp_vals[4], + tmp_vals[5], + tmp_vals[6], + tmp_vals[7], + tmp_vals[8], + tmp_vals[9], + tmp_vals[10], + tmp_vals[11], + tmp_vals[12], + tmp_vals[13], + tmp_vals[14], + tmp_vals[15]); + } + return rv; + } + + float_vec_return_type dequantize( + Vectorized scale, + Vectorized zero_point) const { + Vectorized scale_zp_premul; + return dequantize(scale, zero_point, scale_zp_premul); + } + + protected: + VectorizedQuantizedConverter() {} +}; + +template <> +struct Vectorized : public VectorizedQuantizedConverter< + c10::qint32, + std::array, 1>, + std::array, 1>, + 16> { + Vectorized() + : VectorizedQuantizedConverter< + c10::qint32, + std::array, 1>, + std::array, 1>, + 16>() {} + Vectorized(c10::qint32 val) + : VectorizedQuantizedConverter< + c10::qint32, + std::array, 1>, + std::array, 1>, + 16>(val) {} + Vectorized(const void* ptr) + : VectorizedQuantizedConverter< + c10::qint32, + std::array, 1>, + std::array, 1>, + 16>(ptr) {} + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return loadu(tmp_values); + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale [[maybe_unused]]) { + std::array qvals; + std::array float_vals; + + for (const auto i : c10::irange(float_num_vecs())) { + rhs[i].store(&float_vals[i * 16], 16); + } + + at::native::quantize_vec( + scale, + zero_point, + float_vals.data(), + (c10::qint32*)qvals.data(), + 16 * float_num_vecs()); + + return Vectorized::loadu(qvals.data()); + } + + Vectorized maximum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::max(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized minimum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min( + std::max(vals[i], zero_point.vals[i]), q_six.vals[i]); + } + return retval; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + int_vec_return_type retval; + for (const auto i : c10::irange(size())) { + retval[0].vals[i] = vals[i] - b.vals[i]; + } + return retval; + } + + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = + std::nearbyint(static_cast(inp[0].vals[i]) * multiplier) + + zero_point; + } + return retval; + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template <> +Vectorized inline operator*( + const Vectorized& a, + const Vectorized& b) { + Vectorized retval; + for (const auto i : c10::irange(std::decay_t::size())) { + retval.vals[i] = a.vals[i] * b.vals[i]; + } + return retval; +} + +template <> +Vectorized inline operator+( + const Vectorized& a, + const Vectorized& b) { + Vectorized retval; + for (const auto i : c10::irange(std::decay_t::size())) { + retval.vals[i] = a.vals[i] + b.vals[i]; + } + return retval; +} + +template <> +struct Vectorized : public VectorizedQuantizedConverter< + c10::qint8, + std::array, 4>, + std::array, 4>, + 64> { + Vectorized() + : VectorizedQuantizedConverter< + c10::qint8, + std::array, 4>, + std::array, 4>, + 64>() {} + Vectorized(c10::qint8 val) + : VectorizedQuantizedConverter< + c10::qint8, + std::array, 4>, + std::array, 4>, + 64>(val) {} + Vectorized(const void* ptr) + : VectorizedQuantizedConverter< + c10::qint8, + std::array, 4>, + std::array, 4>, + 64>(ptr) {} + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return loadu(tmp_values); + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale [[maybe_unused]]) { + std::array qvals; + std::array float_vals; + + for (const auto i : c10::irange(float_num_vecs())) { + rhs[i].store(&float_vals[i * 16], 16); + } + + at::native::quantize_vec( + scale, + zero_point, + float_vals.data(), + (c10::qint8*)qvals.data(), + 16 * float_num_vecs()); + + return Vectorized::loadu(qvals.data()); + } + + Vectorized maximum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::max(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized minimum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min( + std::max(vals[i], zero_point.vals[i]), q_six.vals[i]); + } + return retval; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + int_vec_return_type retval; + constexpr int elem_per_int_vec = size() / int_num_vecs(); + for (const auto i : c10::irange(int_num_vecs())) { + for (const auto j : c10::irange(elem_per_int_vec)) { + retval[i].vals[j] = + static_cast(vals[i * elem_per_int_vec + j]) - + static_cast(b.vals[i * elem_per_int_vec + j]); + } + } + return retval; + } + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + constexpr int elem_per_int_vec = size() / int_num_vecs(); + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + Vectorized retval; + for (const auto i : c10::irange(int_num_vecs())) { + for (const auto j : c10::irange(elem_per_int_vec)) { + int32_t rounded = + std::nearbyint(static_cast(inp[i].vals[j]) * multiplier) + + zero_point; + retval.vals[i * elem_per_int_vec + j] = + std::min(std::max(rounded, min_val), max_val); + } + } + return retval; + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +template <> +struct Vectorized : public VectorizedQuantizedConverter< + c10::quint8, + std::array, 4>, + std::array, 4>, + 64> { + Vectorized() + : VectorizedQuantizedConverter< + c10::quint8, + std::array, 4>, + std::array, 4>, + 64>() {} + Vectorized(c10::quint8 val) + : VectorizedQuantizedConverter< + c10::quint8, + std::array, 4>, + std::array, 4>, + 64>(val) {} + Vectorized(const void* ptr) + : VectorizedQuantizedConverter< + c10::quint8, + std::array, 4>, + std::array, 4>, + 64>(ptr) {} + + static Vectorized loadu(const void* ptr) { + return Vectorized(ptr); + } + + static Vectorized loadu(const void* ptr, int64_t count) { + __at_align__ value_type tmp_values[size()]; + // Ensure uninitialized memory does not change the output value See https://github.com/pytorch/pytorch/issues/32502 + // for more details. We do not initialize arrays to zero using "={0}" because gcc would compile it to two + // instructions while a loop would be compiled to one instruction. + for (const auto i : c10::irange(size())) { + tmp_values[i] = 0; + } + std::memcpy(tmp_values, reinterpret_cast(ptr), count * sizeof(value_type)); + return loadu(tmp_values); + } + + static Vectorized quantize( + const float_vec_return_type& rhs, + float scale, + int32_t zero_point, + float inverse_scale [[maybe_unused]]) { + std::array qvals; + std::array float_vals; + + for (const auto i : c10::irange(float_num_vecs())) { + rhs[i].store(&float_vals[i * 16], 16); + } + + at::native::quantize_vec( + scale, + zero_point, + float_vals.data(), + (c10::quint8*)qvals.data(), + 16 * float_num_vecs()); + + return Vectorized::loadu(qvals.data()); + } + + Vectorized maximum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::max(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized minimum(Vectorized b) const { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min(vals[i], b.vals[i]); + } + return retval; + } + + Vectorized relu(Vectorized zero_point) const { + return maximum(zero_point); + } + + + Vectorized relu6( + Vectorized zero_point, + Vectorized q_six) { + Vectorized retval; + for (const auto i : c10::irange(size())) { + retval.vals[i] = std::min( + std::max(vals[i], zero_point.vals[i]), q_six.vals[i]); + } + return retval; + } + + int_vec_return_type widening_subtract(Vectorized b) const { + int_vec_return_type retval; + constexpr int elem_per_int_vec = size() / int_num_vecs(); + for (const auto i : c10::irange(int_num_vecs())) { + for (const auto j : c10::irange(elem_per_int_vec)) { + retval[i].vals[j] = + static_cast(vals[i * elem_per_int_vec + j]) - + static_cast(b.vals[i * elem_per_int_vec + j]); + } + } + return retval; + } + static Vectorized requantize_from_int( + const int_vec_return_type& inp, + float multiplier, + int32_t zero_point) { + constexpr int elem_per_int_vec = size() / int_num_vecs(); + constexpr auto min_val = std::numeric_limits::min(); + constexpr auto max_val = std::numeric_limits::max(); + Vectorized retval; + for (const auto i : c10::irange(int_num_vecs())) { + for (const auto j : c10::irange(elem_per_int_vec)) { + int32_t rounded = + std::nearbyint(static_cast(inp[i].vals[j]) * multiplier) + + zero_point; + retval.vals[i * elem_per_int_vec + j] = + std::min(std::max(rounded, min_val), max_val); + } + } + return retval; + } +}; + +template <> +Vectorized inline maximum(const Vectorized& a, const Vectorized& b) { + return a.maximum(b); +} + +#endif // defined(CPU_CAPABILITY_AVX512) && !defined(MSVC) + +}}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_base.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_base.h new file mode 100644 index 0000000000000000000000000000000000000000..2591338881aef150770e4c2ed52cd7e1f1e59a2c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_base.h @@ -0,0 +1,1200 @@ +#pragma once +#if defined(__GNUC__) && __GNUC__ == 10 && __GNUC_MINOR__ <= 2 && defined(__ARM_FEATURE_SVE) +// Workaround for https: //gcc.gnu.org/bugzilla/show_bug.cgi?id=117161 +#pragma GCC optimize("no-tree-vectorize") +#endif + +// DO NOT DEFINE STATIC DATA IN THIS HEADER! +// See Note [Do not compile initializers with AVX] +// +// Note [Do not compile initializers with AVX] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// If you define a static initializer in this file, the initialization will use +// AVX instructions because these object files are compiled with AVX enabled. +// We need to avoid non-trivial global data in these architecture specific files +// because there's no way to guard the global initializers with CPU capability +// detection. +// +// See https://github.com/pytorch/pytorch/issues/37577 for an instance +// of this bug in the past. + +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#if defined(__GNUC__) +#define __FORCE_INLINE __attribute__((always_inline)) inline +#elif defined(_MSC_VER) +#define __FORCE_INLINE __forceinline +#endif + +#if defined(_MSC_FULL_VER) +/* +https://learn.microsoft.com/en-us/cpp/overview/compiler-versions?view=msvc-170 +Use _MSC_FULL_VER to identify current compiler is msvc, +Windows llvm will not have this definition. +*/ +#define __msvc_cl__ +#endif + +// These macros helped us unify vec_base.h +#ifdef CPU_CAPABILITY_AVX512 +#if defined(__GNUC__) +#define __at_align__ __attribute__((aligned(64))) +#elif defined(_WIN32) +#define __at_align__ __declspec(align(64)) +#else +#define __at_align__ +#endif +#define VECTOR_WIDTH 64 +#define int_vector __m512i +#elif defined(__aarch64__) && !defined(CPU_CAPABILITY_SVE) // CPU_CAPABILITY_AVX512 +// SVE code expects 256-vectors; leave that set for SVE? +#if defined(__GNUC__) +#define __at_align__ __attribute__((aligned(16))) +#elif defined(_WIN32) +#define __at_align__ __declspec(align(16)) +#else +#define __at_align__ +#endif +#define VECTOR_WIDTH 16 +#else // CPU_CAPABILITY_AVX512 +#if defined(__GNUC__) +#define __at_align__ __attribute__((aligned(32))) +#elif defined(_WIN32) +#define __at_align__ __declspec(align(32)) +#else +#define __at_align__ +#endif +#define VECTOR_WIDTH 32 +#define int_vector __m256i +#endif // CPU_CAPABILITY_AVX512 + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { +// at::Half and at::BFloat16 should be treated as floating point +template +struct is_floating_point: + std::integral_constant || + std::is_same_v || + std::is_same_v> { +}; + +template +constexpr bool is_floating_point_v = is_floating_point::value; + +template +struct is_reduced_floating_point: + std::integral_constant || + std::is_same_v> { +}; + +template +constexpr bool is_reduced_floating_point_v = is_reduced_floating_point::value; + +template +struct is_8bit_integer: + std::integral_constant || + std::is_same_v> { +}; + +template +constexpr bool is_8bit_integer_v = is_8bit_integer::value; + +template struct int_of_size; + +#define DEFINE_INT_OF_SIZE(int_t) \ +template<> struct int_of_size { using type = int_t; } + +DEFINE_INT_OF_SIZE(int64_t); +DEFINE_INT_OF_SIZE(int32_t); +DEFINE_INT_OF_SIZE(int16_t); +DEFINE_INT_OF_SIZE(int8_t); + +#undef DEFINE_INT_OF_SIZE + +template +using int_same_size_t = typename int_of_size::type; + +// NOTE: If you specialize on a type, you must define all operations! + +// emulates Vectorized types +#if defined(__s390x__) +template +#else +template +#endif +struct Vectorized { +private: + __at_align__ T values[VECTOR_WIDTH / sizeof(T)]; +public: + using value_type = T; + using size_type = int; + + static constexpr size_type kSize = VECTOR_WIDTH / sizeof(T); + static constexpr size_type size() { + return kSize; + } + Vectorized() : values{static_cast(0)} {} + Vectorized(T val) { + for (int i = 0; i != size(); i++) { + values[i] = val; + } + } + template> + Vectorized(Args... vals) : values{vals...}{ + } + Vectorized(const T(&arr)[kSize]) { + std::memcpy(values, arr, sizeof(values)); + } + // This also implies const T& operator[](int idx) const + inline operator const T*() const { + return values; + } + // This also implies T& operator[](int idx) + inline operator T*() { + return values; + } + // Return the values as char* for type punning + auto as_bytes() const -> const char* { + return reinterpret_cast(values); + } + template + static Vectorized blend(const Vectorized& a, const Vectorized& b) { + int64_t mask = mask_; + Vectorized vector; + for (const auto i : c10::irange(size())) { + if (mask & 0x01) { + vector[i] = b[i]; + } else { + vector[i] = a[i]; + } + mask = mask >> 1; + } + return vector; + } +// Workaround for https: //gcc.gnu.org/bugzilla/show_bug.cgi?id=117001 +#if __GNUC__ <= 12 && !defined(__clang__) && defined(__ARM_FEATURE_SVE) + static Vectorized __attribute__ ((optimize("-fno-tree-loop-vectorize"))) blendv(const Vectorized& a, +#else + static Vectorized blendv(const Vectorized& a, +#endif + const Vectorized& b, const Vectorized& mask) { + Vectorized vector; + int_same_size_t buffer[size()]; + mask.store(buffer); +#if defined(__clang__) && __ARM_FEATURE_SVE + #pragma clang loop vectorize(disable) +#endif + for (const auto i : c10::irange(size())) { + if (buffer[i] & 0x01) + { + vector[i] = b[i]; + } else { + vector[i] = a[i]; + } + } + return vector; + } + template // step sometimes requires a higher precision type (e.g., T=int, step_t=double) + static Vectorized arange(T base = static_cast(0), step_t step = static_cast(1)) { + Vectorized vector; + for (const auto i : c10::irange(size())) { + vector.values[i] = base + i * step; + } + return vector; + } + static Vectorized set(const Vectorized& a, const Vectorized& b, int64_t count = size()) { + Vectorized vector; + for (const auto i : c10::irange(size())) { + if (i < count) { + vector[i] = b[i]; + } else { + vector[i] = a[i]; + } + } + return vector; + } + static Vectorized loadu(const void* ptr) { + Vectorized vector; + std::memcpy(vector.values, ptr, VECTOR_WIDTH); + return vector; + } + static Vectorized loadu(const void* ptr, int64_t count) { + Vectorized vector; + std::memcpy(vector.values, ptr, count * sizeof(T)); + return vector; + } + static Vectorized loadu_one_fourth(const void* ptr) { + static_assert(std::is_same_v || std::is_same_v, "For byte types only"); + return Vectorized::loadu(ptr, 8); + } + + void store(void* ptr, int count = size()) const { + std::memcpy(ptr, values, count * sizeof(T)); + } + int zero_mask() const { + // returns an integer mask where all zero elements are translated to 1-bit and others are translated to 0-bit + int mask = 0; + for (int i = 0; i < size(); ++ i) { + if (values[i] == static_cast(0)) { + mask |= (1 << i); + } + } + return mask; + } + Vectorized isnan() const { + Vectorized vector; + for (int64_t i = 0; i != size(); i++) { + if (_isnan(values[i])) { + std::memset(static_cast(vector.values + i), 0xFF, sizeof(T)); + } else { + std::memset(static_cast(vector.values + i), 0, sizeof(T)); + } + } + return vector; + } + bool has_inf_nan() const { + for (int64_t i = 0; i != size(); i++) { + if(_isnan(values[i]) || _isinf(values[i])) { + return true; + } + } + return false; + } +// MSVC versions between 14.36 and 14.42 has a loop unrolling bug on Windows Arm64 +// See https://developercommunity.visualstudio.com/t/MSVC-loop-unrolling-problem-194033813-/10720692 +#if defined(_WIN32) && defined(__aarch64__) && ((_MSVC_VER >= 1936) && (_MSVC_VER <= 1942)) + Vectorized map(T (*const f)(T)) const { + Vectorized ret; + for (int64_t i = 0; i < size(); i++) { + ret[i] = f(values[i]); + if (++i < size()) + ret[i] = f(values[i]); + } + return ret; + } + T reduce(T (*const f)(T)) const { + T ret = 0; + for (int64_t i = 0; i < size(); i++) { + ret = f(ret, values[i]); + if (++i < size()) + ret = f(ret, values[i]); + } + return ret; + } +#else + Vectorized map(T (*const f)(T)) const { + Vectorized ret; + for (int64_t i = 0; i != size(); i++) { + ret[i] = f(values[i]); + } + return ret; + } + T reduce(T (*const f)(T)) const { + T ret = 0; + for (int64_t i = 0; i != size(); i++) { + ret = f(ret, values[i]); + } + return ret; + } +#endif + Vectorized map(T (*const f)(const T &)) const { + Vectorized ret; + for (int64_t i = 0; i != size(); i++) { + ret[i] = f(values[i]); + } + return ret; + } + T reduce(T (*const f)(const T &)) const { + T ret = 0; + for (int64_t i = 0; i != size(); i++) { + ret = f(ret, values[i]); + } + return ret; + } + template && !c10::is_complex::value, int> = 0> + Vectorized abs() const { + // other_t_abs is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "other_t_abs must be T"); + return map([](T x) -> T { return x < static_cast(0) ? -x : x; }); + } + template , int> = 0> + Vectorized abs() const { + // float_t_abs is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "float_t_abs must be T"); + // Specifically deal with floating-point because the generic code above won't handle -0.0 (which should result in + // 0.0) properly. + return map([](T x) -> T { return std::abs(x); }); + } + template ::value, int> = 0> + Vectorized abs() const { + // complex_t_abs is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "complex_t_abs must be T"); + // Specifically map() does not perform the type conversion needed by abs. + return map([](T x) { return static_cast(std::abs(x)); }); + } + + template ::value, int> = 0> + Vectorized sgn() const { + return map(at::native::sgn_impl); + } + + template ::value, int> = 0> + Vectorized angle() const { + // other_t_angle is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "other_t_angle must be T"); + return map(at::native::angle_impl); // compiler is unable to resolve the overload without + } + template ::value, int> = 0> + Vectorized angle() const { + // complex_t_angle is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "complex_t_angle must be T"); + return map([](T x) { return static_cast(std::arg(x)); }); + } + template ::value, int> = 0> + Vectorized real() const { + // other_t_real is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "other_t_real must be T"); + return *this; + } + template ::value, int> = 0> + Vectorized real() const { + // complex_t_real is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "complex_t_real must be T"); + return map([](T x) { return static_cast(x.real()); }); + } + template ::value, int> = 0> + Vectorized imag() const { + // other_t_imag is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "other_t_imag must be T"); + return Vectorized(0); + } + template ::value, int> = 0> + Vectorized imag() const { + // complex_t_imag is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "complex_t_imag must be T"); + return map([](T x) { return static_cast(x.imag()); }); + } + template ::value, int> = 0> + Vectorized conj() const { + // other_t_conj is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "other_t_conj must be T"); + return *this; + } + template ::value, int> = 0> + Vectorized conj() const { + // complex_t_conj is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "complex_t_conj must be T"); + return map([](T x) { return static_cast(std::conj(x)); }); + } + Vectorized acos() const { + return map(std::acos); + } + Vectorized acosh() const { + return map(std::acosh); + } + Vectorized asin() const { + return map(std::asin); + } + Vectorized asinh() const { + return map(std::asinh); + } + Vectorized atan() const { + return map(std::atan); + } + Vectorized atanh() const { + return map(std::atanh); + } + Vectorized atan2(const Vectorized &exp) const { + Vectorized ret; + for (const auto i : c10::irange(size())) { + ret[i] = std::atan2(values[i], exp[i]); + } + return ret; + } + template < + typename U = T, + typename std::enable_if_t, int> = 0> + Vectorized copysign(const Vectorized &sign) const { + Vectorized ret; + for (size_type i = 0; i < size(); i++) { + ret[i] = c10::copysign(values[i], sign[i]); + } + return ret; + } + Vectorized erf() const { + return map(std::erf); + } + Vectorized erfc() const { + return map(std::erfc); + } + Vectorized erfinv() const { + return map(calc_erfinv); + } + Vectorized exp() const { + return map(std::exp); + } + Vectorized exp2() const { + return map(exp2_impl); + } + Vectorized expm1() const { + return map(std::expm1); + } + Vectorized exp_u20() const { + return map(std::exp); + } + Vectorized frac() const { + return *this - this->trunc(); + } + template < + typename U = T, + typename std::enable_if_t, int> = 0> + Vectorized fmod(const Vectorized& q) const { + // U is for SFINAE purposes only. Make sure it is not changed. + static_assert(std::is_same_v, "U must be T"); + Vectorized ret; + for (const auto i : c10::irange(size())) { + ret[i] = std::fmod(values[i], q[i]); + } + return ret; + } + Vectorized log() const { + return map(std::log); + } + Vectorized log10() const { + return map(std::log10); + } + Vectorized log1p() const { + return map(std::log1p); + } + template ::value, int> = 0> + Vectorized log2() const { + // other_t_log2 is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "other_t_log2 must be T"); + return map(std::log2); + } + template ::value, int> = 0> + Vectorized log2() const { + // complex_t_log2 is for SFINAE and clarity. Make sure it is not changed. + static_assert(std::is_same_v, "complex_t_log2 must be T"); + const T log_2 = T(std::log(2.0)); + return Vectorized(map(std::log))/Vectorized(log_2); + } + Vectorized ceil() const { + return map(at::native::ceil_impl); + } + Vectorized cos() const { + return map(std::cos); + } + Vectorized cosh() const { + return map(std::cosh); + } + Vectorized floor() const { + return map(at::native::floor_impl); + } + Vectorized hypot(const Vectorized &b) const { + Vectorized ret; + for (const auto i : c10::irange(size())) { + ret[i] = std::hypot(values[i], b[i]); + } + return ret; + } + Vectorized i0() const { + return map(calc_i0); + } + Vectorized i0e() const { + return map(calc_i0e); + } + Vectorized digamma() const { + return map(calc_digamma); + } + Vectorized igamma(const Vectorized &x) const { + Vectorized ret; + for (const auto i : c10::irange(size())) { + ret[i] = calc_igamma(values[i], x[i]); + } + return ret; + } + Vectorized igammac(const Vectorized &x) const { + Vectorized ret; + for (const auto i : c10::irange(size())) { + ret[i] = calc_igammac(values[i], x[i]); + } + return ret; + } + Vectorized neg() const { + // NB: the trailing return type is needed because we need to coerce the + // return value back to T in the case of unary operator- incuring a + // promotion + return map([](T x) -> T { return -x; }); + } + Vectorized nextafter(const Vectorized &b) const { + Vectorized ret; + for (const auto i : c10::irange(size())) { + ret[i] = std::nextafter(values[i], b[i]); + } + return ret; + } + Vectorized round() const { + // We do not use std::round because we would like to round midway numbers to the nearest even integer. + return map(at::native::round_impl); + } + Vectorized sin() const { + return map(std::sin); + } + Vectorized sinh() const { + return map(std::sinh); + } + Vectorized tan() const { + return map(std::tan); + } + Vectorized tanh() const { + return map(std::tanh); + } + Vectorized trunc() const { + return map(at::native::trunc_impl); + } + Vectorized lgamma() const { + return map(std::lgamma); + } + Vectorized sqrt() const { + return map(std::sqrt); + } + Vectorized reciprocal() const { + return map([](T x) { return (T)(1) / x; }); + } + Vectorized rsqrt() const { + return map([](T x) { return (T)1 / std::sqrt(x); }); + } + Vectorized pow(const Vectorized &exp) const { + Vectorized ret; + for (const auto i : c10::irange(size())) { + ret[i] = std::pow(values[i], exp[i]); + } + return ret; + } + T reduce_add() const { + return reduce([](T x, T y) -> T { return x + y; }); + } + T reduce_max() const { + return reduce(std::max); + } +private: + template + inline Vectorized binary_pred(const Vectorized& other, Op op) const { + // All bits are set to 1 if the pred is true, otherwise 0. + Vectorized vector; + for (int64_t i = 0; i != size(); i++) { + if (op(values[i], other.values[i])) { + std::memset(static_cast(vector.values + i), 0xFF, sizeof(T)); + } else { + std::memset(static_cast(vector.values + i), 0, sizeof(T)); + } + } + return vector; + } + +public: + Vectorized operator==(const Vectorized& other) const { return binary_pred(other, std::equal_to()); } + Vectorized operator!=(const Vectorized& other) const { return binary_pred(other, std::not_equal_to()); } + Vectorized operator>=(const Vectorized& other) const { return binary_pred(other, std::greater_equal()); } + Vectorized operator<=(const Vectorized& other) const { return binary_pred(other, std::less_equal()); } + Vectorized operator>(const Vectorized& other) const { return binary_pred(other, std::greater()); } + Vectorized operator<(const Vectorized& other) const { return binary_pred(other, std::less()); } + +private: + template + inline Vectorized binary_pred_bool(const Vectorized& other, Op op) const { + // 1 if the pred is true, otherwise 0. + Vectorized vector; + for (int i = 0; i != size(); ++ i) { + vector[i] = static_cast(op(values[i], other.values[i])); + } + return vector; + } + +public: + Vectorized eq(const Vectorized& other) const { return binary_pred_bool(other, std::equal_to()); } + Vectorized ne(const Vectorized& other) const { return binary_pred_bool(other, std::not_equal_to()); } + Vectorized gt(const Vectorized& other) const { return binary_pred_bool(other, std::greater()); } + Vectorized ge(const Vectorized& other) const { return binary_pred_bool(other, std::greater_equal()); } + Vectorized lt(const Vectorized& other) const { return binary_pred_bool(other, std::less()); } + Vectorized le(const Vectorized& other) const { return binary_pred_bool(other, std::less_equal()); } +}; + +template Vectorized inline operator+(const Vectorized &a, const Vectorized &b) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = a[i] + b[i]; + } + return c; +} + +template Vectorized inline operator-(const Vectorized &a, const Vectorized &b) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = a[i] - b[i]; + } + return c; +} + +template Vectorized inline operator*(const Vectorized &a, const Vectorized &b) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = a[i] * b[i]; + } + return c; +} + +template Vectorized inline operator/(const Vectorized &a, const Vectorized &b) __ubsan_ignore_float_divide_by_zero__ { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = a[i] / b[i]; + } + return c; +} + +template , int> = 0> +Vectorized inline operator%(const Vectorized &a, const Vectorized &b) __ubsan_ignore_float_divide_by_zero__ { + return a - a / b * b; +} + +template Vectorized inline operator||( + const Vectorized &a, const Vectorized &b) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = a[i] || b[i]; + } + return c; +} + +// Implements the IEEE 754 201X `maximum` operation, which propagates NaN if +// either input is a NaN. +template ::value, int> = 0> +Vectorized inline maximum(const Vectorized &a, const Vectorized &b) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = (a[i] > b[i]) ? a[i] : b[i]; + if (_isnan(a[i])) { + // If either input is NaN, propagate a NaN. + // NOTE: The case where b[i] was NaN is handled correctly by the naive + // ternary operator above. + c[i] = a[i]; + } + } + return c; +} + +template ::value, int> = 0> +Vectorized inline maximum(const Vectorized &a, const Vectorized &b) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = (std::abs(a[i]) > std::abs(b[i])) ? a[i] : b[i]; + if (_isnan(a[i])) { + // If either input is NaN, propagate a NaN. + // NOTE: The case where b[i] was NaN is handled correctly by the naive + // ternary operator above. + c[i] = a[i]; + } + } + return c; +} + +// Implements the IEEE 754 201X `minimum` operation, which propagates NaN if +// either input is a NaN. +template ::value, int> = 0> +Vectorized inline minimum(const Vectorized &a, const Vectorized &b) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = (a[i] < b[i]) ? a[i] : b[i]; + if (_isnan(a[i])) { + // If either input is NaN, propagate a NaN. + // NOTE: The case where b[i] was NaN is handled correctly by the naive + // ternary operator above. + c[i] = a[i]; + } + } + return c; +} + +template ::value, int> = 0> +Vectorized inline minimum(const Vectorized &a, const Vectorized &b) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = (std::abs(a[i]) < std::abs(b[i])) ? a[i] : b[i]; + if (_isnan(a[i])) { + // If either input is NaN, propagate a NaN. + // NOTE: The case where b[i] was NaN is handled correctly by the naive + // ternary operator above. + c[i] = a[i]; + } + } + return c; +} + +template ::value, int> = 0> +Vectorized inline clamp(const Vectorized &a, const Vectorized &min_vec, const Vectorized &max_vec) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = std::min(std::max(a[i], min_vec[i]), max_vec[i]); + } + return c; +} + +template ::value, int> = 0> +Vectorized inline clamp_max(const Vectorized &a, const Vectorized &max_vec) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = a[i] > max_vec[i] ? max_vec[i] : a[i]; + } + return c; +} + +template ::value, int> = 0> +Vectorized inline clamp_min(const Vectorized &a, const Vectorized &min_vec) { + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + c[i] = a[i] < min_vec[i] ? min_vec[i] : a[i]; + } + return c; +} + +struct Vectorizedi; + +#if defined(CPU_CAPABILITY_AVX2) || defined(CPU_CAPABILITY_AVX512) +template +static inline Vectorized bitwise_binary_op(const Vectorized &a, const Vectorized &b, Op op) { + int_vector buffer; +#if defined(CPU_CAPABILITY_AVX2) + int_vector a_buffer = _mm256_load_si256(reinterpret_cast((const T*)a)); + int_vector b_buffer = _mm256_load_si256(reinterpret_cast((const T*)b)); +#elif defined(CPU_CAPABILITY_AVX512) + int_vector a_buffer = _mm512_load_si512(reinterpret_cast((const T*)a)); + int_vector b_buffer = _mm512_load_si512(reinterpret_cast((const T*)b)); +#endif + buffer = op(a_buffer, b_buffer); + __at_align__ T results[Vectorized::size()]; + +#if defined(CPU_CAPABILITY_AVX2) + _mm256_store_si256(reinterpret_cast(results), buffer); +#elif defined(CPU_CAPABILITY_AVX512) + _mm512_store_si512(reinterpret_cast(results), buffer); +#endif + return Vectorized::loadu(results); +} + +template>::value, int> = 0> +inline Vectorized operator&(const Vectorized& a, const Vectorized& b) { + // We enclose _mm512_and_si512 or _mm256_and_si256 with lambda because it is always_inline +#if defined(CPU_CAPABILITY_AVX2) + return bitwise_binary_op(a, b, [](int_vector a, int_vector b) { return _mm256_and_si256(a, b); }); +#elif defined(CPU_CAPABILITY_AVX512) + return bitwise_binary_op(a, b, [](int_vector a, int_vector b) { return _mm512_and_si512(a, b); }); +#endif +} +template>::value, int> = 0> +inline Vectorized operator|(const Vectorized& a, const Vectorized& b) { + // We enclose _mm512_or_si512 or _mm256_or_si256 with lambda because it is always_inline +#if defined(CPU_CAPABILITY_AVX2) + return bitwise_binary_op(a, b, [](int_vector a, int_vector b) { return _mm256_or_si256(a, b); }); +#elif defined(CPU_CAPABILITY_AVX512) + return bitwise_binary_op(a, b, [](int_vector a, int_vector b) { return _mm512_or_si512(a, b); }); +#endif +} +template>::value, int> = 0> +inline Vectorized operator^(const Vectorized& a, const Vectorized& b) { + // We enclose _mm512_xor_si512 or _mm256_xor_si256 with lambda because it is always_inline +#if defined(CPU_CAPABILITY_AVX2) + return bitwise_binary_op(a, b, [](int_vector a, int_vector b) { return _mm256_xor_si256(a, b); }); +#elif defined(CPU_CAPABILITY_AVX512) + return bitwise_binary_op(a, b, [](int_vector a, int_vector b) { return _mm512_xor_si512(a, b); }); +#endif +} + +#else + +template +auto load(char const* data) -> T { + T ret; + std::memcpy(&ret, data, sizeof(ret)); + return ret; +} + +template +static inline Vectorized bitwise_binary_op(const Vectorized &a, const Vectorized &b, Op op) { + static constexpr uint32_t element_no = VECTOR_WIDTH / sizeof(intmax_t); + __at_align__ intmax_t buffer[element_no]; + static_assert(VECTOR_WIDTH % sizeof(intmax_t) == 0, "VECTOR_WIDTH not a multiple of sizeof(intmax_t)"); + static_assert(sizeof(buffer) == sizeof(Vectorized), "sizeof(buffer) must match sizeof(Vectorized)"); + // We should be using memcpy in order to respect the strict aliasing rule + // see: https://github.com/pytorch/pytorch/issues/66119 + // Using char* is defined in the C11 standard 6.5 Expression paragraph 7 + // (http://www.open-std.org/jtc1/sc22/wg14/www/docs/n1570.pdf) + const auto* a_data = a.as_bytes(); + const auto* b_data = b.as_bytes(); + // load each intmax_t chunk and process; increase pointers by sizeof(intmax_t) + for (auto& out : buffer) { + out = op(load(a_data), load(b_data)); + a_data += sizeof(intmax_t); + b_data += sizeof(intmax_t); + } + assert(a_data == a.as_bytes() + sizeof(a)); + assert(b_data == b.as_bytes() + sizeof(b)); + return Vectorized::loadu(buffer); +} + +template>, int> = 0> +inline Vectorized operator&(const Vectorized& a, const Vectorized& b) { + return bitwise_binary_op(a, b, std::bit_and()); +} +template>, int> = 0> +inline Vectorized operator|(const Vectorized& a, const Vectorized& b) { + return bitwise_binary_op(a, b, std::bit_or()); +} +template>, int> = 0> +inline Vectorized operator^(const Vectorized& a, const Vectorized& b) { + return bitwise_binary_op(a, b, std::bit_xor()); +} + +#endif // defined(CPU_CAPABILITY_AVX2) || defined(CPU_CAPABILITY_AVX512) + +template>, int> = 0> +inline Vectorized operator~(const Vectorized& a) { + using int_t = int_same_size_t; + Vectorized ones(c10::bit_cast((int_t)(~(int_t)0))); // All bits are 1 + return a ^ ones; +} + +template Vectorized inline operator<<(const Vectorized &a, const Vectorized &b) { + constexpr T max_shift = sizeof(T) * CHAR_BIT; + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + T shift = b[i]; + if ((static_cast>(shift) < 0) || (shift >= max_shift)) { + c[i] = 0; + } else { + c[i] = static_cast>(a[i]) << shift; + } + } + return c; +} + +template Vectorized inline operator>>(const Vectorized &a, const Vectorized &b) { + // right shift value to retain sign bit for signed and no bits for unsigned + constexpr T max_shift = sizeof(T) * CHAR_BIT - std::is_signed_v; + Vectorized c; + for (int i = 0; i != Vectorized::size(); i++) { + T shift = b[i]; + if ((static_cast>(shift) < 0) || (shift >= max_shift)) { + c[i] = a[i] >> max_shift; + } else { + c[i] = a[i] >> shift; + } + } + return c; +} + +template +inline Vectorized& operator += (Vectorized& a, const Vectorized& b) { + a = a + b; + return a; +} +template +inline Vectorized& operator -= (Vectorized& a, const Vectorized& b) { + a = a - b; + return a; +} +template +inline Vectorized& operator /= (Vectorized& a, const Vectorized& b) { + a = a / b; + return a; +} +template +inline Vectorized& operator %= (Vectorized& a, const Vectorized& b) { + a = a % b; + return a; +} +template +inline Vectorized& operator *= (Vectorized& a, const Vectorized& b) { + a = a * b; + return a; +} + +template +inline Vectorized& operator <<= (Vectorized& a, const Vectorized& b) { + a = a << b; + return a; +} + +template +inline Vectorized& operator >>= (Vectorized& a, const Vectorized& b) { + a = a >> b; + return a; +} + +template +inline Vectorized fmadd(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return a * b + c; +} + +template +inline Vectorized fmsub(const Vectorized& a, const Vectorized& b, const Vectorized& c) { + return a * b - c; +} + +template +Vectorized inline operator&&( + const Vectorized& a, + const Vectorized& b) { + Vectorized ret; + for (int i = 0; i != Vectorized::size(); i++) { + ret[i] = a[i] && b[i]; + } + return ret; +} + +template +std::enable_if_t> +inline gather(T const* base_addr, const Vectorized>& vindex) { + static constexpr int size = Vectorized::size(); + int_same_size_t index_arr[size]; + vindex.store(static_cast(index_arr)); + T buffer[size]; + for (const auto i : c10::irange(size)) { + buffer[i] = base_addr[index_arr[i] * scale / sizeof(T)]; + } + return Vectorized::loadu(static_cast(buffer)); +} + +template +std::enable_if_t> +inline mask_gather(const Vectorized& src, T const* base_addr, + const Vectorized>& vindex, Vectorized& mask) { + static constexpr int size = Vectorized::size(); + T src_arr[size]; + int_same_size_t mask_arr[size]; // use int type so we can logical and + int_same_size_t index_arr[size]; + src.store(static_cast(src_arr)); + mask.store(static_cast(mask_arr)); + vindex.store(static_cast(index_arr)); + T buffer[size]; + for (const auto i : c10::irange(size)) { + if (mask_arr[i] & 0x01) { // check highest bit + buffer[i] = base_addr[index_arr[i] * scale / sizeof(T)]; + } else { + buffer[i] = src_arr[i]; + } + } + mask = Vectorized(static_cast(0)); // "zero out" mask + return Vectorized::loadu(static_cast(buffer)); +} + +// Cast a given vector to another type without changing the bits representation. +// So a Vectorized of 512 bits containing all ones can be cast to a +// Vectorized of 512 bits containing all ones (i.e., eight negative 1s). +// A Vec of 256 bits containing all ones can be cast to a +// Vec of 256 bits containing all ones (i.e., four negative 1s). +// There is a struct here because we don't have static_if and I can't +// partially specialize a templated function. +template +struct CastImpl { + static inline Vectorized apply(const Vectorized& src) { + src_t src_arr[Vectorized::size()]; + src.store(static_cast(src_arr)); + return Vectorized::loadu(static_cast(src_arr)); + } +}; + +template +struct CastImpl { + static inline Vectorized apply(const Vectorized& src) { + return src; + } +}; + +template +inline Vectorized cast(const Vectorized& src) { + return CastImpl::apply(src); +} + +template > +inline Vectorized convert_to_int_of_same_size(const Vectorized& src) { + static_assert(sizeof(T) == sizeof(IntType)); + static constexpr int size = Vectorized::size(); + + std::array src_arr; + src.store(static_cast(src_arr.data())); + std::array buffer; + std::transform(src_arr.cbegin(), src_arr.cend(), buffer.begin(), + [](const T& x) { return static_cast(x); }); + return Vectorized::loadu(static_cast(buffer.data())); +} + +template > +inline Vectorized convert_to_fp_of_same_size(const Vectorized& src) { + static_assert(sizeof(T) == sizeof(IntType)); + static constexpr int size = Vectorized::size(); + + std::array src_arr; + src.store(static_cast(src_arr.data())); + std::array buffer; + std::transform(src_arr.cbegin(), src_arr.cend(), buffer.begin(), + [](const IntType& x) { return static_cast(x); }); + return Vectorized::loadu(static_cast(buffer.data())); +} + +// Example inputs for AVX512: +// a Vectorized = {a0, b0, a1, b1, a2, b2, a3, b3, a4, b4, a5, b5, a6, b6, a7, b7} +// b Vectorized = {a8, b8, a9, b9, a10, b10, a11, b11, a12, b12, a13, b13, a14, b14, a15, b15} +// returns: +// Vectorized = {a0, a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11, a12, a13, a14, a15} +// Vectorized = {b0, b1, b2, b3, b4, b5, b6, b7, b8, b9, b10, b11, b12, b13, b14, b15} +// Example inputs for AVX2: a Vectorized = {a0, b0, a1, b1, a2, b2, a3, b3} +// b Vectorized = {a4, b4, a5, b5, a6, b6, a7, b7} +// returns: Vectorized = {a0, a1, a2, a3, a4, a5, a6, a7} +// Vectorized = {b0, b1, b2, b3, b4, b5, b6, b7} +template +inline std::enable_if_t::size() % 2 == 0, std::pair, Vectorized>> +deinterleave2(const Vectorized& a, const Vectorized& b) { + static constexpr int size = Vectorized::size(); + static constexpr int half_size = size / 2; + T a_arr[size]; + T b_arr[size]; + T buffer1[size]; + T buffer2[size]; + a.store(static_cast(a_arr)); + b.store(static_cast(b_arr)); + for (const auto i : c10::irange(half_size)) { + buffer1[i] = a_arr[i * 2]; + buffer1[half_size + i] = b_arr[i * 2]; + buffer2[i] = a_arr[i * 2 + 1]; + buffer2[half_size + i] = b_arr[i * 2 + 1]; + } + return std::make_pair(Vectorized::loadu(static_cast(buffer1)), + Vectorized::loadu(static_cast(buffer2))); +} + +// inverse operation of deinterleave2 +// Example inputs for AVX512: +// a Vectorized = {a0, a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11, a12, a13, a14, a15} +// b Vectorized = {b0, b1, b2, b3, b4, b5, b6, b7, b8, b9, b10, b11, b12, b13, b14, b15} +// returns, for AVX512: +// Vectorized = {a0, b0, a1, b1, a2, b2, a3, b3, a4, b4, a5, b5, a6, b6, a7, b7} +// Vectorized = {a8, b8, a9, b9, a10, b10, a11, b11, a12, b12, a13, b13, a14, b14, a15, b15} +// Example inputs for AVX2 : a Vectorized = {a0, a1, a2, a3, a4, a5, a6, a7} +// b Vectorized = {b0, b1, b2, b3, b4, b5, b6, b7} +// returns: Vectorized = {a0, b0, a1, b1, a2, b2, a3, b3} +// Vectorized = {a4, b4, a5, b5, a6, b6, a7, b7} +template +inline std::enable_if_t::size() % 2 == 0, std::pair, Vectorized>> +interleave2(const Vectorized& a, const Vectorized& b) { + static constexpr int size = Vectorized::size(); + static constexpr int half_size = size / 2; + T a_arr[size]; + T b_arr[size]; + T buffer1[size]; + T buffer2[size]; + a.store(static_cast(a_arr)); + b.store(static_cast(b_arr)); + for (const auto i : c10::irange(half_size)) { + buffer1[i * 2] = a_arr[i]; + buffer1[i * 2 + 1] = b_arr[i]; + buffer2[i * 2] = a_arr[half_size + i]; + buffer2[i * 2 + 1] = b_arr[half_size + i]; + } + return std::make_pair(Vectorized::loadu(static_cast(buffer1)), + Vectorized::loadu(static_cast(buffer2))); +} + +template +inline void convert(const src_T *src, dst_T *dst, int64_t n) { +#ifndef _MSC_VER +# pragma unroll +#endif + for ([[maybe_unused]] const auto i : c10::irange(n)) { + *dst = c10::convert(c10::load(src)); + src++; + dst++; + } +} + +template +inline Vectorized flip(const Vectorized & data) { + static constexpr int size = Vectorized::size(); + T output[size]; + T buffer[size]; + data.store(static_cast(buffer)); + for (const auto i : c10::irange(size)) { + output[i] = buffer[size - i - 1]; + } + return Vectorized::loadu(static_cast(output)); +} + +// Transpose the `src` buffer of type `T` and size (M,N) into the `dst` buffer. `ld_src` is the leading +// dimension of `src` and `ld_dst` is the leading dimension of `dst`. +template +inline void transpose_mxn(const T* src, int64_t ld_src, T* dst, int64_t ld_dst, int M, int N) { + for (int i = 0; i < M; i++) { + for (int j = 0; j < N; j++) { + dst[j*ld_dst + i] = src[i*ld_src + j]; + } + } +} + +template +inline void transpose_mxn(const T* src, int64_t ld_src, T* dst, int64_t ld_dst) { + transpose_mxn(src, ld_src, dst, ld_dst, M, N); +} + +}} // namespace at::vec::CPU_CAPABILITY + +// additional headers for more operations that depend on vec_base +#include +#include +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_convert.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_convert.h new file mode 100644 index 0000000000000000000000000000000000000000..a5cee03dabcfc5355f51a614c33e2002fb01f4fd --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_convert.h @@ -0,0 +1,65 @@ +#pragma once + +#include +#include + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +template < + typename dst_t, + int dst_n, + typename src_t, + int src_n, + typename Enabled = void> +struct VecConvert { + static inline VectorizedN apply( + const VectorizedN& src) { + constexpr int count = std::min( + VectorizedN::size(), VectorizedN::size()); + __at_align__ src_t src_buf[VectorizedN::size()]; + src.store(src_buf); + __at_align__ dst_t dst_buf[VectorizedN::size()]; + for (int i = 0; i < count; i++) { + dst_buf[i] = static_cast(src_buf[i]); + } + return VectorizedN::loadu(dst_buf, count); + } +}; + +template +inline std::enable_if_t, Vectorized> +convert(const Vectorized& src) { + return src; +} + +template +inline std::enable_if_t, Vectorized> +convert(const Vectorized& src) { + return VecConvert::apply(src); +} + +template < + typename dst_t, + int dst_n, + typename src_t, + int src_n, + std::enable_if_t = 0> +inline VectorizedN convert(const VectorizedN& src) { + return VecConvert::apply(src); +} + +template < + typename dst_t, + int dst_n, + typename src_t, + int src_n, + bool keep = false, + std::enable_if_t = 0> +inline std::conditional_t, Vectorized> +convert(const VectorizedN& src) { + return VecConvert::apply(src); +} + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_half.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_half.h new file mode 100644 index 0000000000000000000000000000000000000000..c7c90cc95b470a9eed0898147364d52c46f24908 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_half.h @@ -0,0 +1,151 @@ +#pragma once + +#include +#include + +namespace at::vec { +// See Note [CPU_CAPABILITY namespace] +inline namespace CPU_CAPABILITY { + +#if (defined(CPU_CAPABILITY_AVX2) || defined(CPU_CAPABILITY_AVX512)) && \ + !defined(__APPLE__) +static inline uint16_t float2half_scalar(float val) { +#if defined(CPU_CAPABILITY_AVX2) +#if defined(_MSC_VER) + __m256 v = _mm256_set1_ps(val); + __m128i o = + _mm256_cvtps_ph(v, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + return static_cast(_mm_cvtsi128_si32(o)); +#else + return _cvtss_sh(val, _MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC); +#endif +#elif defined(CPU_CAPABILITY_AVX512) + __m512 v = _mm512_set1_ps(val); + __m256i o = + _mm512_cvtps_ph(v, (_MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC)); + return static_cast( + _mm_cvtsi128_si32(_mm256_castsi256_si128(o))); +#endif +} + +static inline float half2float_scalar(uint16_t val) { +#if defined(CPU_CAPABILITY_AVX2) +#if defined(_MSC_VER) + __m128i v = _mm_cvtsi32_si128(val); + __m256 o = _mm256_cvtph_ps(v); + return _mm256_cvtss_f32(o); +#else + return _cvtsh_ss(val); +#endif +#elif defined(CPU_CAPABILITY_AVX512) + __m256i v = + _mm256_setr_epi16(val, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0); + __m512 o = _mm512_cvtph_ps(v); + return _mm512_cvtss_f32(o); +#endif +} + +#endif + +// Transpose a [2, 32] matrix to [32, 2] +// Note: the output leading dimension should be 2, +// that is, the output must be contiguous +template > +static inline void transpose_pad_2x32_block( + const scalar_t* src, + scalar_t* dst, + int64_t ld_src, + int krem = 2, + int nrem = 32) { +#if defined(CPU_CAPABILITY_AVX512) + __m512i r0, r1; + __m512i d0, d1; + // load + if (nrem < 32) { + __mmask32 mask_krem_v = (1LL << nrem) - 1; + r0 = _mm512_maskz_loadu_epi16(mask_krem_v, src); + // if krem is not 2, pad with zeros + if (krem == 2) { + r1 = _mm512_maskz_loadu_epi16(mask_krem_v, src + ld_src); + } else { + r1 = _mm512_setzero_si512(); + } + } else { + r0 = _mm512_loadu_si512(reinterpret_cast(src)); + if (krem == 2) { + r1 = _mm512_loadu_si512(reinterpret_cast(src + ld_src)); + } else { + r1 = _mm512_setzero_si512(); + } + } + // transpose + d0 = _mm512_unpacklo_epi16(r0, r1); + d1 = _mm512_unpackhi_epi16(r0, r1); + r0 = _mm512_shuffle_i32x4(d0, d1, 0x88); + r1 = _mm512_shuffle_i32x4(d0, d1, 0xdd); + d0 = _mm512_shuffle_i32x4(r0, r1, 0x88); + d1 = _mm512_shuffle_i32x4(r0, r1, 0xdd); + + // store + if (nrem < 16) { + __mmask32 mask_rem_v = (1LL << (nrem * 2)) - 1; + _mm512_mask_storeu_epi16(dst, mask_rem_v, d0); + } else if (nrem == 16) { + _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst), d0); + } else if (nrem < 32) { + __mmask32 mask_rem_v = (1LL << (nrem * 2 - 32)) - 1; + _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst), d0); + _mm512_mask_storeu_epi16( + reinterpret_cast<__m512i*>(dst + 32), mask_rem_v, d1); + } else { + // normal store + _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst), d0); + _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst + 32), d1); + } +#else +TORCH_CHECK(false, "transpose_pad_2x32_block is only supported when avx512 is supported") +#endif +} + +// To use AMX to accelerate GEMM, +// reorder the memory format [K, N] -> [K/2, N, 2] +// Note: If K % 2 != 0, pad K implicitly +template > +static inline void pack_vnni2( + const scalar_t* src, + scalar_t* dst, + int64_t ld_src, + int64_t K, + int64_t N) { +#if defined(CPU_CAPABILITY_AVX512) + int64_t bk = 0; + int64_t _K = K / 2 * 2; + int64_t _N = N / 32 * 32; + for (; bk < _K; bk += 2) { + int64_t bn = 0; + for (; bn < _N; bn += 32) { + transpose_pad_2x32_block(src + bk * ld_src + bn, dst + bk * N + bn * 2, ld_src); + } + int64_t nrem = N - bn; + if (nrem > 0) { + transpose_pad_2x32_block(src + bk * ld_src + bn, dst + bk * N + bn * 2, ld_src, 2, nrem); + } + } + if (K % 2 == 1) { + int64_t bn = 0; + for (; bn < _N; bn += 32) { + transpose_pad_2x32_block(src + bk * ld_src + bn, dst + bk * N + bn * 2, ld_src, 1); + } + int64_t nrem = N - bn; + if (nrem > 0) { + transpose_pad_2x32_block(src + bk * ld_src + bn, dst + bk * N + bn * 2, ld_src, 1, nrem); + } + } +#else +TORCH_CHECK(false, "pack_vnni2 is only supported when avx512 is supported") +#endif +} + + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_mask.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_mask.h new file mode 100644 index 0000000000000000000000000000000000000000..c547e5911ecbd653d6cfde9c6e6363390490c60a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_mask.h @@ -0,0 +1,295 @@ +#pragma once + +#include +#include +namespace at::vec { +inline namespace CPU_CAPABILITY { + +/** + * The `VecMask` class provides a convenient interface for working with + * vectorized masks in SIMD operations. It encapsulates a `Vectorized` + * mask that can be directly usable in masked vectorized operations. It provides + * various methods for manipulating and accessing the mask elements: + * 1. `from` and `to`: Conversion between a vector of boolean values and a + * vectorized mask. + * 2. `cast`: Casts the mask to a different base type. + * 3. `all_zero`: Checks if all mask elements are zero. + * 4. `is_masked`: Checks if a specific element is masked. + * 5. `loadu`: Loads data from memory using the mask. + * 6. `all_masked`: Checks if all mask elements are masked. + * + * Some helper template classes are provided to simplify the specialization of + * the `VecMask` for the specific CPU arch: + * 1. `VecMaskLoad`: Loads data from memory using the mask. + * 2. `VecMaskTo`: Converts the mask to boolean. + * 3. `VecMaskCast`: Casts the mask to a different base type. + * + */ +template +class VecMask; + +template < + typename data_t, + int data_n, + typename mask_t, + int mask_n, + typename Enabled = void> +struct VecMaskLoad { + static inline VectorizedN apply( + const data_t* ptr, + const VecMask& vec_mask) { + constexpr typename VecMask::size_type size = + VecMask::size(); + static_assert(VectorizedN::size() >= size); + __at_align__ data_t data[size]; + __at_align__ mask_t mask[size]; + auto mask_ = VectorizedN(vec_mask); + mask_.store(mask); + for (int i = 0; i < size; i++) { + data[i] = mask[i] ? ptr[i] : static_cast(0); + } + return VectorizedN::loadu(data, size); + } +}; + +template < + typename dst_t, + int dst_n, + typename src_t, + int src_n, + typename Enabled = void> +struct VecMaskTo { + static inline VecMask apply( + const VecMask& vec_mask) { + auto zeros = VectorizedN(static_cast(0)); + auto ones = VectorizedN(static_cast(1)); + return VectorizedN::blendv( + zeros, ones, vec_mask.template cast()); + } +}; + +template +struct VecMaskCast { + static inline VecMask apply( + const VecMask& vec_mask) { + return VecMask::from(VectorizedN(vec_mask)); + } +}; + +template +struct VecMaskCast { + static inline VecMask apply(const VecMask& vec_mask) { + return vec_mask; + } +}; + +template +struct VecMaskCheck { + static inline bool all_zero(const VectorizedN& vec_mask) { + __at_align__ T mask[VectorizedN::size()]; + vec_mask.store(mask); + return std::all_of( + mask, mask + VectorizedN::size(), [](T m) { return m == static_cast(0); }); + } + + static inline bool all_masked(const VectorizedN& vec_mask) { + __at_align__ T mask[VectorizedN::size()]; + vec_mask.store(mask); + return std::all_of( + mask, mask + VectorizedN::size(), [](T m) { return m != static_cast(0); }); + } + + static inline bool is_masked(const VectorizedN& vec_mask, int i) { + __at_align__ T mask[VectorizedN::size()]; + vec_mask.store(mask); + return mask[i] != static_cast(0); + } +}; + +template +class VecMask { + public: + using size_type = int; + static constexpr size_type size() { + return VectorizedN::size(); + } + + private: + VectorizedN mask_; + + public: + VecMask() : mask_(static_cast(0)) {} + VecMask(const VectorizedN& mask) : mask_(mask) {} + + template = 0> + VecMask(const Vectorized& mask) : mask_(mask) {} + + template + static VecMask from(const VectorizedN& b_vec) { + __at_align__ U b_buf[size()]; + if constexpr (size() >= VectorizedN::size()) { + b_vec.store(b_buf); + for (int i = VectorizedN::size(); i < size(); i++) { + b_buf[i] = static_cast(0); + } + } else { + b_vec.store(b_buf, size()); + } + return from(b_buf); + } + + template + static VecMask from(U b) { + using int_t = int_same_size_t; + T mask = b ? c10::bit_cast((int_t)(~(int_t)0)) : (T)0; + return VectorizedN(mask); + } + + template + static VecMask from(U* b) { + using int_t = int_same_size_t; + __at_align__ T mask[size()]; +#ifndef __msvc_cl__ +#pragma unroll +#endif + for (int i = 0; i < size(); i++) { + *(int_t*)(mask + i) = b[i] ? ~(int_t)0 : (int_t)0; + } + return VectorizedN(VectorizedN::loadu(mask)); + } + + static VecMask blendv( + const VecMask& c, + const VecMask& b, + const VecMask& a) { + VectorizedN result = VectorizedN::blendv( + VectorizedN(c), + VectorizedN(b), + VectorizedN(a)); + return result; + } + + static VecMask set( + const VecMask& a, + const VecMask& b, + int64_t count = size()) { + VectorizedN result = VectorizedN::set( + VectorizedN(a), + VectorizedN(b), + count); + return result; + } + + void store(bool* b, int count = size()) { + constexpr int L = (VectorizedN::size() + Vectorized::size() - 1)/ Vectorized::size(); + auto res = this->to(); + res.store(b, count); + return; + } + + template = 2, int> = 0> + inline VectorizedN to() const { + return VecMaskTo::apply(*this); + } + + template = 0> + inline Vectorized to() const { + return VecMaskTo::apply(*this); + } + + template + inline VecMask cast() const { + return VecMaskCast::apply(*this); + } + + inline bool all_zero() const { + return VecMaskCheck::all_zero(mask_); + } + + inline bool all_masked() const { + return VecMaskCheck::all_masked(mask_); + } + + inline bool is_masked(int i) const { + return VecMaskCheck::is_masked(mask_, i); + } + + inline operator VectorizedN() const { + return mask_; + } + + template = 0> + inline operator Vectorized() const { + return mask_[0]; + } + + inline Vectorized operator[](int i) const { + return mask_[i]; + } + + template < + typename U, + int L, + std::enable_if_t= 2 && VectorizedN::size() >= size(), int> = 0> + VectorizedN loadu(const U* ptr) const { + return VecMaskLoad::apply(ptr, *this); + } + + template < + typename U, + int L, + std::enable_if_t::size() >= size(), int> = 0> + Vectorized loadu(const U* ptr) const { + return VecMaskLoad::apply(ptr, *this); + } +}; + +#define VEC_MASK_DEFINE_UNARY_OP_GLOBAL(op) \ + template \ + inline VecMask op(const VecMask& a) { \ + return op(VectorizedN(a)); \ + } + +#define VEC_MASK_DEFINE_BINARY_OP_GLOBAL(op) \ + template < \ + typename T, \ + int N, \ + typename V, \ + int M, \ + std::enable_if_t::size() == VecMask::size(), int> = \ + 0> \ + inline VecMask op(const VecMask& a, const VecMask& b) { \ + return op( \ + VectorizedN(a), VectorizedN(b.template cast())); \ + } + +#define VEC_MASK_DEFINE_BINARY_OP_WITH_EXPR_GLOBAL(op, EXPR) \ + template < \ + typename T, \ + int N, \ + typename V, \ + int M, \ + std::enable_if_t::size() == VecMask::size(), int> = \ + 0> \ + inline VecMask op(const VecMask& a, const VecMask& b) { \ + return EXPR; \ + } + +VEC_MASK_DEFINE_UNARY_OP_GLOBAL(operator~) +VEC_MASK_DEFINE_BINARY_OP_GLOBAL(operator&) +VEC_MASK_DEFINE_BINARY_OP_GLOBAL(operator|) +VEC_MASK_DEFINE_BINARY_OP_GLOBAL(operator^) +VEC_MASK_DEFINE_BINARY_OP_GLOBAL(operator*) +VEC_MASK_DEFINE_BINARY_OP_WITH_EXPR_GLOBAL(operator>, a & ~b) +VEC_MASK_DEFINE_BINARY_OP_WITH_EXPR_GLOBAL(operator<, ~a& b) +VEC_MASK_DEFINE_BINARY_OP_WITH_EXPR_GLOBAL(operator==, ~(a ^ b)) +VEC_MASK_DEFINE_BINARY_OP_WITH_EXPR_GLOBAL(operator>=, (a == b) | (a > b)) +VEC_MASK_DEFINE_BINARY_OP_WITH_EXPR_GLOBAL(operator<=, (a == b) | (a < b)) +VEC_MASK_DEFINE_BINARY_OP_WITH_EXPR_GLOBAL(operator!=, (a ^ b)) + +#undef VEC_MASK_DEFINE_UNARY_OP_GLOBAL +#undef VEC_MASK_DEFINE_BINARY_OP_GLOBAL +#undef VEC_MASK_DEFINE_BINARY_OP_WITH_EXPR_GLOBAL + +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_n.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_n.h new file mode 100644 index 0000000000000000000000000000000000000000..9725bf3eedb09270c04e71dd5bb8388fe57a20e0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vec/vec_n.h @@ -0,0 +1,405 @@ +#pragma once + +#include +#include + +namespace at::vec { +inline namespace CPU_CAPABILITY { + +/** + * @brief A class template representing a vectorized type with + * `N * Vectorized::size()` elements, aiming to support vectors of + * arbitrary size. A specific use case of it is to represent vectors + * converted from data types with different sizes but with the same + * number of vector elements, e.g., `VectorizedN` can be + * a vector converted from two `Vectorized`, `VectorizedN` + * can be a vector converted from two `Vectorized` etc. + * + * It supports most of the operations of `Vectorized` + * and the implementation delegates to `Vectorized` with loops over `N`. + * + * @tparam T The underlying type of the vectorized elements. + * @tparam N The number of underlying `Vectorized`. + */ +template +class VectorizedN { + public: + using value_type = T; + using size_type = int; + + static constexpr size_type size_T = sizeof(T); + static constexpr size_type size() { + return Vectorized::size() * N; + } + + private: + std::array, N> values; + + public: + // methods not implemented yet: + // variadic constructor, operator T*, as_bytes, zero_mask + +#define VECTORIZEDN_DEFINE_UNARY_OP(op) \ + VectorizedN op() const { \ + return unary_op([](const Vectorized& a) { return a.op(); }); \ + } + +#define VECTORIZEDN_DEFINE_BINARY_OP(op) \ + VectorizedN op(const VectorizedN& other) const { \ + return binary_op( \ + other, [](const Vectorized& a, const Vectorized& b) { \ + return a.op(b); \ + }); \ + } + + template + inline VectorizedN unary_op(Op op) const { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result.values[i] = op(values[i]); + } + return result; + } + + template + inline VectorizedN binary_op(const VectorizedN& other, Op op) + const { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result.values[i] = op(values[i], other.values[i]); + } + return result; + } + + template + inline VectorizedN ternary_op( + const VectorizedN& other, + const VectorizedN& other2, + Op op) const { + VectorizedN result; +#ifndef _MSC_VER +#pragma unroll +#endif + for (int i = 0; i < N; ++i) { + result.values[i] = op(values[i], other.values[i], other2.values[i]); + } + return result; + } + + VectorizedN() = default; + + explicit VectorizedN(T val) { + for (int i = 0; i < N; ++i) { + values[i] = Vectorized(val); + } + } + + template = 0> + VectorizedN(const Vectorized& val) : values({val}) {} + + template = 0> + VectorizedN(const Vectorized& val_0, const Vectorized& val_1) + : values({val_0, val_1}) {} + + template = 0> + inline operator Vectorized() const { + return values[0]; + } + + inline const Vectorized& operator[](int i) const { + return values[i]; + } + + inline Vectorized& operator[](int i) { + return values[i]; + } + + template + static VectorizedN blend( + const VectorizedN& a, + const VectorizedN& b) { + VectorizedN result; + for (int i = 0; i < N; ++i) { + result.values[i] = + Vectorized::template blend(a.values[i], b.values[i]); + } + return result; + } + + static VectorizedN blendv( + const VectorizedN& a, + const VectorizedN& b, + const VectorizedN& mask) { + VectorizedN result; + for (int i = 0; i < N; ++i) { + result.values[i] = + Vectorized::blendv(a.values[i], b.values[i], mask.values[i]); + } + return result; + } + + template + static VectorizedN arange( + T base = static_cast(0), + step_t step = static_cast(1)) { + VectorizedN result; + for (int i = 0; i < N; ++i) { + result.values[i] = Vectorized::arange(base, step); + base += step * Vectorized::size(); + } + return result; + } + + static VectorizedN set( + const VectorizedN& a, + const VectorizedN& b, + int64_t count = size()) { + VectorizedN result; + for (int i = 0; i < N; ++i) { + if (count > 0) { + result.values[i] = Vectorized::set( + a.values[i], + b.values[i], + std::min(count, (int64_t)Vectorized::size())); + count -= Vectorized::size(); + } else { + result.values[i] = a.values[i]; + } + } + return result; + } + + static VectorizedN loadu(const void* ptr) { + VectorizedN result; + for (int i = 0; i < N; ++i) { + result.values[i] = Vectorized::loadu(ptr); + ptr = static_cast(ptr) + Vectorized::size(); + } + return result; + } + + static VectorizedN loadu(const void* ptr, int64_t count) { + VectorizedN result; + for (int i = 0; i < N; ++i) { + result.values[i] = Vectorized::loadu( + ptr, std::min(count, (int64_t)Vectorized::size())); + ptr = static_cast(ptr) + Vectorized::size(); + count -= Vectorized::size(); + if (count <= 0) { + break; + } + } + return result; + } + + void store(void* ptr) const { + for (int i = 0; i < N; ++i) { + values[i].store(ptr); + ptr = static_cast(ptr) + Vectorized::size(); + } + } + + void store(void* ptr, int count) const { + for (int i = 0; i < N; ++i) { + values[i].store(ptr, std::min(count, (int)Vectorized::size())); + ptr = static_cast(ptr) + Vectorized::size(); + count -= Vectorized::size(); + if (count <= 0) { + break; + } + } + } + + bool has_inf_nan() const { + for (int i = 0; i < N; ++i) { + if (values[i].has_inf_nan()) { + return true; + } + } + return false; + } + + VectorizedN map(T (*const f)(T)) const { + VectorizedN result; + for (int i = 0; i < N; ++i) { + result.values[i] = values[i].map(f); + } + return result; + } + + VectorizedN map(T (*const f)(const T&)) const { + VectorizedN result; + for (int i = 0; i < N; ++i) { + result.values[i] = values[i].map(f); + } + return result; + } + + VECTORIZEDN_DEFINE_UNARY_OP(isnan) + VECTORIZEDN_DEFINE_UNARY_OP(abs) + VECTORIZEDN_DEFINE_UNARY_OP(sgn) + VECTORIZEDN_DEFINE_UNARY_OP(angle) + VECTORIZEDN_DEFINE_UNARY_OP(real) + VECTORIZEDN_DEFINE_UNARY_OP(imag) + VECTORIZEDN_DEFINE_UNARY_OP(conj) + VECTORIZEDN_DEFINE_UNARY_OP(acos) + VECTORIZEDN_DEFINE_UNARY_OP(acosh) + VECTORIZEDN_DEFINE_UNARY_OP(asin) + VECTORIZEDN_DEFINE_UNARY_OP(asinh) + VECTORIZEDN_DEFINE_UNARY_OP(atan) + VECTORIZEDN_DEFINE_UNARY_OP(atanh) + VECTORIZEDN_DEFINE_BINARY_OP(atan2) + VECTORIZEDN_DEFINE_BINARY_OP(copysign) + VECTORIZEDN_DEFINE_UNARY_OP(erf) + VECTORIZEDN_DEFINE_UNARY_OP(erfc) + VECTORIZEDN_DEFINE_UNARY_OP(erfinv) + VECTORIZEDN_DEFINE_UNARY_OP(exp) + VECTORIZEDN_DEFINE_UNARY_OP(exp2) + VECTORIZEDN_DEFINE_UNARY_OP(expm1) + VECTORIZEDN_DEFINE_UNARY_OP(exp_u20) + VECTORIZEDN_DEFINE_UNARY_OP(frac) + VECTORIZEDN_DEFINE_BINARY_OP(fmod) + VECTORIZEDN_DEFINE_UNARY_OP(log) + VECTORIZEDN_DEFINE_UNARY_OP(log10) + VECTORIZEDN_DEFINE_UNARY_OP(log1p) + VECTORIZEDN_DEFINE_UNARY_OP(log2) + VECTORIZEDN_DEFINE_UNARY_OP(ceil) + VECTORIZEDN_DEFINE_UNARY_OP(cos) + VECTORIZEDN_DEFINE_UNARY_OP(cosh) + VECTORIZEDN_DEFINE_UNARY_OP(floor) + VECTORIZEDN_DEFINE_BINARY_OP(hypot) + VECTORIZEDN_DEFINE_UNARY_OP(i0) + VECTORIZEDN_DEFINE_UNARY_OP(i0e) + VECTORIZEDN_DEFINE_UNARY_OP(digamma) + VECTORIZEDN_DEFINE_BINARY_OP(igamma) + VECTORIZEDN_DEFINE_BINARY_OP(igammac) + VECTORIZEDN_DEFINE_UNARY_OP(neg) + VECTORIZEDN_DEFINE_BINARY_OP(nextafter) + VECTORIZEDN_DEFINE_UNARY_OP(round) + VECTORIZEDN_DEFINE_UNARY_OP(sin) + VECTORIZEDN_DEFINE_UNARY_OP(sinh) + VECTORIZEDN_DEFINE_UNARY_OP(tan) + VECTORIZEDN_DEFINE_UNARY_OP(tanh) + VECTORIZEDN_DEFINE_UNARY_OP(trunc) + VECTORIZEDN_DEFINE_UNARY_OP(lgamma) + VECTORIZEDN_DEFINE_UNARY_OP(sqrt) + VECTORIZEDN_DEFINE_UNARY_OP(reciprocal) + VECTORIZEDN_DEFINE_UNARY_OP(rsqrt) + VECTORIZEDN_DEFINE_BINARY_OP(pow) + VECTORIZEDN_DEFINE_BINARY_OP(operator==) + VECTORIZEDN_DEFINE_BINARY_OP(operator!=) + VECTORIZEDN_DEFINE_BINARY_OP(operator>=) + VECTORIZEDN_DEFINE_BINARY_OP(operator<=) + VECTORIZEDN_DEFINE_BINARY_OP(operator>) + VECTORIZEDN_DEFINE_BINARY_OP(operator<) + VECTORIZEDN_DEFINE_BINARY_OP(eq) + VECTORIZEDN_DEFINE_BINARY_OP(ne) + VECTORIZEDN_DEFINE_BINARY_OP(gt) + VECTORIZEDN_DEFINE_BINARY_OP(ge) + VECTORIZEDN_DEFINE_BINARY_OP(lt) + VECTORIZEDN_DEFINE_BINARY_OP(le) + +#undef VECTORIZEDN_DEFINE_UNARY_OP +#undef VECTORIZEDN_DEFINE_BINARY_OP +}; + +#define VECTORIZEDN_DEFINE_UNARY_OP_GLOBAL(op) \ + template \ + inline VectorizedN op(const VectorizedN& a) { \ + return a.unary_op([](const Vectorized& a) { return op(a); }); \ + } + +#define VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(op) \ + template \ + inline VectorizedN op( \ + const VectorizedN& a, const VectorizedN& b) { \ + return a.binary_op(b, [](const Vectorized& a, const Vectorized& b) { \ + return op(a, b); \ + }); \ + } + +#define VECTORIZEDN_DEFINE_TERNARY_OP_GLOBAL(op) \ + template \ + inline VectorizedN op( \ + const VectorizedN& a, \ + const VectorizedN& b, \ + const VectorizedN& c) { \ + return a.ternary_op( \ + b, \ + c, \ + [](const Vectorized& a, \ + const Vectorized& b, \ + const Vectorized& c) { return op(a, b, c); }); \ + } + +#define VECTORIZEDN_DEFINE_BINARY_OP_INPLACE_GLOBAL(op) \ + template \ + inline VectorizedN& op( \ + VectorizedN& a, const VectorizedN& b) { \ + a = a.binary_op(b, [](const Vectorized& a, const Vectorized& b) { \ + return op(a, b); \ + }); \ + return a; \ + } + +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator+) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator-) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator*) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator/) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator%) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator||) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator<<) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator>>) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(maximum) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(minimum) +VECTORIZEDN_DEFINE_TERNARY_OP_GLOBAL(fmadd) +VECTORIZEDN_DEFINE_TERNARY_OP_GLOBAL(fmsub) +VECTORIZEDN_DEFINE_TERNARY_OP_GLOBAL(clamp) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(clamp_max) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(clamp_min) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator&) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator|) +VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL(operator^) +VECTORIZEDN_DEFINE_UNARY_OP_GLOBAL(operator~) + +VECTORIZEDN_DEFINE_BINARY_OP_INPLACE_GLOBAL(operator+=) +VECTORIZEDN_DEFINE_BINARY_OP_INPLACE_GLOBAL(operator-=) +VECTORIZEDN_DEFINE_BINARY_OP_INPLACE_GLOBAL(operator*=) +VECTORIZEDN_DEFINE_BINARY_OP_INPLACE_GLOBAL(operator/=) +VECTORIZEDN_DEFINE_BINARY_OP_INPLACE_GLOBAL(operator%=) +VECTORIZEDN_DEFINE_BINARY_OP_INPLACE_GLOBAL(operator<<=) +VECTORIZEDN_DEFINE_BINARY_OP_INPLACE_GLOBAL(operator>>=) + +#undef VECTORIZEDN_DEFINE_UNARY_OP_GLOBAL +#undef VECTORIZEDN_DEFINE_BINARY_OP_GLOBAL +#undef VECTORIZEDN_DEFINE_BINARY_OP_INPLACE_GLOBAL + +template +inline T vec_reduce_all(const OpVec& vec_fun, VectorizedN acc_vec) { + Vectorized vec_result = acc_vec[0]; + for (int i = 1; i < N; i++) { + vec_result = vec_fun(vec_result, acc_vec[i]); + } + return vec_reduce_all(vec_fun, vec_result); +} + +template +std::ostream& operator<<(std::ostream& stream, const VectorizedN& vec_n) { + stream << "vec_n["; + for (int i = 0; i < N; ++i) { + if (i != 0) { + stream << ", "; + } + stream << vec_n[i]; + } + stream << ']'; + return stream; +} +} // namespace CPU_CAPABILITY +} // namespace at::vec diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vml.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vml.h new file mode 100644 index 0000000000000000000000000000000000000000..26547e99a1b576ce2892f1fd772fd2e5b59828e0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cpu/vml.h @@ -0,0 +1,170 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + +// This header implements various unary operations using a MKL VML style +// interface. + +// It implements various functions with a simple interface +// For example it enables the user to call vsin(float* out, const float* in, +// size) This functions takes a pointer to a continuous output array of floats and +// a constant input array. It will then apply sin to each value in the input +// array and write the result into the output array. out and in may point to the +// same memory, i.e. this fully supports in-place operations. These functions +// also implement their own parallelization, so take precautions when calling +// these from threaded functions. + +// When MKL is available it will call into MKL's VML library similar to NumPy +// If MKL is not available it will use SLEEF. + +// This file might be compiled under AVX or AVX2 when called from e.g. +// UnaryOpsKernel.cpp + +#include +#include +#include +#include +#include + +#if AT_MKL_ENABLED() && !defined(__APPLE__) +#include +#endif + + +namespace at::vml { +inline namespace CPU_CAPABILITY { + +using namespace vec; + +template +inline void vrsqrt(scalar_t* out, scalar_t* in, int64_t size) { + parallel_for(0, size, 2048, [out, in](int64_t begin, int64_t end) { + map( + [](const Vectorized& x) { + return Vectorized((scalar_t)(1)) / x.sqrt(); + }, + out + begin, + in + begin, + end - begin); + }); +} + +// NB: We ignore numerical errors by convention and leave them to the user + +#define IMPLEMENT_VML(op) \ + template \ + inline void v##op(scalar_t* out, const scalar_t* in, int64_t size) { \ + using vec_t = Vectorized>; \ + vec::map([](vec_t x) { return x.op(); }, out, in, size); \ + } \ + +IMPLEMENT_VML(abs) +IMPLEMENT_VML(acos) +IMPLEMENT_VML(asin) +IMPLEMENT_VML(atan) +IMPLEMENT_VML(atanh) +IMPLEMENT_VML(ceil) +IMPLEMENT_VML(cos) +// IMPLEMENT_VML(cosh) +IMPLEMENT_VML(erf) +IMPLEMENT_VML(erfc) +IMPLEMENT_VML(erfinv) +IMPLEMENT_VML(exp) +IMPLEMENT_VML(expm1) +IMPLEMENT_VML(floor) +IMPLEMENT_VML(i0) +IMPLEMENT_VML(i0e) +IMPLEMENT_VML(digamma) +IMPLEMENT_VML(reciprocal) +IMPLEMENT_VML(log) +IMPLEMENT_VML(log10) +IMPLEMENT_VML(log1p) +IMPLEMENT_VML(log2) +IMPLEMENT_VML(neg) +IMPLEMENT_VML(sin) +// IMPLEMENT_VML(sinh) +IMPLEMENT_VML(sqrt) +IMPLEMENT_VML(round) +IMPLEMENT_VML(rsqrt) +IMPLEMENT_VML(tan) +IMPLEMENT_VML(tanh) +IMPLEMENT_VML(trunc) +IMPLEMENT_VML(lgamma) + + +#if AT_MKL_ENABLED() && !defined(__APPLE__) + +// NB: LP64 MKL is the most commonly used and thus we assume it here. That means +// we need to expect MKL_INT to be of type int, which implies int32_t or int64_t in most +// cases. +static_assert( + std::is_same_v || std::is_same_v, + "MKL_INT is assumed to be int32_t or int64_t"); +#define IMPLEMENT_VML_MKL_STUB(op, mklop, type, mkltype) \ + template <> \ + inline void v##op(type * out, const type * in, int64_t size) { \ + auto constexpr max_mkl_ind = std::numeric_limits::max(); \ + if (size <= static_cast(max_mkl_ind)) { \ + vm##mkltype##mklop( \ + size, in, out, VML_HA | VML_FTZDAZ_OFF | VML_ERRMODE_IGNORE); \ + } else { \ + int64_t ind = 0; \ + int64_t chunks = size / max_mkl_ind; \ + int64_t rest = size % max_mkl_ind; \ + for (; ind < chunks; ind++) { \ + vm##mkltype##mklop( \ + max_mkl_ind, \ + in + ind * max_mkl_ind, \ + out + ind * max_mkl_ind, \ + VML_HA | VML_FTZDAZ_OFF | VML_ERRMODE_IGNORE); \ + } \ + vm##mkltype##mklop( \ + rest, \ + in + ind * max_mkl_ind, \ + out + ind * max_mkl_ind, \ + VML_HA | VML_FTZDAZ_OFF | VML_ERRMODE_IGNORE); \ + } \ + } + +#define IMPLEMENT_VML_MKL(op, mklop) \ + IMPLEMENT_VML_MKL_STUB(op, mklop, float, s) \ + IMPLEMENT_VML_MKL_STUB(op, mklop, double, d) + +// NB: abs, cosh and sinh were temporarily disabled due to issues with Apple +// NB: expm1 is disabled because on some configs it produces expm1(nan)=-1 +IMPLEMENT_VML_MKL(acos, Acos) +IMPLEMENT_VML_MKL(asin, Asin) +IMPLEMENT_VML_MKL(atan, Atan) +IMPLEMENT_VML_MKL(cos, Cos) +// IMPLEMENT_VML_MKL(cosh, Cosh) +IMPLEMENT_VML_MKL(erf, Erf) +IMPLEMENT_VML_MKL(erfc, Erfc) +IMPLEMENT_VML_MKL(erfinv, ErfInv) +IMPLEMENT_VML_MKL(exp, Exp) +// IMPLEMENT_VML_MKL(expm1, Expm1) +IMPLEMENT_VML_MKL(log, Ln) +IMPLEMENT_VML_MKL(log10, Log10) +IMPLEMENT_VML_MKL(sin, Sin) +// IMPLEMENT_VML_MKL(sinh, Sinh) +IMPLEMENT_VML_MKL(sqrt, Sqrt) +IMPLEMENT_VML_MKL(tan, Tan) +IMPLEMENT_VML_MKL(tanh, Tanh) +IMPLEMENT_VML_MKL(trunc, Trunc) + +// Not vectorized in MKL version tested +// IMPLEMENT_VML_MKL(abs, Abs) +// IMPLEMENT_VML_MKL(log1p, Log1p) + +#if INTEL_MKL_VERSION >= 20180406 +IMPLEMENT_VML_MKL(log2, Log2) +#endif + +#endif + +} // namespace +} // namespace at::vml diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ATenCUDAGeneral.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ATenCUDAGeneral.h new file mode 100644 index 0000000000000000000000000000000000000000..c64643546a2c1097a7a323dafc6cf5079d1b2fd9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ATenCUDAGeneral.h @@ -0,0 +1,9 @@ +#pragma once + +#include +#include +#include + +#include + +// Use TORCH_CUDA_CPP_API or TORCH_CUDA_CU_API for exports from this folder diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ApplyGridUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ApplyGridUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..b0b1412298d7b65bd0354d234bbddd09f19031a7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ApplyGridUtils.cuh @@ -0,0 +1,47 @@ +#include + +#include + +namespace at::cuda { + +/** + Computes ceil(a / b) +*/ +template +__host__ __device__ __forceinline__ T ATenCeilDiv(T a, T b) { + return (a + b - 1) / b; +} + +namespace { + +// Threads per block for our apply kernel +// FIXME: use occupancy calculator instead +constexpr uint32_t AT_APPLY_THREADS_PER_BLOCK = 512; +constexpr uint32_t AT_APPLY_BLOCKS_PER_SM = 4; + +template +inline bool getApplyGrid(uint64_t totalElements, dim3& grid, c10::DeviceIndex curDevice, int max_threads_per_block=AT_APPLY_THREADS_PER_BLOCK) { + if (curDevice == -1) return false; + uint64_t numel_per_thread = static_cast(max_threads_per_block) * static_cast(step); + uint64_t numBlocks = ATenCeilDiv(totalElements, numel_per_thread); + uint64_t maxGridX = at::cuda::getDeviceProperties(curDevice)->maxGridSize[0]; + if (numBlocks > maxGridX) + numBlocks = maxGridX; + grid = dim3(numBlocks); + return true; +} + +constexpr int getApplyBlocksPerSM() { + return AT_APPLY_BLOCKS_PER_SM; +} + +constexpr int getApplyBlockSize() { + return AT_APPLY_THREADS_PER_BLOCK; +} + +inline dim3 getApplyBlock(int max_threads_per_block=AT_APPLY_THREADS_PER_BLOCK) { + return dim3(max_threads_per_block); +} + +} // anonymous namespace +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/AsmUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/AsmUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..8bd897e64c4fdcdf6bd32c0b176ce2414ebe9438 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/AsmUtils.cuh @@ -0,0 +1,149 @@ +#pragma once +#include + +// Collection of direct PTX functions + +namespace at::cuda { + +template +struct Bitfield {}; + +template <> +struct Bitfield { + static __device__ __host__ __forceinline__ + unsigned int getBitfield(unsigned int val, int pos, int len) { +#if !defined(__CUDA_ARCH__) + pos &= 0xff; + len &= 0xff; + + unsigned int m = (1u << len) - 1u; + return (val >> pos) & m; +#else + unsigned int ret; + asm("bfe.u32 %0, %1, %2, %3;" : "=r"(ret) : "r"(val), "r"(pos), "r"(len)); + return ret; +#endif + } + + static __device__ __host__ __forceinline__ + unsigned int setBitfield(unsigned int val, unsigned int toInsert, int pos, int len) { +#if !defined(__CUDA_ARCH__) + pos &= 0xff; + len &= 0xff; + + unsigned int m = (1u << len) - 1u; + toInsert &= m; + toInsert <<= pos; + m <<= pos; + + return (val & ~m) | toInsert; +#else + unsigned int ret; + asm("bfi.b32 %0, %1, %2, %3, %4;" : + "=r"(ret) : "r"(toInsert), "r"(val), "r"(pos), "r"(len)); + return ret; +#endif + } +}; + +template <> +struct Bitfield { + static __device__ __host__ __forceinline__ + uint64_t getBitfield(uint64_t val, int pos, int len) { +#if !defined(__CUDA_ARCH__) + pos &= 0xff; + len &= 0xff; + + uint64_t m = (1u << len) - 1u; + return (val >> pos) & m; +#else + uint64_t ret; + asm("bfe.u64 %0, %1, %2, %3;" : "=l"(ret) : "l"(val), "r"(pos), "r"(len)); + return ret; +#endif + } + + static __device__ __host__ __forceinline__ + uint64_t setBitfield(uint64_t val, uint64_t toInsert, int pos, int len) { +#if !defined(__CUDA_ARCH__) + pos &= 0xff; + len &= 0xff; + + uint64_t m = (1u << len) - 1u; + toInsert &= m; + toInsert <<= pos; + m <<= pos; + + return (val & ~m) | toInsert; +#else + uint64_t ret; + asm("bfi.b64 %0, %1, %2, %3, %4;" : + "=l"(ret) : "l"(toInsert), "l"(val), "r"(pos), "r"(len)); + return ret; +#endif + } +}; + +__device__ __forceinline__ int getLaneId() { +#if defined(USE_ROCM) + return __lane_id(); +#else + int laneId; + asm("mov.s32 %0, %%laneid;" : "=r"(laneId) ); + return laneId; +#endif +} + +#if defined(USE_ROCM) +__device__ __forceinline__ unsigned long long int getLaneMaskLt() { + const std::uint64_t m = (1ull << getLaneId()) - 1ull; + return m; +} +#else +__device__ __forceinline__ unsigned getLaneMaskLt() { + unsigned mask; + asm("mov.u32 %0, %%lanemask_lt;" : "=r"(mask)); + return mask; +} +#endif + +#if defined (USE_ROCM) +__device__ __forceinline__ unsigned long long int getLaneMaskLe() { + std::uint64_t m = UINT64_MAX >> (sizeof(std::uint64_t) * CHAR_BIT - (getLaneId() + 1)); + return m; +} +#else +__device__ __forceinline__ unsigned getLaneMaskLe() { + unsigned mask; + asm("mov.u32 %0, %%lanemask_le;" : "=r"(mask)); + return mask; +} +#endif + +#if defined(USE_ROCM) +__device__ __forceinline__ unsigned long long int getLaneMaskGt() { + const std::uint64_t m = getLaneMaskLe(); + return m ? ~m : m; +} +#else +__device__ __forceinline__ unsigned getLaneMaskGt() { + unsigned mask; + asm("mov.u32 %0, %%lanemask_gt;" : "=r"(mask)); + return mask; +} +#endif + +#if defined(USE_ROCM) +__device__ __forceinline__ unsigned long long int getLaneMaskGe() { + const std::uint64_t m = getLaneMaskLt(); + return ~m; +} +#else +__device__ __forceinline__ unsigned getLaneMaskGe() { + unsigned mask; + asm("mov.u32 %0, %%lanemask_ge;" : "=r"(mask)); + return mask; +} +#endif + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/Atomic.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/Atomic.cuh new file mode 100644 index 0000000000000000000000000000000000000000..5a127b4d7507f98049d59a4c95386ffeb8b1c4f1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/Atomic.cuh @@ -0,0 +1,514 @@ +#pragma once + +#include +#include +#include + +#include + +#if !(defined(USE_ROCM) || ((defined(__CUDA_ARCH__) && (__CUDA_ARCH__ < 800)))) +#include +#endif + +template +struct AtomicFPOp; + +template <> +struct AtomicFPOp { + template + inline __device__ at::Half operator() (at::Half *address, at::Half val, const func_t& func) { + unsigned int * address_as_ui = + (unsigned int *) ((char *)address - ((size_t)address & 2)); + unsigned int old = *address_as_ui; + unsigned int assumed; + + at::Half hsum; + do { + assumed = old; + hsum.x = (size_t)address & 2 ? (old >> 16) : (old & 0xffff); + hsum = func(hsum, val); + old = (size_t)address & 2 ? (old & 0xffff) | (hsum.x << 16) : (old & 0xffff0000) | hsum.x; + old = atomicCAS(address_as_ui, assumed, old); + } while (assumed != old); + hsum.x = (size_t)address & 2 ? (old >> 16) : (old & 0xffff); + return hsum; + } +}; + +template <> +struct AtomicFPOp { + template + inline __device__ at::BFloat16 operator() (at::BFloat16 *address, at::BFloat16 val, const func_t& func) { + unsigned int * address_as_ui = + (unsigned int *) ((char *)address - ((size_t)address & 2)); + unsigned int old = *address_as_ui; + unsigned int assumed; + + at::BFloat16 bsum; + do { + assumed = old; + bsum.x = (size_t)address & 2 ? (old >> 16) : (old & 0xffff); + bsum = func(bsum, val); + old = (size_t)address & 2 ? (old & 0xffff) | (bsum.x << 16) : (old & 0xffff0000) | bsum.x; + old = atomicCAS(address_as_ui, assumed, old); + } while (assumed != old); + bsum.x = (size_t)address & 2 ? (old >> 16) : (old & 0xffff); + return bsum.x; + } +}; + +template <> +struct AtomicFPOp { + template + inline __device__ double operator() (double * address, double val, const func_t& func) { + unsigned long long int* address_as_ull = (unsigned long long int*)address; + unsigned long long int old = *address_as_ull; + unsigned long long int assumed; + + do { + assumed = old; + old = atomicCAS(address_as_ull, assumed, func(val, assumed)); + // Note: uses integer comparison to avoid hang in case of NaN (since NaN != NaN) + } while (assumed != old); + + return __longlong_as_double(old); + } +}; + +#define ATOMIC_INTEGER_IMPL(NAME) \ +template \ +struct Atomic##NAME##IntegerImpl; \ + \ +template \ +struct Atomic##NAME##IntegerImpl { \ + template \ + inline __device__ void operator()(T *address, T val, const func_t& func) { \ + size_t offset = (size_t)address & 3; \ + uint32_t * address_as_ui = (uint32_t *)((char *)address - offset); \ + uint32_t old = *address_as_ui; \ + uint32_t shift = offset * 8; \ + uint32_t old_byte; \ + uint32_t newval; \ + uint32_t assumed; \ + \ + do { \ + assumed = old; \ + old_byte = (old >> shift) & 0xff; \ + newval = static_cast(func(val, static_cast(old_byte))); \ + newval = (old & ~(0x000000ff << shift)) | (newval << shift); \ + old = atomicCAS(address_as_ui, assumed, newval); \ + } while (assumed != old); \ + } \ +}; \ + \ +template \ +struct Atomic##NAME##IntegerImpl { \ + template \ + inline __device__ void operator()(T *address, T val, const func_t& func) { \ + size_t offset = (size_t)address & 2; \ + uint32_t * address_as_ui = (uint32_t *)((char *)address - offset); \ + bool is_32_align = offset; \ + uint32_t old = *address_as_ui; \ + uint32_t old_bytes; \ + uint32_t newval; \ + uint32_t assumed; \ + \ + do { \ + assumed = old; \ + old_bytes = is_32_align ? old >> 16 : old & 0xffff; \ + newval = static_cast(func(val, static_cast(old_bytes))); \ + newval = is_32_align ? (old & 0xffff) | (newval << 16) : (old & 0xffff0000) | newval; \ + old = atomicCAS(address_as_ui, assumed, newval); \ + } while (assumed != old); \ + } \ +}; \ + \ +template \ +struct Atomic##NAME##IntegerImpl { \ + template \ + inline __device__ void operator()(T *address, T val, const func_t& func) { \ + uint32_t * address_as_ui = (uint32_t *) (address); \ + uint32_t old = *address_as_ui; \ + uint32_t newval; \ + uint32_t assumed; \ + \ + do { \ + assumed = old; \ + newval = static_cast(func(val, static_cast(old))); \ + old = atomicCAS(address_as_ui, assumed, newval); \ + } while (assumed != old); \ + } \ +}; \ + \ +template \ +struct Atomic##NAME##IntegerImpl { \ + template \ + inline __device__ void operator()(T *address, T val, const func_t& func) { \ + unsigned long long * address_as_ui = (unsigned long long *) (address); \ + unsigned long long old = *address_as_ui; \ + unsigned long long newval; \ + unsigned long long assumed; \ + \ + do { \ + assumed = old; \ + newval = static_cast(func(val, static_cast(old))); \ + old = atomicCAS(address_as_ui, assumed, newval); \ + } while (assumed != old); \ + } \ +}; + + +# define GPU_ATOMIC_INTEGER(NAME, OP, DTYPE) \ +inline __device__ void gpuAtomic##NAME(DTYPE *address, DTYPE val) { \ +Atomic##NAME##IntegerImpl()(address, \ + val, \ + [](DTYPE a, DTYPE b) { \ + return OP; \ + }); \ +} \ + +ATOMIC_INTEGER_IMPL(Add) +GPU_ATOMIC_INTEGER(Add, a || b, bool) + +// Don't instantiate gpuAtomicAdd with the macro as it seems non-standard (see int32, int64) +inline __device__ void gpuAtomicAdd(uint8_t *address, uint8_t val) { + AtomicAddIntegerImpl()(address, + val, + [](uint8_t a, uint8_t b) { + return a + b; + }); +} + +inline __device__ void gpuAtomicAdd(int8_t *address, int8_t val) { + AtomicAddIntegerImpl()(address, + val, + [](int8_t a, int8_t b) { + return a + b; + }); +} + +inline __device__ void gpuAtomicAdd(int16_t *address, int16_t val) { + AtomicAddIntegerImpl()(address, + val, + [](int16_t a, int16_t b) { + return a + b; + }); +} + +inline __device__ int32_t gpuAtomicAdd(int32_t *address, int32_t val) { + return atomicAdd(address, val); +} + +inline __device__ void gpuAtomicAdd(int64_t *address, int64_t val) { +#if defined(USE_ROCM) + __atomic_fetch_add(address, val, __ATOMIC_RELAXED); +#else + static_assert(sizeof(unsigned long long int) == sizeof(int64_t), "bitwidth change is not allowed"); + atomicAdd(reinterpret_cast(address), static_cast(val)); +#endif +} + +inline __device__ at::Half gpuAtomicAdd(at::Half *address, at::Half val) { +#if defined(USE_ROCM) || ((defined(__CUDA_ARCH__) && (__CUDA_ARCH__ < 700))) + return AtomicFPOp()(address, val, + [](at::Half hsum, at::Half val) { + return hsum + val; + }); +#else + return atomicAdd(reinterpret_cast<__half*>(address), val); +#endif +} + +inline __device__ at::BFloat16 gpuAtomicAdd(at::BFloat16 *address, at::BFloat16 val) { +#if defined(USE_ROCM) || ((defined(__CUDA_ARCH__) && (__CUDA_ARCH__ < 800))) +return AtomicFPOp()(address, val, + [](at::BFloat16 bsum, at::BFloat16 val) { + return bsum + val; + }); +#else + __nv_bfloat16 r = atomicAdd(reinterpret_cast<__nv_bfloat16*>(address), *reinterpret_cast<__nv_bfloat16*>(&val)); + return *reinterpret_cast(&r); +#endif +} + +#if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ < 600) +// from CUDA C Programmic Guide +inline __device__ double atomicAdd(double* address, double val) +#if defined(__clang__) && defined(__CUDA__) +#pragma GCC diagnostic push +#pragma GCC diagnostic ignored "-Wgcc-compat" + __attribute__((enable_if(true, ""))) +#pragma GCC diagnostic pop +#endif +{ + + return AtomicFPOp()(address, val, + [](double val, unsigned long long int assumed) { + return __double_as_longlong(val + __longlong_as_double(assumed)); + }); +} +#elif defined(USE_ROCM) || !(defined(__CUDA_ARCH__)) + +/* Note [hip-clang differences to hcc] + * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + * The upcoming hip-clang compiler for ROCm differs from hcc in a few details. + * It exports the __HIP__ macro, we can hence differentiate between hcc and + * hip-clang. In the below, hcc only received support for atomicAdd with double + * typing after work week 18312. hip-clang had support from the first version. + * In general, the code-visible differences between hip-clang and hcc will be + * minimal. + */ + +#if defined(USE_ROCM) && __hcc_workweek__ < 18312 && !__HIP__ + // This needs to be defined for the host side pass + inline __device__ double atomicAdd(double *address, double val) { } +#endif +#endif + +inline __device__ double gpuAtomicAdd(double *address, double val) { + return atomicAdd(address, val); +} + +inline __device__ float gpuAtomicAdd(float *address, float val) { + return atomicAdd(address, val); +} + +template +inline __device__ void gpuAtomicAdd(c10::complex *address, c10::complex val) { + gpuAtomicAdd(&address->real_, val.real_); + gpuAtomicAdd(&address->imag_, val.imag_); +} + +/* Note [gpuAtomicAdd vs atomicAdd] + * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + * Some extensions such as torchvision call atomicAdd() + * directly and require non-library provided data type support. Only for these, we + * continue to provide atomicAdd overloads. + */ +inline __device__ at::Half atomicAdd(at::Half *address, at::Half val) { + return gpuAtomicAdd(address, val); +} + +inline __device__ at::BFloat16 atomicAdd(at::BFloat16 *address, at::BFloat16 val) { + return gpuAtomicAdd(address, val); +} + +inline __device__ void atomicAdd(uint8_t *address, uint8_t val) { + gpuAtomicAdd(address, val); +} + +inline __device__ void atomicAdd(int8_t *address, int8_t val) { + gpuAtomicAdd(address, val); +} + +inline __device__ void atomicAdd(int16_t *address, int16_t val) { + gpuAtomicAdd(address, val); +} + +inline __device__ void atomicAdd(int64_t *address, int64_t val) { + gpuAtomicAdd(address, val); +} + +inline __device__ void atomicAdd(bool *address, bool val) { + gpuAtomicAdd(address, val); +} + +/* Note [explicitly non-returning atomics] + * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + * AMD's MI100 (gfx908) provides an optimized fp32 atomicAdd, exposed via atomicAddNoRet(). + * Due to compiler limitations, callers must opt-in to guarantee the optimized instruction. + * This non-returning atomicAddNoRet cannot be used to implement the returning atomicAdd, + * therefore we need a new API 'gpuAtomicAddNoReturn'. + */ +template +inline __device__ void gpuAtomicAddNoReturn(c10::complex *address, c10::complex val) { gpuAtomicAdd(address, val); } +inline __device__ void gpuAtomicAddNoReturn(uint8_t *address, uint8_t val) { gpuAtomicAdd(address, val); } +inline __device__ void gpuAtomicAddNoReturn(int8_t *address, int8_t val) { gpuAtomicAdd(address, val); } +inline __device__ void gpuAtomicAddNoReturn(int16_t *address, int16_t val) { gpuAtomicAdd(address, val); } +inline __device__ void gpuAtomicAddNoReturn(int32_t *address, int32_t val) { gpuAtomicAdd(address, val); } +inline __device__ void gpuAtomicAddNoReturn(int64_t *address, int64_t val) { gpuAtomicAdd(address, val); } +inline __device__ void gpuAtomicAddNoReturn(bool *address, bool val) { gpuAtomicAdd(address, val); } +inline __device__ void gpuAtomicAddNoReturn(at::Half *address, at::Half val) { gpuAtomicAdd(address, val); } +inline __device__ void gpuAtomicAddNoReturn(at::BFloat16 *address, at::BFloat16 val) { gpuAtomicAdd(address, val); } +inline __device__ void gpuAtomicAddNoReturn(double *address, double val) { gpuAtomicAdd(address, val); } + +/* Special case fp32 atomic. */ +#if defined(USE_ROCM) +inline __device__ void gpuAtomicAddNoReturn(float *address, float val) { +#if defined(__gfx908__) + atomicAddNoRet(address, val); +#else + (void)unsafeAtomicAdd(address, val); +#endif +} +#else +inline __device__ void gpuAtomicAddNoReturn(float *address, float val) { gpuAtomicAdd(address, val); } +#endif + +// Atomic multiplication implementation. + +ATOMIC_INTEGER_IMPL(Mul) +GPU_ATOMIC_INTEGER(Mul, a * b, uint8_t) +GPU_ATOMIC_INTEGER(Mul, a * b, int8_t) +GPU_ATOMIC_INTEGER(Mul, a * b, int16_t) +GPU_ATOMIC_INTEGER(Mul, a * b, int32_t) +GPU_ATOMIC_INTEGER(Mul, a * b, int64_t) + +inline __device__ at::Half gpuAtomicMul(at::Half * address, at::Half val) { + return AtomicFPOp()(address, val, + [](at::Half bsum, at::Half val) { + return bsum * val; + }); +} + +inline __device__ at::BFloat16 gpuAtomicMul(at::BFloat16 * address, at::BFloat16 val) { + return AtomicFPOp()(address, val, + [](at::BFloat16 bsum, at::BFloat16 val) { + return bsum * val; + }); +} + +inline __device__ double gpuAtomicMul(double * address, double val) { + return AtomicFPOp()(address, val, + [](double val, unsigned long long int assumed) { + return __double_as_longlong(val * __longlong_as_double(assumed)); + }); +} + +// Dont use a templated function for this since the addition function defaults to the CUDA built-in. +inline __device__ float gpuAtomicMul (float * address, float val) { + unsigned int* address_as_ull = (unsigned int*)address; + unsigned int old = *address_as_ull; + unsigned int assumed; + + do { + assumed = old; + old = atomicCAS(address_as_ull, assumed, + __float_as_int(val * + __int_as_float(assumed))); + + // Note: uses integer comparison to avoid hang in case of NaN (since NaN != NaN) + } while (assumed != old); + + return __int_as_float(old); +} + +// Atomic maximum implementation. + +template +__host__ __device__ T safe_max(T a, T b) { + #if defined(__HIPCC__) + // TODO: remove this special case for HIP when issue is fixed: + // https://github.com/ROCm-Developer-Tools/HIP/issues/2209 + T max = at::_isnan(a) ? a : (at::_isnan(b) ? b : std::max(a, b)); + #else + T max = at::_isnan(b) ? b : std::max(a, b); + #endif + + return max; +} + +ATOMIC_INTEGER_IMPL(Max) +GPU_ATOMIC_INTEGER(Max, safe_max(a, b), uint8_t) +GPU_ATOMIC_INTEGER(Max, safe_max(a, b), int8_t) +GPU_ATOMIC_INTEGER(Max, safe_max(a, b), int16_t) +GPU_ATOMIC_INTEGER(Max, safe_max(a, b), int32_t) +GPU_ATOMIC_INTEGER(Max, safe_max(a, b), int64_t) + +inline __device__ at::Half gpuAtomicMax(at::Half * address, at::Half val) { + return AtomicFPOp()(address, val, + [](at::Half bsum, at::Half val) { + return safe_max(bsum, val); + }); +} + +inline __device__ at::BFloat16 gpuAtomicMax(at::BFloat16 * address, at::BFloat16 val) { + return AtomicFPOp()(address, val, + [](at::BFloat16 bsum, at::BFloat16 val) { + return safe_max(bsum, val); + }); +} + +inline __device__ double gpuAtomicMax(double * address, double val) { + return AtomicFPOp()(address, val, + [](double val, unsigned long long int assumed) { + return __double_as_longlong(safe_max(val, __longlong_as_double(assumed))); + }); +} + +// Dont use a templated function for this since the addition function defaults to the CUDA built-in. +inline __device__ float gpuAtomicMax(float * address, float val) { + unsigned int* address_as_ull = (unsigned int*)address; + unsigned int old = *address_as_ull; + unsigned int assumed; + + do { + assumed = old; + old = atomicCAS(address_as_ull, assumed, + __float_as_int(safe_max(val, __int_as_float(assumed)))); + + // Note: uses integer comparison to avoid hang in case of NaN (since NaN != NaN) + } while (assumed != old); + + return __int_as_float(old); +} + +// Atomic minimum implementation. + +template +__host__ __device__ T safe_min(T a, T b) { + #if defined(__HIPCC__) + // TODO: remove this special case for HIP when issue is fixed: + // https://github.com/ROCm-Developer-Tools/HIP/issues/2209 + T min = at::_isnan(a) ? a : (at::_isnan(b) ? b : std::min(a, b)); + #else + T min = at::_isnan(b) ? b : std::min(a, b); + #endif + + return min; +} + +ATOMIC_INTEGER_IMPL(Min) +GPU_ATOMIC_INTEGER(Min, safe_min(a, b), uint8_t) +GPU_ATOMIC_INTEGER(Min, safe_min(a, b), int8_t) +GPU_ATOMIC_INTEGER(Min, safe_min(a, b), int16_t) +GPU_ATOMIC_INTEGER(Min, safe_min(a, b), int32_t) +GPU_ATOMIC_INTEGER(Min, safe_min(a, b), int64_t) + +inline __device__ at::Half gpuAtomicMin(at::Half * address, at::Half val) { + return AtomicFPOp()(address, val, + [](at::Half bsum, at::Half val) { + return safe_min(bsum, val); + }); +} + +inline __device__ at::BFloat16 gpuAtomicMin(at::BFloat16 * address, at::BFloat16 val) { + return AtomicFPOp()(address, val, + [](at::BFloat16 bsum, at::BFloat16 val) { + return safe_min(bsum, val); + }); +} + +inline __device__ double gpuAtomicMin(double * address, double val) { + return AtomicFPOp()(address, val, + [](double val, unsigned long long int assumed) { + return __double_as_longlong(safe_min(val, __longlong_as_double(assumed))); + }); +} + +// Dont use a templated function for this since the addition function defaults to the CUDA built-in. +inline __device__ float gpuAtomicMin(float * address, float val) { + unsigned int* address_as_ull = (unsigned int*)address; + unsigned int old = *address_as_ull; + unsigned int assumed; + + do { + assumed = old; + old = atomicCAS(address_as_ull, assumed, + __float_as_int(safe_min(val, __int_as_float(assumed)))); + + // Note: uses integer comparison to avoid hang in case of NaN (since NaN != NaN) + } while (assumed != old); + + return __int_as_float(old); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAApplyUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAApplyUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..4dcdabf17b3b90ad598db48f7210e3932142aaad --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAApplyUtils.cuh @@ -0,0 +1,537 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include + +#include + +// +// This file contains pointwise operation functions and kernels that +// work on both contiguous and non-contiguous tensor arguments of +// arbitrary (up to MAX_CUTORCH_DIMS) dimensioned arguments without +// copying or temporary storage. +// + +/* + NOTE [ CUDA_tensor_applyN helpers ] + + The following CUDA_tensor_applyN (where N currently can be 1, 2, 3, or 4) + functions apply a pointwise operator to N tensor(s). + + The calling convention is + + 1. The template arguments should be, sequentially, + - First N typename args specify the scalar types of each of the N tensors. + - (Optional) `int step` arg specifies the number of elements processed + together at the same time. + Default is 1. + - A usually omitted (i.e., inferred) typename arg specifies the type of the + function/functor applied on `N * step` values in each iteration of each + CUDA thread. + 2. The arguments should be, sequentially, + - N tensors + - op: a function/functor that processes `N * step` values at the same time. + - If `step == 1`, it must have signature + `void(*)(scalar1_t&, scalar2_t&, ..., scalarN_t&)`, where + `scalar*_t`s are the first N typename template args, and the inputs + are the `N` values from the `N` tensors retrieved at a common index. + - Otherwise, it must must have signature + void(*)(int n, scalar1_t&, scalar1_t&, ..., scalar1_t&, // repeat `step` times + scalar2_t&, scalar2_t&, ..., scalar2_t&, // repeat `step` times + ..., + scalarN_t&, scalarN_t&, ..., scalarN_t&) // repeat `step` times + Different from `step == 1` case, it processes `N * step` values taken + from `step` common indices. Moreover, the first input `n` represents the + number of valid indices (it will always have `0 < n <= step`). It will + almost always be `step`, but at the boundary we may not have full `step` + elements and `n` can be a lesser value. + + E.g., if `step == 4` and `N == 2`, `op` could be + + [](int n, scalar1_t &u1, scalar1_t &u2, scalar1_t &u3, scalar1_t &u4, + scalar2_t &v1, scalar2_t &v2, scalar2_t &v3, scalar2_t &v4) { + // Only process u1, ..., un and v1, ..., vn. + // So if `n == 3`, `u4` and `v4` need not to be considered. + } + + In both cases, the references can actually be const, but at least one of + them should be non-const in order to write the output. + - (Optional, but recommended) N TensorArgType args that specify for each + tensor whether `op` reads AND writes ] (i.e., TensorArgType::ReadWrite), + or only reads (i.e., TensorArgType::ReadOnly). + Default is TensorArgType::ReadWrite for first Tensor, and + TensorArgType::ReadOnly for the rest. + + E.g., + + to compute a = b^2 for a and b of same dtype, we can call + + CUDA_tensor_apply2( + a, b, + [] __device__ (scalar &a_val, const scalar &b_val) { a_val = b_val * b_val; } + ); + + to work on 2 values at the same time, we can call + + CUDA_tensor_apply2( + a, b, + [] __device__ (int n, scalar1 &a_val1, scalar1 &a_val2, + const scalar2 &b_val1, const scalar2 &b_val2) { + // call special vectorized op here, or just do elementwise and enjoy unrolling... + // if n == 1, only process a_val1 and b_val1 + } + ); +*/ + +namespace at::cuda { + +// TODO: combine with TensorArg? So far that's been for debugging, and this is functional... +enum class TensorArgType { ReadWrite, ReadOnly }; + +namespace { + +// Rearrange dimensions for pointwise operations so that strides are in +// decreasing order as much as possible, so that kernels have better memory +// access patterns. +// +// For example, consider a binary operation on two "transposed" 2-dim tensors: +// sizes: 256 512 +// aInfo->strides: 1 256 +// bInfo->strides: 1 256 +// +// Given this, each concurrent memory access inside kernelPointwiseApply2() is +// exactly 256 elements apart, resulting in poor performance. +// +// This function exchanges dimensions so that memory access is contiguous: +// sizes: 512 256 +// aInfo->strides: 256 1 +// bInfo->strides: 256 1 +// +// (Actually, it becomes even better because now collapseDims() can turn each +// input into one contiguous array.) +// +// In general, given M (<=4) TensorInfo's with N dimensions, we can view each +// strides[i] (0 <= i < N) as an M-tuple. Given each pair i < j, we exchange +// strides[i] and [j] if +// (1) strides[i][k] < strides[j][k] for some k (0 <= k < M) +// (exchanging them will benefit input #k), and +// (2) strides[i][k] <= strieds[j][k] for all k +// (exchanging them will not make any input worse). +template +inline void rearrangeDims(detail::TensorInfo* aInfo, + detail::TensorInfo* bInfo = nullptr, + detail::TensorInfo* cInfo = nullptr, + detail::TensorInfo* dInfo = nullptr) { + int numInfos = 1; + int dims = aInfo->dims; + IndexType *sizes[4] = { aInfo->sizes, }; + IndexType *strides[4] = { aInfo->strides, }; + + if (bInfo != nullptr) { + ++numInfos; + if (bInfo->dims != dims) return; + sizes[1] = bInfo->sizes; + strides[1] = bInfo->strides; + } + + if (cInfo != nullptr) { + ++numInfos; + if (cInfo->dims != dims) return; + sizes[2] = cInfo->sizes; + strides[2] = cInfo->strides; + } + + if (dInfo != nullptr) { + ++numInfos; + if (dInfo->dims != dims) return; + sizes[3] = dInfo->sizes; + strides[3] = dInfo->strides; + } + + // Bail out if sizes do not match: we are using "deprecated pointwise + // behavior" among tensors of different shapes but same number of elements. + for (int i = 1; i < numInfos; ++i) { + for (int j = 0; j < dims; ++j) { + if (sizes[i][j] != sizes[0][j]) return; + } + } + + for (int i = 0; i < dims - 1; ++i) { + // No need to consider dimensions of size 1. + if (sizes[0][i] == 1) continue; + + for (int j = i + 1; j < dims; ++j) { + if (sizes[0][j] == 1) continue; + + // Compare the relative sizes of strides between dim #i and dim #j. + bool hasIncreasingStrides = false; + bool hasDecreasingStrides = false; + + for (int k = 0; k < numInfos; k++) { + IndexType stride_i = strides[k][i]; + IndexType stride_j = strides[k][j]; + if (stride_i < stride_j) { + hasIncreasingStrides = true; + } else if (stride_i > stride_j) { + hasDecreasingStrides = true; + } + } + + if (hasIncreasingStrides && !hasDecreasingStrides) { + for (int k = 0; k < numInfos; k++) { + IndexType size = sizes[k][i]; + sizes[k][i] = sizes[k][j]; + sizes[k][j] = size; + + IndexType stride = strides[k][i]; + strides[k][i] = strides[k][j]; + strides[k][j] = stride; + } + } + } + } +} + +// The `remaining_steps` argument is used to support Op that operates on +// multiple elements at the same time. Generally, the strategy of ApplyOpN is to +// 1. Initialize `remaining_steps = step`, where `step` is the template arg of +// CUDA_tensor_applyN helpers. The input arg `n` to `apply()` represents the +// number of elements in bound for this call. It will almost always equal to +// `step` except at boundaries. +// 2. If `remaining_steps > 0` convert the current linearIndex to offset (if in +// bound), and recursively call `ApplyOpN` with `remaining_steps - 1`. +// 3. At `remaining_steps = 0`, +// if `step = 1`, call `op(tensor1_val, tensor2_val, ...)`; +// if `step > 1`, call `op(n, tensor1_val1, tensor1_val2, ..., tesor1_valstep, +// tensor2_val1, tensor2_val2, ..., tesor2_valstep, +// ... +// tensorN_val1, tensorN_val2, ..., tesorN_valstep);` +// +// See NOTE [ CUDA_tensor_applyN helpers ] above for how Op may look like. + +template +struct ApplyOp1 { +__device__ __forceinline__ +static void apply(detail::TensorInfo &a, const Op &op, int n, + IndexType linearIndex, Offsets... aOffsets) { + // Convert `linearIndex` into an offset of `a` + const IndexType aOffset = sizeof...(Offsets) < n ? + detail::IndexToOffset::get(linearIndex, a) : 0; + + ApplyOp1::apply( + a, op, n, linearIndex + 1, aOffsets..., aOffset + ); +} +}; + +// Specialize `step=1` case (i.e., `remaining_steps=0` and `len(Offsets)=1`). +// We don't need to pass in how many elements need to processed in this case. +template +struct ApplyOp1 { +__device__ __forceinline__ +static void apply(detail::TensorInfo &a, const Op &op, + int n, IndexType linearIndex, Offset offset) { + op(a.data[offset]); +} +}; + +template +struct ApplyOp1 { +__device__ __forceinline__ +static void apply(detail::TensorInfo &a, const Op &op, int n, + IndexType linearIndex, Offsets... offsets) { + op(n, a.data[offsets]...); +} +}; + +template +#if __CUDA_ARCH__ >= 350 || defined(USE_ROCM) +C10_LAUNCH_BOUNDS_2(AT_APPLY_THREADS_PER_BLOCK, AT_APPLY_BLOCKS_PER_SM) +#endif +__global__ void kernelPointwiseApply1(detail::TensorInfo a, + IndexType totalElements, const Op op) { + for (IndexType linearIndex = (blockIdx.x * blockDim.x + threadIdx.x) * step; + linearIndex < totalElements; + linearIndex += gridDim.x * blockDim.x * step) { + ApplyOp1::apply( + a, op, ::min(step, static_cast(totalElements - linearIndex)), linearIndex); + } +} + + +template +struct ApplyOp2 { +__device__ __forceinline__ +static void apply(detail::TensorInfo &a, + detail::TensorInfo &b, + const Op &op, int64_t n, IndexType linearIndex, + Offsets... aOffsets, Offsets... bOffsets) { + // Convert `linearIndex` into an offset of `a` + const IndexType aOffset = static_cast(sizeof...(Offsets)) < n ? + detail::IndexToOffset::get(linearIndex, a) : 0; + + // Convert `linearIndex` into an offset of `b` + const IndexType bOffset = static_cast(sizeof...(Offsets)) < n ? + detail::IndexToOffset::get(linearIndex, b) : 0; + + ApplyOp2::apply( + a, b, op, n, linearIndex + 1, aOffsets..., aOffset, bOffsets..., bOffset + ); +} +}; + +// Specialize `step=1` case (i.e., `remaining_steps=0` and `len(Offsets)=1`). +// We don't need to pass in how many elements need to processed in this case. +template +struct ApplyOp2 { +__device__ __forceinline__ +static void apply(detail::TensorInfo &a, + detail::TensorInfo &b, + const Op &op, int /*n*/, IndexType /*linearIndex*/, + Offset aOffset, Offset bOffset) { + op(a.data[aOffset], b.data[bOffset]); +} +}; + +template +struct ApplyOp2 { +__device__ __forceinline__ +static void apply(detail::TensorInfo &a, + detail::TensorInfo &b, + const Op &op, int n, IndexType linearIndex, + Offsets... aOffsets, Offsets... bOffsets) { + op(n, a.data[aOffsets]..., b.data[bOffsets]...); +} +}; + +template +#if __CUDA_ARCH__ >= 350 || defined(USE_ROCM) +C10_LAUNCH_BOUNDS_2(max_threads_per_block, min_blocks_per_sm) +#endif +__global__ void +kernelPointwiseApply2(detail::TensorInfo a, + detail::TensorInfo b, + IndexType totalElements, + const Op op) { + for (IndexType linearIndex = (blockIdx.x * blockDim.x + threadIdx.x) * step; + linearIndex < totalElements; + linearIndex += gridDim.x * blockDim.x * step) { + ApplyOp2::apply( + a, b, op, ::min(step, static_cast(totalElements - linearIndex)), + linearIndex); + } +} + +} // anonymous namespace + +template +inline bool CUDA_tensor_apply2(at::TensorBase a, + at::TensorBase b, + const Op op, + TensorArgType aType = TensorArgType::ReadWrite, + TensorArgType bType = TensorArgType::ReadOnly) { + TORCH_CHECK(a.device().is_cuda() && b.device().is_cuda(), + "CUDA_tensor_apply2: Expected tensors to have CUDA DeviceType, but got " + "tensors with type ", a.device().type(), " and ", b.device().type()); + int64_t totalElements = a.numel(); + + if (totalElements != b.numel()) { + return false; + } + + if (a.dim() > MAX_TENSORINFO_DIMS || + b.dim() > MAX_TENSORINFO_DIMS) { + return false; + } + + if (a.numel() == 0) { + // Empty tensor; do nothing + return true; + } + const dim3 block = getApplyBlock(max_threads_per_block); + + dim3 grid; + auto curDevice = current_device(); + if (curDevice == -1) return false; + if (!getApplyGrid(totalElements, grid, curDevice, max_threads_per_block)) { + return false; + } + + /* + Expands readable/writable tensors whose indices may be "overlapped." + This ensures that each element of the tensor is operated on once and only + once. + */ + TensorBase oldA; + TensorBase oldB; + + if (aType == TensorArgType::ReadWrite && detail::maybeOverlappingIndices(a)) { + // Must perform in contiguous space + oldA = std::exchange(a, a.contiguous()); + } + if (bType == TensorArgType::ReadWrite && detail::maybeOverlappingIndices(b)) { + // Must perform in contiguous space + oldB = std::exchange(b, b.contiguous()); + } + + // It is possible that the tensor dimensions are able to be collapsed, + // and thus we can reduce the actual code complexity of the copy by + // exploiting this knowledge statically, since the div/mod is the + // most expensive part of the operation, more so than memory accesses. + // For instance, when copying a non-contiguous to a contiguous tensor + // (or vice versa), the contiguous tensor can be collapsed to one + // dimension, and the loop to translate the linear index to the array + // index can be similarly collapsed. That is what this unrolling is for. + +#define HANDLE_CASE(TYPE, A, B) \ + kernelPointwiseApply2 \ + <<>>( \ + aInfo, bInfo, static_cast(totalElements), op); \ + C10_CUDA_KERNEL_LAUNCH_CHECK(); + +#define HANDLE_B_CASE(TYPE, A, B) { \ + switch (B) { \ + case 1: \ + HANDLE_CASE(TYPE, A, 1); \ + break; \ + case 2: \ + HANDLE_CASE(TYPE, A, 2); \ + break; \ + default: \ + HANDLE_CASE(TYPE, A, -1); \ + break; \ + } \ +} + +#define HANDLE_A_CASE(TYPE, A, B) { \ + switch (A) { \ + case 1: \ + HANDLE_B_CASE(TYPE, 1, B); \ + break; \ + case 2: \ + HANDLE_B_CASE(TYPE, 2, B); \ + break; \ + default: \ + HANDLE_B_CASE(TYPE, -1, B); \ + break; \ + } \ +} + + if (detail::canUse32BitIndexMath(a) && + detail::canUse32BitIndexMath(b)) { + detail::TensorInfo aInfo = + detail::getTensorInfo(a); + + detail::TensorInfo bInfo = + detail::getTensorInfo(b); + rearrangeDims(&aInfo, &bInfo); + aInfo.collapseDims(); + bInfo.collapseDims(); + + HANDLE_A_CASE(unsigned int, aInfo.dims, bInfo.dims); + } else { + detail::TensorInfo aInfo = + detail::getTensorInfo(a); + + detail::TensorInfo bInfo = + detail::getTensorInfo(b); + rearrangeDims(&aInfo, &bInfo); + aInfo.collapseDims(); + bInfo.collapseDims(); + + /* + Only instantiates the all 1D special case and the fallback all nD case for + large (64-bit indexed) tensors to reduce compilation time. + */ + if (aInfo.dims == 1 && bInfo.dims == 1) { + HANDLE_CASE(uint64_t, 1, 1); + } else { + HANDLE_CASE(uint64_t, -1, -1); + } + } +#undef HANDLE_CASE +#undef HANDLE_B_CASE +#undef HANDLE_A_CASE + + if (oldA.defined()) { + at::native::copy_ignoring_overlaps(oldA, a); + } + + if (oldB.defined()) { + at::native::copy_ignoring_overlaps(oldB, b); + } + + return true; +} + +/* Provides default step = 1 to CUDA_tensor_apply2. */ +template +inline bool CUDA_tensor_apply2(const at::TensorBase &a, + const at::TensorBase &b, + const Op op, + TensorArgType aType = TensorArgType::ReadWrite, + TensorArgType bType = TensorArgType::ReadOnly) { + return CUDA_tensor_apply2(a, b, op, aType, bType); +} + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDABlas.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDABlas.h new file mode 100644 index 0000000000000000000000000000000000000000..6075e7b9c9d84586f4418696c138af4ab2cd582e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDABlas.h @@ -0,0 +1,360 @@ +#pragma once +/* + Provides a subset of CUDA BLAS functions as templates: + + gemm(transa, transb, m, n, k, alpha, a, lda, b, ldb, beta, c, + ldc) + + gemv(transa, m, n, alpha, a, lda, x, incx, beta, y, incy) + + dot(n, x, incx, y, incy, result) + + where Dtype is double, float, at::Half or at::BFloat16 (ROCm, NOT for dot). + The functions are available in at::cuda::blas namespace. + */ + +#include +#include + +namespace at::cuda::blas { + +// RAII guard that sets the CuBLAS pointer mode and restores it to +// its previous value when the guard is destroyed +class PointerModeGuard { +public: + PointerModeGuard(cublasHandle_t handle, cublasPointerMode_t mode) : + handle(handle) { + TORCH_CUDABLAS_CHECK(cublasGetPointerMode(handle, &previous_mode)); + TORCH_CUDABLAS_CHECK(cublasSetPointerMode(handle, mode)); + } + + ~PointerModeGuard() { + cublasSetPointerMode(handle, previous_mode); + } + +private: + cublasHandle_t handle; + cublasPointerMode_t previous_mode{}; +}; + +/* LEVEL 3 BLAS FUNCTIONS */ + +#define CUDABLAS_GEMM_ARGTYPES(Dtype) \ + char transa, char transb, int64_t m, int64_t n, int64_t k, at::opmath_type alpha, \ + const Dtype *a, int64_t lda, const Dtype *b, int64_t ldb, at::opmath_type beta,\ + Dtype *c, int64_t ldc + +#define CUDABLAS_GEMM_ARGS(Dtype) transa, transb, m, n, k, alpha, a, lda, b, ldb, beta, c, ldc + +template +inline void gemm(CUDABLAS_GEMM_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas::gemm: not implemented"); +} + +template <> +void gemm(CUDABLAS_GEMM_ARGTYPES(double)); +template <> +void gemm(CUDABLAS_GEMM_ARGTYPES(float)); +template <> +void gemm>(CUDABLAS_GEMM_ARGTYPES(c10::complex)); +template <> +void gemm>(CUDABLAS_GEMM_ARGTYPES(c10::complex)); +template <> +void gemm(CUDABLAS_GEMM_ARGTYPES(at::Half)); +template <> +void gemm(CUDABLAS_GEMM_ARGTYPES(at::BFloat16)); + +template +inline void gemm_internal(CUDABLAS_GEMM_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas::gemm_internal: not implemented"); +} + +template <> +void gemm_internal(CUDABLAS_GEMM_ARGTYPES(double)); +template <> +void gemm_internal(CUDABLAS_GEMM_ARGTYPES(float)); +template <> +void gemm_internal>(CUDABLAS_GEMM_ARGTYPES(c10::complex)); +template <> +void gemm_internal>(CUDABLAS_GEMM_ARGTYPES(c10::complex)); +template <> +void gemm_internal(CUDABLAS_GEMM_ARGTYPES(at::Half)); +template <> +void gemm_internal(CUDABLAS_GEMM_ARGTYPES(at::BFloat16)); + +enum GEMMAndBiasActivationEpilogue { + None, + RELU, + GELU, +}; + +// NOTE: GELU activation is not supported prior to CUDA 11.4 and will +// do nothing if passed in that case. +template +void gemm_and_bias( + bool transpose_mat1, + bool transpose_mat2, + int64_t m, + int64_t n, + int64_t k, + at::opmath_type alpha_val, + const Dtype* mat1_ptr, + int64_t mat1_ld, + const Dtype* mat2_ptr, + int64_t mat2_ld, + const Dtype* bias, + Dtype* result_ptr, + int64_t result_ld, + GEMMAndBiasActivationEpilogue activation = GEMMAndBiasActivationEpilogue::None); + +void int8_gemm( + bool transpose_mat1, + bool transpose_mat2, + int64_t m, + int64_t n, + int64_t k, + const int8_t* mat1_ptr, + int64_t mat1_ld, + const int8_t* mat2_ptr, + int64_t mat2_ld, + int32_t* result_ptr, + int64_t result_ld); + +void scaled_gemm( + char transa, + char transb, + int64_t m, + int64_t n, + int64_t k, + const void* mat1_ptr, + const void* mat1_scale_ptr, + int64_t mat1_ld, + ScalarType mat1_dtype, + ScalarType mat1_scale_dtype, + const void* mat2_ptr, + const void* mat2_scale_ptr, + int64_t mat2_ld, + ScalarType mat2_dtype, + ScalarType mat2_scale_dtype, + const void* bias_ptr, + ScalarType bias_dtype, + void* result_ptr, + const void* result_scale_ptr, + int64_t result_ld, + ScalarType result_dtype, + bool use_fast_accum, + bool use_rowwise); + +#define CUDABLAS_BGEMM_ARGTYPES(Dtype) \ + char transa, char transb, int64_t m, int64_t n, int64_t k, at::opmath_type alpha, \ + const Dtype *a, int64_t lda, int64_t stridea, \ + const Dtype *b, int64_t ldb, int64_t strideb, \ + at::opmath_type beta, Dtype *c, int64_t ldc, int64_t stridec, int64_t num_batches + +#define CUDABLAS_BGEMM_ARGS(Dtype) \ + transa, transb, m, n, k, alpha, a, lda, stridea, b, ldb, strideb, beta, c, ldc, stridec, num_batches + +template +inline void bgemm(CUDABLAS_BGEMM_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas::bgemm: not implemented"); +} + +template <> +void bgemm(CUDABLAS_BGEMM_ARGTYPES(double)); +template <> +void bgemm(CUDABLAS_BGEMM_ARGTYPES(float)); +template <> +void bgemm>(CUDABLAS_BGEMM_ARGTYPES(c10::complex)); +template <> +void bgemm>(CUDABLAS_BGEMM_ARGTYPES(c10::complex)); +template <> +void bgemm(CUDABLAS_BGEMM_ARGTYPES(at::Half)); +template <> +void bgemm(CUDABLAS_BGEMM_ARGTYPES(at::BFloat16)); + +template +inline void bgemm_internal(CUDABLAS_BGEMM_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas::bgemm_internal: not implemented"); +} + +template <> +void bgemm_internal(CUDABLAS_BGEMM_ARGTYPES(double)); +template <> +void bgemm_internal(CUDABLAS_BGEMM_ARGTYPES(float)); +template <> +void bgemm_internal>(CUDABLAS_BGEMM_ARGTYPES(c10::complex)); +template <> +void bgemm_internal>(CUDABLAS_BGEMM_ARGTYPES(c10::complex)); +template <> +void bgemm_internal(CUDABLAS_BGEMM_ARGTYPES(at::Half)); +template <> +void bgemm_internal(CUDABLAS_BGEMM_ARGTYPES(at::BFloat16)); + +#define CUDABLAS_TRSM_ARGTYPES(Dtype) \ + cublasHandle_t handle, cublasSideMode_t side, cublasFillMode_t uplo, \ + cublasOperation_t trans, cublasDiagType_t diag, int m, int n, \ + const Dtype *alpha, const Dtype *A, int lda, Dtype *B, int ldb + +template +inline void trsm(CUDABLAS_TRSM_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype), "at::cuda::blas::trsm: not implemented"); +} + +template <> +TORCH_CUDA_CU_API void trsm(CUDABLAS_TRSM_ARGTYPES(float)); +template <> +TORCH_CUDA_CU_API void trsm(CUDABLAS_TRSM_ARGTYPES(double)); +template <> +TORCH_CUDA_CU_API void trsm>(CUDABLAS_TRSM_ARGTYPES(c10::complex)); +template <> +TORCH_CUDA_CU_API void trsm>(CUDABLAS_TRSM_ARGTYPES(c10::complex)); + +#define CUDABLAS_TRSM_BATCHED_ARGTYPES(Dtype) \ + cublasHandle_t handle, cublasSideMode_t side, cublasFillMode_t uplo, \ + cublasOperation_t trans, cublasDiagType_t diag, int m, int n, \ + const Dtype *alpha, Dtype *A[], int lda, Dtype *B[], int ldb, \ + int batchCount + +template +inline void trsmBatched(CUDABLAS_TRSM_BATCHED_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype), "at::cuda::blas::trsmBatched: not implemented"); +} + +template <> +TORCH_CUDA_CU_API void trsmBatched(CUDABLAS_TRSM_BATCHED_ARGTYPES(float)); +template <> +TORCH_CUDA_CU_API void trsmBatched(CUDABLAS_TRSM_BATCHED_ARGTYPES(double)); +template <> +TORCH_CUDA_CU_API void trsmBatched>(CUDABLAS_TRSM_BATCHED_ARGTYPES(c10::complex)); +template <> +TORCH_CUDA_CU_API void trsmBatched>(CUDABLAS_TRSM_BATCHED_ARGTYPES(c10::complex)); + +/* LEVEL 2 BLAS FUNCTIONS */ + +#define CUDABLAS_GEMV_ARGTYPES(Dtype) \ + char trans, int64_t m, int64_t n, Dtype alpha, const Dtype *a, int64_t lda, \ + const Dtype *x, int64_t incx, Dtype beta, Dtype *y, int64_t incy + +template +inline void gemv(CUDABLAS_GEMV_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype), "at::cuda::blas::gemv: not implemented"); +} + +template <> +void gemv(CUDABLAS_GEMV_ARGTYPES(double)); +template <> +void gemv(CUDABLAS_GEMV_ARGTYPES(float)); +template <> +void gemv>(CUDABLAS_GEMV_ARGTYPES(c10::complex)); +template <> +void gemv>(CUDABLAS_GEMV_ARGTYPES(c10::complex)); +template <> +void gemv(CUDABLAS_GEMV_ARGTYPES(at::Half)); +template <> +void gemv(CUDABLAS_GEMV_ARGTYPES(at::BFloat16)); + +/* LEVEL 1 BLAS FUNCTIONS */ + +#define CUDABLAS_DOT_ARGTYPES(Dtype) \ + cublasHandle_t handle, int n, const Dtype *x, int incx, const Dtype *y, \ + int incy, Dtype *result + +template +inline void dot(CUDABLAS_DOT_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas::dot: not implemented"); +} + +template <> +void dot(CUDABLAS_DOT_ARGTYPES(double)); +template <> +void dot(CUDABLAS_DOT_ARGTYPES(float)); +template <> +void dot(CUDABLAS_DOT_ARGTYPES(at::Half)); +template <> +void dot(CUDABLAS_DOT_ARGTYPES(at::BFloat16)); +template <> +void dot>(CUDABLAS_DOT_ARGTYPES(c10::complex)); +template <> +void dot>(CUDABLAS_DOT_ARGTYPES(c10::complex)); + +template +inline void vdot(CUDABLAS_DOT_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas::vdot: not implemented"); +} + +template <> +void vdot>(CUDABLAS_DOT_ARGTYPES(c10::complex)); +template <> +void vdot>(CUDABLAS_DOT_ARGTYPES(c10::complex)); + +#define CUDABLAS_GETRS_ARGTYPES(Dtype) \ + cublasHandle_t handle, cublasOperation_t trans, \ + int n, int nrhs, Dtype** dA_array, int lda, int* ipiv_array, \ + Dtype** dB_array, int ldb, int* info_array, int batchsize + +template +void getrsBatched(CUDABLAS_GETRS_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas::getrsBatched: not implemented"); +} +template<> +TORCH_CUDA_CU_API void getrsBatched(CUDABLAS_GETRS_ARGTYPES(float)); +template<> +TORCH_CUDA_CU_API void getrsBatched(CUDABLAS_GETRS_ARGTYPES(double)); +template<> +TORCH_CUDA_CU_API void getrsBatched>(CUDABLAS_GETRS_ARGTYPES(c10::complex)); +template<> +TORCH_CUDA_CU_API void getrsBatched>(CUDABLAS_GETRS_ARGTYPES(c10::complex)); + +#define CUDABLAS_GEQRF_BATCHED_ARGTYPES(Dtype) \ + cublasHandle_t handle, int m, int n, Dtype **A_array, int lda, \ + Dtype **tau_array, int *info, int batchsize + +template +void geqrfBatched(CUDABLAS_GEQRF_BATCHED_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype), "at::cuda::blas::geqrfBatched: not implemented"); +} +template <> +TORCH_CUDA_CU_API void geqrfBatched(CUDABLAS_GEQRF_BATCHED_ARGTYPES(float)); +template <> +TORCH_CUDA_CU_API void geqrfBatched(CUDABLAS_GEQRF_BATCHED_ARGTYPES(double)); +template <> +TORCH_CUDA_CU_API void geqrfBatched>( + CUDABLAS_GEQRF_BATCHED_ARGTYPES(c10::complex)); +template <> +TORCH_CUDA_CU_API void geqrfBatched>( + CUDABLAS_GEQRF_BATCHED_ARGTYPES(c10::complex)); + +#define CUDABLAS_GETRF_ARGTYPES(Dtype) \ + int n, Dtype** dA_array, int ldda, int* ipiv_array, int* info_array, int batchsize + +template +void getrfBatched(CUDABLAS_GETRF_ARGTYPES(Dtype)) { + TORCH_CHECK(false, "at::cuda::blas::getrfBatched: not implemented"); +} +template<> +TORCH_CUDA_CU_API void getrfBatched(CUDABLAS_GETRF_ARGTYPES(float)); +template<> +TORCH_CUDA_CU_API void getrfBatched(CUDABLAS_GETRF_ARGTYPES(double)); +template<> +TORCH_CUDA_CU_API void getrfBatched>(CUDABLAS_GETRF_ARGTYPES(c10::complex)); +template<> +TORCH_CUDA_CU_API void getrfBatched>(CUDABLAS_GETRF_ARGTYPES(c10::complex)); + +#define CUDABLAS_GELS_BATCHED_ARGTYPES(Dtype) \ + cublasHandle_t handle, cublasOperation_t trans, int m, int n, int nrhs, Dtype** dA_array, int ldda, Dtype** dC_array, int lddc, int* info, int *devInfoArray, int batchSize + +template +void gelsBatched(CUDABLAS_GELS_BATCHED_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas::gelsBatched: not implemented"); +} + +template<> +TORCH_CUDA_CU_API void gelsBatched(CUDABLAS_GELS_BATCHED_ARGTYPES(double)); +template<> +TORCH_CUDA_CU_API void gelsBatched(CUDABLAS_GELS_BATCHED_ARGTYPES(float)); +template<> +TORCH_CUDA_CU_API void gelsBatched>(CUDABLAS_GELS_BATCHED_ARGTYPES(c10::complex)); +template<> +TORCH_CUDA_CU_API void gelsBatched>(CUDABLAS_GELS_BATCHED_ARGTYPES(c10::complex)); + +} // namespace at::cuda::blas diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAConfig.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAConfig.h new file mode 100644 index 0000000000000000000000000000000000000000..3e9e496c8830cd011fff700907d94e72c55d75ef --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAConfig.h @@ -0,0 +1,19 @@ +#pragma once + +// Test these using #if AT_CUDNN_ENABLED(), not #ifdef, so that it's +// obvious if you forgot to include Config.h +// c.f. https://stackoverflow.com/questions/33759787/generating-an-error-if-checked-boolean-macro-is-not-defined +// +// NB: This header MUST NOT be included from other headers; it should +// only be included from C++ files. +#define AT_CUDNN_ENABLED() 1 +#define AT_CUSPARSELT_ENABLED() 1 +#define AT_ROCM_ENABLED() 0 +#define AT_MAGMA_ENABLED() 1 + +// Needed for hipMAGMA to correctly identify implementation +#if (AT_ROCM_ENABLED() && AT_MAGMA_ENABLED()) +#define HAVE_HIP 1 +#endif + +#define NVCC_FLAGS_EXTRA "-gencode;arch=compute_50,code=sm_50;-gencode;arch=compute_60,code=sm_60;-gencode;arch=compute_70,code=sm_70;-gencode;arch=compute_75,code=sm_75;-gencode;arch=compute_80,code=sm_80;-gencode;arch=compute_86,code=sm_86;-gencode;arch=compute_90,code=sm_90" diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAContext.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAContext.h new file mode 100644 index 0000000000000000000000000000000000000000..0cb024dd701b284502965cba681f1f9beb214592 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAContext.h @@ -0,0 +1,9 @@ +#pragma once + +#include + +// Preserved for BC, as many files depend on these includes +#include +#include +#include +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAContextLight.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAContextLight.h new file mode 100644 index 0000000000000000000000000000000000000000..dc33cb541370f54f8b8b03baadc52709017ca527 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAContextLight.h @@ -0,0 +1,99 @@ +#pragma once +// Light-weight version of CUDAContext.h with fewer transitive includes + +#include + +#include +#include +#include + +// cublasLT was introduced in CUDA 10.1 but we enable only for 11.1 that also +// added bf16 support +#include + +#ifdef CUDART_VERSION +#include +#endif + +#if defined(USE_CUDSS) +#include +#endif + +#if defined(USE_ROCM) +#include +#endif + +#include +#include + +namespace c10 { +struct Allocator; +} + +namespace at::cuda { + +/* +A common CUDA interface for ATen. + +This interface is distinct from CUDAHooks, which defines an interface that links +to both CPU-only and CUDA builds. That interface is intended for runtime +dispatch and should be used from files that are included in both CPU-only and +CUDA builds. + +CUDAContext, on the other hand, should be preferred by files only included in +CUDA builds. It is intended to expose CUDA functionality in a consistent +manner. + +This means there is some overlap between the CUDAContext and CUDAHooks, but +the choice of which to use is simple: use CUDAContext when in a CUDA-only file, +use CUDAHooks otherwise. + +Note that CUDAContext simply defines an interface with no associated class. +It is expected that the modules whose functions compose this interface will +manage their own state. There is only a single CUDA context/state. +*/ + +/** + * DEPRECATED: use device_count() instead + */ +inline int64_t getNumGPUs() { + return c10::cuda::device_count(); +} + +/** + * CUDA is available if we compiled with CUDA, and there are one or more + * devices. If we compiled with CUDA but there is a driver problem, etc., + * this function will report CUDA is not available (rather than raise an error.) + */ +inline bool is_available() { + return c10::cuda::device_count() > 0; +} + +TORCH_CUDA_CPP_API cudaDeviceProp* getCurrentDeviceProperties(); + +TORCH_CUDA_CPP_API int warp_size(); + +TORCH_CUDA_CPP_API cudaDeviceProp* getDeviceProperties(c10::DeviceIndex device); + +TORCH_CUDA_CPP_API bool canDeviceAccessPeer( + c10::DeviceIndex device, + c10::DeviceIndex peer_device); + +TORCH_CUDA_CPP_API c10::Allocator* getCUDADeviceAllocator(); + +/* Handles */ +TORCH_CUDA_CPP_API cusparseHandle_t getCurrentCUDASparseHandle(); +TORCH_CUDA_CPP_API cublasHandle_t getCurrentCUDABlasHandle(); +TORCH_CUDA_CPP_API cublasLtHandle_t getCurrentCUDABlasLtHandle(); + +TORCH_CUDA_CPP_API void clearCublasWorkspaces(); + +#if defined(CUDART_VERSION) || defined(USE_ROCM) +TORCH_CUDA_CPP_API cusolverDnHandle_t getCurrentCUDASolverDnHandle(); +#endif + +#if defined(USE_CUDSS) +TORCH_CUDA_CPP_API cudssHandle_t getCurrentCudssHandle(); +#endif + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDADataType.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDADataType.h new file mode 100644 index 0000000000000000000000000000000000000000..b3ac2b39fcfb7bec4e7fabff9e25186d573fb76e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDADataType.h @@ -0,0 +1,98 @@ +#pragma once + +#include + +#include +#include + +namespace at::cuda { + +template +cudaDataType getCudaDataType() { + static_assert(false && sizeof(scalar_t), "Cannot convert type to cudaDataType."); + return {}; +} + +template<> inline cudaDataType getCudaDataType() { + return CUDA_R_16F; +} +template<> inline cudaDataType getCudaDataType() { + return CUDA_R_32F; +} +template<> inline cudaDataType getCudaDataType() { + return CUDA_R_64F; +} +template<> inline cudaDataType getCudaDataType>() { + return CUDA_C_16F; +} +template<> inline cudaDataType getCudaDataType>() { + return CUDA_C_32F; +} +template<> inline cudaDataType getCudaDataType>() { + return CUDA_C_64F; +} + +template<> inline cudaDataType getCudaDataType() { + return CUDA_R_8U; +} +template<> inline cudaDataType getCudaDataType() { + return CUDA_R_8I; +} +template<> inline cudaDataType getCudaDataType() { + return CUDA_R_32I; +} + +template<> inline cudaDataType getCudaDataType() { + return CUDA_R_16I; +} +template<> inline cudaDataType getCudaDataType() { + return CUDA_R_64I; +} +template<> inline cudaDataType getCudaDataType() { + return CUDA_R_16BF; +} + +inline cudaDataType ScalarTypeToCudaDataType(const c10::ScalarType& scalar_type) { + switch (scalar_type) { + case c10::ScalarType::Byte: + return CUDA_R_8U; + case c10::ScalarType::Char: + return CUDA_R_8I; + case c10::ScalarType::Int: + return CUDA_R_32I; + case c10::ScalarType::Half: + return CUDA_R_16F; + case c10::ScalarType::Float: + return CUDA_R_32F; + case c10::ScalarType::Double: + return CUDA_R_64F; + case c10::ScalarType::ComplexHalf: + return CUDA_C_16F; + case c10::ScalarType::ComplexFloat: + return CUDA_C_32F; + case c10::ScalarType::ComplexDouble: + return CUDA_C_64F; + case c10::ScalarType::Short: + return CUDA_R_16I; + case c10::ScalarType::Long: + return CUDA_R_64I; + case c10::ScalarType::BFloat16: + return CUDA_R_16BF; +#if (defined(CUDA_VERSION) && CUDA_VERSION >= 11080) || (defined(USE_ROCM) && ROCM_VERSION >= 60300) + case c10::ScalarType::Float8_e4m3fn: + return CUDA_R_8F_E4M3; + case c10::ScalarType::Float8_e5m2: + return CUDA_R_8F_E5M2; +#endif +#if defined(USE_ROCM) + case c10::ScalarType::Float8_e4m3fnuz: + return HIP_R_8F_E4M3_FNUZ; + case c10::ScalarType::Float8_e5m2fnuz: + return HIP_R_8F_E5M2_FNUZ; +#endif + default: + TORCH_INTERNAL_ASSERT(false, "Cannot convert ScalarType ", scalar_type, " to cudaDataType.") + } +} + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDADevice.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDADevice.h new file mode 100644 index 0000000000000000000000000000000000000000..ba9a5eb849a091be6e86658a8c7af87a0a3fbb8f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDADevice.h @@ -0,0 +1,23 @@ +#pragma once + +#include + +#include +#include + +namespace at::cuda { + +inline Device getDeviceFromPtr(void* ptr) { + cudaPointerAttributes attr{}; + + AT_CUDA_CHECK(cudaPointerGetAttributes(&attr, ptr)); + +#if !defined(USE_ROCM) + TORCH_CHECK(attr.type != cudaMemoryTypeUnregistered, + "The specified pointer resides on host memory and is not registered with any CUDA device."); +#endif + + return {c10::DeviceType::CUDA, static_cast(attr.device)}; +} + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAEvent.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAEvent.h new file mode 100644 index 0000000000000000000000000000000000000000..94ce34645b02bf21d30eef42191560962a6c40a3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAEvent.h @@ -0,0 +1,211 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include + +#include + +#include +#include + +namespace at::cuda { + +/* +* CUDAEvents are movable not copyable wrappers around CUDA's events. +* +* CUDAEvents are constructed lazily when first recorded unless it is +* reconstructed from a cudaIpcEventHandle_t. The event has a device, and this +* device is acquired from the first recording stream. However, if reconstructed +* from a handle, the device should be explicitly specified; or if ipc_handle() is +* called before the event is ever recorded, it will use the current device. +* Later streams that record the event must match this device. +*/ +struct TORCH_CUDA_CPP_API CUDAEvent { + // Constructors + // Default value for `flags` is specified below - it's cudaEventDisableTiming + CUDAEvent() noexcept = default; + CUDAEvent(unsigned int flags) noexcept : flags_{flags} {} + + CUDAEvent( + DeviceIndex device_index, const cudaIpcEventHandle_t* handle) : device_index_(device_index) { + CUDAGuard guard(device_index_); + + AT_CUDA_CHECK(cudaIpcOpenEventHandle(&event_, *handle)); + is_created_ = true; + } + + // Note: event destruction done on creating device to avoid creating a + // CUDA context on other devices. + ~CUDAEvent() { + try { + if (is_created_) { + CUDAGuard guard(device_index_); + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_deletion(at::kCUDA, reinterpret_cast(event_)); + } + AT_CUDA_CHECK(cudaEventDestroy(event_)); + } + } catch (...) { /* No throw */ } + } + + CUDAEvent(const CUDAEvent&) = delete; + CUDAEvent& operator=(const CUDAEvent&) = delete; + + CUDAEvent(CUDAEvent&& other) noexcept { moveHelper(std::move(other)); } + CUDAEvent& operator=(CUDAEvent&& other) noexcept { + if (this != &other) { + moveHelper(std::move(other)); + } + return *this; + } + + operator cudaEvent_t() const { return event(); } + + // Less than operator (to allow use in sets) + friend bool operator<(const CUDAEvent& left, const CUDAEvent& right) { + return left.event_ < right.event_; + } + + std::optional device() const { + if (is_created_) { + return at::Device(at::kCUDA, device_index_); + } else { + return {}; + } + } + + bool isCreated() const { return is_created_; } + DeviceIndex device_index() const {return device_index_;} + cudaEvent_t event() const { return event_; } + + // Note: cudaEventQuery can be safely called from any device + bool query() const { + if (!is_created_) { + return true; + } + + cudaError_t err = cudaEventQuery(event_); + if (err == cudaSuccess) { + return true; + } else if (err != cudaErrorNotReady) { + C10_CUDA_CHECK(err); + } else { + // ignore and clear the error if not ready + (void)cudaGetLastError(); + } + + return false; + } + + void record() { record(getCurrentCUDAStream()); } + + void recordOnce(const CUDAStream& stream) { + if (!was_recorded_) record(stream); + } + + // Note: cudaEventRecord must be called on the same device as the event. + void record(const CUDAStream& stream) { + if (!is_created_) { + createEvent(stream.device_index()); + } + + TORCH_CHECK(device_index_ == stream.device_index(), "Event device ", device_index_, + " does not match recording stream's device ", stream.device_index(), "."); + CUDAGuard guard(device_index_); + AT_CUDA_CHECK(cudaEventRecord(event_, stream)); + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_record(at::kCUDA, + reinterpret_cast(event_), + reinterpret_cast(stream.stream()) + ); + } + was_recorded_ = true; + } + + // Note: cudaStreamWaitEvent must be called on the same device as the stream. + // The event has no actual GPU resources associated with it. + void block(const CUDAStream& stream) { + if (is_created_) { + CUDAGuard guard(stream.device_index()); + AT_CUDA_CHECK(cudaStreamWaitEvent(stream, event_, 0)); + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_wait(at::kCUDA, + reinterpret_cast(event_), + reinterpret_cast(stream.stream()) + ); + } + } + } + + // Note: cudaEventElapsedTime can be safely called from any device + float elapsed_time(const CUDAEvent& other) const { + TORCH_CHECK(is_created_ && other.isCreated(), + "Both events must be recorded before calculating elapsed time."); + float time_ms = 0; + // We do not strictly have to set the device index to the same as our event, + // but if we don't and the current device is not initialized, it will + // create a new cuda context, which will consume a lot of memory. + CUDAGuard guard(device_index_); + // raise cudaErrorNotReady if either event is recorded but not yet completed + AT_CUDA_CHECK(cudaEventElapsedTime(&time_ms, event_, other.event_)); + return time_ms; + } + + // Note: cudaEventSynchronize can be safely called from any device + void synchronize() const { + if (is_created_) { + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_synchronization(at::kCUDA, reinterpret_cast(event_)); + } + AT_CUDA_CHECK(cudaEventSynchronize(event_)); + } + } + + // Note: cudaIpcGetEventHandle must be called on the same device as the event + void ipc_handle(cudaIpcEventHandle_t * handle) { + if (!is_created_) { + // this CUDAEvent object was initially constructed from flags but event_ + // is not created yet. + createEvent(getCurrentCUDAStream().device_index()); + } + CUDAGuard guard(device_index_); + AT_CUDA_CHECK(cudaIpcGetEventHandle(handle, event_)); + } + +private: + unsigned int flags_ = cudaEventDisableTiming; + bool is_created_ = false; + bool was_recorded_ = false; + DeviceIndex device_index_ = -1; + cudaEvent_t event_{}; + + void createEvent(DeviceIndex device_index) { + device_index_ = device_index; + CUDAGuard guard(device_index_); + AT_CUDA_CHECK(cudaEventCreateWithFlags(&event_, flags_)); + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_creation(at::kCUDA, reinterpret_cast(event_)); + } + is_created_ = true; + } + + void moveHelper(CUDAEvent&& other) { + std::swap(flags_, other.flags_); + std::swap(is_created_, other.is_created_); + std::swap(was_recorded_, other.was_recorded_); + std::swap(device_index_, other.device_index_); + std::swap(event_, other.event_); + } +}; + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAGeneratorImpl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAGeneratorImpl.h new file mode 100644 index 0000000000000000000000000000000000000000..b0b77cb822a85f89442c9d77d00a8d4919b1a113 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAGeneratorImpl.h @@ -0,0 +1,180 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +namespace at { + +namespace cuda { +struct CUDAGraph; +} + +/** + * Note [CUDA Graph-safe RNG states] + * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + * + * Strategy: + * ~~~~~~~~~ + * (It helps to look at + * cuda/detail/PhiloxCudaStateRaw.cuh and + * cuda/detail/UnpackRaw.cuh + * while you read this.) + * + * A CUDA graph containing multiple RNG ops behaves like a + * single giant kernel from the perspective of ops external + * to the graph. During graph capture, logic in CUDAGeneratorImpl + * records the total of all offset increments that occur in the + * graphed region, and records the final total as the offset for + * the entire graph. + * + * When the graph reruns, the logic that reruns it + * increments this device's CUDA generator's offset + * by that total. + * + * Meanwhile, within the graph, at capture time, instead of + * populating PhiloxCudaStates with the uint64_t offset pulled + * directly from the global state, PhiloxCudaState uses a pointer + * to a one-element stream-local int64_t device tensor + * holding an initial offset value, and a uint64_t holding an + * intra-graph offset. (The intra-graph offset starts from zero + * when capture begins.) In each consumer kernel, + * at::cuda::philox::unpack computes the offset to use for this kernel + * as intra-graph offset + *initial offset. + * + * When the graph reruns, the logic that reruns it first + * fill_s the initial offset tensor with this device's + * CUDA generator's current offset. + * + * The control flow above ensures graphed execution is bitwise + * identical to eager execution as long as RNG ops are enqueued + * from a single thread, even if RNG ops and graphs containing + * RNG ops are enqueued and run simultaneously on multiple streams. + * + * Usage: + * ~~~~~~ + * PhiloxCudaState in this file, and unpack() in + * cuda/CUDAGraphsUtils.cuh allow non-divergent use of + * CUDAGeneratorImpl whether graph capture is underway or not. + * + * Each PhiloxCudaState instance should be used for one and only one + * consumer kernel. + * + * Example (see e.g. native/cuda/Dropout.cu): + * + * #include + * #include + * + * __global__ void kernel(..., PhiloxCudaState philox_args) { + * auto seeds = at::cuda::philox::unpack(philox_args); + * IndexType idx = blockIdx.x * blockDim.x + threadIdx.x; + * curandStatePhilox4_32_10_t state; + * curand_init(std::get<0>(seeds), // seed + * idx, // per-thread subsequence + * std::get<1>(seeds), // offset in subsequence + * &state); + * ... + * } + * + * host_caller(...) { + * PhiloxCudaState rng_engine_inputs; + * { + * // See Note [Acquire lock when using random generators] + * std::lock_guard lock(gen->mutex_); + * + * // gen could be HostState or DevState here! No divergent code needed! + * rng_engine_inputs = gen->philox_cuda_state(offset_increment); + * } + * kernel<<<...>>>(..., rng_engine_inputs); + * } + * + */ + +struct CUDAGeneratorState : public c10::intrusive_ptr_target { + uint64_t seed_; + uint64_t philox_offset_per_thread_; + uint32_t offset_intragraph_; + bool capturing_{}; + std::unordered_set registered_graphs_; + at::TensorBase seed_extragraph_{}; + at::TensorBase offset_extragraph_{}; + + CUDAGeneratorState( + uint64_t seed = default_rng_seed_val, + uint64_t philox_offset_per_thread = 0, + uint32_t offset_intragraph = 0) + : seed_(seed), + philox_offset_per_thread_(philox_offset_per_thread), + offset_intragraph_(offset_intragraph) {} + + void increase(uint64_t increment); + + void register_graph(cuda::CUDAGraph* graph); + void unregister_graph(cuda::CUDAGraph* graph); + + void capture_prologue(); + // capture_epilogue returns the wholegraph_increment + uint64_t capture_epilogue(); + void replay_prologue(uint64_t wholegraph_increment); + c10::intrusive_ptr clone(); +}; + +struct TORCH_CUDA_CPP_API CUDAGeneratorImpl : public c10::GeneratorImpl { + // Constructors + CUDAGeneratorImpl(DeviceIndex device_index = -1); + CUDAGeneratorImpl( + DeviceIndex device_index, + c10::intrusive_ptr state_); + ~CUDAGeneratorImpl() override = default; + + // CUDAGeneratorImpl methods + std::shared_ptr clone() const; + void set_current_seed(uint64_t seed) override; + void set_offset(uint64_t offset) override; + uint64_t get_offset() const override; + uint64_t current_seed() const override; + uint64_t seed() override; + void set_state(const c10::TensorImpl& new_state) override; + c10::intrusive_ptr get_state() const override; + void graphsafe_set_state( + const c10::intrusive_ptr& state) override; + c10::intrusive_ptr graphsafe_get_state() const override; + + void set_philox_offset_per_thread(uint64_t offset); + uint64_t philox_offset_per_thread() const; + + void register_graph(cuda::CUDAGraph* graph); + void unregister_graph(cuda::CUDAGraph* graph); + + // Generates a PhiloxCudaState with a specified increment, and increment + // current state + PhiloxCudaState philox_cuda_state(uint64_t increment); + + bool reset_rnn_state() { + return !no_reset_rnn_state_.test_and_set(); + } + + // Temporarily accommodates call sites that use philox_engine_inputs. + // Allows incremental refactor of call sites to use philox_cuda_state. + std::pair philox_engine_inputs(uint64_t increment); + + static c10::DeviceType device_type(); + + private: + CUDAGeneratorImpl* clone_impl() const override; + + c10::intrusive_ptr state_; + std::atomic_flag no_reset_rnn_state_{}; +}; + +namespace cuda::detail { + +TORCH_CUDA_CPP_API const Generator& getDefaultCUDAGenerator( + DeviceIndex device_index = -1); +TORCH_CUDA_CPP_API Generator createCUDAGenerator(DeviceIndex device_index = -1); + +} // namespace cuda::detail +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAGraph.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAGraph.h new file mode 100644 index 0000000000000000000000000000000000000000..76a090579d1dfafb75a5a202f78071c43433da87 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAGraph.h @@ -0,0 +1,86 @@ +#pragma once + +#include +#include +#include +#include +#include + +namespace at { + +struct Generator; +struct CUDAGeneratorImpl; +struct CUDAGeneratorState; + +namespace cuda { + +// Standalone way to get a unique mempool id usable as a pool=... argument +// to CUDAGraph::capture_begin +TORCH_CUDA_CPP_API MempoolId_t graph_pool_handle(); + +struct TORCH_CUDA_CPP_API CUDAGraph { + CUDAGraph(); + ~CUDAGraph(); + + // See Note [Explicit Registration of Generators to the CUDA Graph] + void register_generator_state(c10::intrusive_ptr state); + void register_generator_state(const at::Generator& generator); + void capture_begin( + MempoolId_t pool = {0, 0}, + cudaStreamCaptureMode capture_mode = cudaStreamCaptureModeGlobal); + void capture_end(); + void replay(); + void reset(); + MempoolId_t pool(); + void enable_debug_mode(); + void debug_dump(const std::string& debug_path); + + protected: + cudaGraph_t graph_ = nullptr; + cudaGraphExec_t graph_exec_ = nullptr; + + // internal states so reset() can do its best cleaning up + // Set to true in capture_end if cudaStreamEndCapture succeeded + // Set back to false soon after, when graph_ is consumed by cudaGraphInstantiate + // to create graph_exec_, then graph_ is deleted + bool has_graph_ = false; + // Set to true in capture_end if cudaGraphInstantiate succeeded + bool has_graph_exec_ = false; + + // the ID assigned by cuda during graph capture, + // used to identify when a stream is participating in capture + CaptureId_t capture_id_ = -1; + + // uuid used to request a particular private mempool from CUDACachingAllocator. + // By default, this will be set to {id_, 0}. + // + // If capture_begin is called with "pool=other_graph.pool()", this graph's mempool_id_ + // will be set to the other graph's mempool_id_, and therefore share a mempool with the + // other graph. + // + // If capture_begin is called with "pool=handle" where "handle" came from graph_pool_handle(), + // it will share a mempool with any other captures that used "pool=handle". + // + // Sharing a mempool across graphs saves memory, and it's safe if you + // know you'll replay those graphs in the same order you captured them. + MempoolId_t mempool_id_; + + // Stream on which capture began + at::cuda::CUDAStream capture_stream_; + + // multiple generator states and their wholegraph_increments in this graph + // that are managed by the CUDA Graph + ska::flat_hash_map, uint64_t> + captured_generator_states_; + + // Device where capture occurred. Right now, for simplicity, we require all ops + // in a capture to run on the same device, but this is a limitation of CUDAGraph, + // not CUDA itself. We can straightforwardly modify CUDAGraph to support multi-device + // captures if needed. + // init capture_dev_ as UNDEFINED_DEVICE to check that it stores the real device id in the destructor + static constexpr c10::DeviceIndex UNDEFINED_DEVICE = -1; + c10::DeviceIndex capture_dev_{UNDEFINED_DEVICE}; +}; + +} // namespace cuda +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAGraphsUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAGraphsUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..d3a5b306eeea49b47d45ae5f28944b6dfd8ac4dc --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAGraphsUtils.cuh @@ -0,0 +1,53 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include + +// c10/cuda/CUDAGraphsC10Utils.h has utils used by both c10 and aten. +// This file adds utils used by aten only. + +namespace at::cuda { + +using CaptureId_t = c10::cuda::CaptureId_t; +using CaptureStatus = c10::cuda::CaptureStatus; + +// Use this version where you don't want to create a CUDA context if none exists. +inline CaptureStatus currentStreamCaptureStatus() { + // don't create a context if we don't have to + if (c10::cuda::hasPrimaryContext(c10::cuda::current_device())) { + return c10::cuda::currentStreamCaptureStatusMayInitCtx(); + } else { + return CaptureStatus::None; + } +} + +inline void assertNotCapturing(const std::string& attempt) { + auto status = currentStreamCaptureStatus(); + TORCH_CHECK(status == CaptureStatus::None, + attempt, + " during CUDA graph capture. If you need this call to be captured, " + "please file an issue. " + "Current cudaStreamCaptureStatus: ", + status); +} + +inline void errorIfCapturingCudnnBenchmark(const std::string& version_specific) { + auto status = currentStreamCaptureStatus(); + TORCH_CHECK(status == CaptureStatus::None, + "Current cudaStreamCaptureStatus: ", + status, + "\nCapturing ", + version_specific, + "is prohibited. Possible causes of this error:\n" + "1. No warmup iterations occurred before capture.\n" + "2. The convolutions you're trying to capture use dynamic shapes, " + "in which case capturing them is generally prohibited."); +} + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDASparse.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDASparse.h new file mode 100644 index 0000000000000000000000000000000000000000..736fbe4ae50dac94f9022c9e827393d4a7e9cf5a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDASparse.h @@ -0,0 +1,75 @@ +#pragma once + +#include +#if defined(USE_ROCM) +#include +#define HIPSPARSE_VERSION ((hipsparseVersionMajor*100000) + (hipsparseVersionMinor*100) + hipsparseVersionPatch) +#endif + +// cuSparse Generic API added in CUDA 10.1 +// Windows support added in CUDA 11.0 +#if defined(CUDART_VERSION) && defined(CUSPARSE_VERSION) && ((CUSPARSE_VERSION >= 10300) || (CUSPARSE_VERSION >= 11000 && defined(_WIN32))) +#define AT_USE_CUSPARSE_GENERIC_API() 1 +#else +#define AT_USE_CUSPARSE_GENERIC_API() 0 +#endif + +// cuSparse Generic API descriptor pointers were changed to const in CUDA 12.0 +#if defined(CUDART_VERSION) && defined(CUSPARSE_VERSION) && \ + (CUSPARSE_VERSION < 12000) +#define AT_USE_CUSPARSE_NON_CONST_DESCRIPTORS() 1 +#else +#define AT_USE_CUSPARSE_NON_CONST_DESCRIPTORS() 0 +#endif + +#if defined(CUDART_VERSION) && defined(CUSPARSE_VERSION) && \ + (CUSPARSE_VERSION >= 12000) +#define AT_USE_CUSPARSE_CONST_DESCRIPTORS() 1 +#else +#define AT_USE_CUSPARSE_CONST_DESCRIPTORS() 0 +#endif + +#if defined(USE_ROCM) +// hipSparse const API added in v2.4.0 +#if HIPSPARSE_VERSION >= 200400 +#define AT_USE_HIPSPARSE_CONST_DESCRIPTORS() 1 +#define AT_USE_HIPSPARSE_NON_CONST_DESCRIPTORS() 0 +#define AT_USE_HIPSPARSE_GENERIC_API() 1 +#else +#define AT_USE_HIPSPARSE_CONST_DESCRIPTORS() 0 +#define AT_USE_HIPSPARSE_NON_CONST_DESCRIPTORS() 1 +#define AT_USE_HIPSPARSE_GENERIC_API() 1 +#endif +#else // USE_ROCM +#define AT_USE_HIPSPARSE_CONST_DESCRIPTORS() 0 +#define AT_USE_HIPSPARSE_NON_CONST_DESCRIPTORS() 0 +#define AT_USE_HIPSPARSE_GENERIC_API() 0 +#endif // USE_ROCM + +// cuSparse Generic API spsv function was added in CUDA 11.3.0 +#if defined(CUDART_VERSION) && defined(CUSPARSE_VERSION) && (CUSPARSE_VERSION >= 11500) +#define AT_USE_CUSPARSE_GENERIC_SPSV() 1 +#else +#define AT_USE_CUSPARSE_GENERIC_SPSV() 0 +#endif + +// cuSparse Generic API spsm function was added in CUDA 11.3.1 +#if defined(CUDART_VERSION) && defined(CUSPARSE_VERSION) && (CUSPARSE_VERSION >= 11600) +#define AT_USE_CUSPARSE_GENERIC_SPSM() 1 +#else +#define AT_USE_CUSPARSE_GENERIC_SPSM() 0 +#endif + +// cuSparse Generic API sddmm function was added in CUDA 11.2.1 (cuSparse version 11400) +#if defined(CUDART_VERSION) && defined(CUSPARSE_VERSION) && (CUSPARSE_VERSION >= 11400) +#define AT_USE_CUSPARSE_GENERIC_SDDMM() 1 +#else +#define AT_USE_CUSPARSE_GENERIC_SDDMM() 0 +#endif + +// BSR triangular solve functions were added in hipSPARSE 1.11.2 (ROCm 4.5.0) +#if defined(CUDART_VERSION) || defined(USE_ROCM) +#define AT_USE_HIPSPARSE_TRIANGULAR_SOLVE() 1 +#else +#define AT_USE_HIPSPARSE_TRIANGULAR_SOLVE() 0 +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDASparseBlas.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDASparseBlas.h new file mode 100644 index 0000000000000000000000000000000000000000..a098496491d155567d31454b35760c9eb3d941da --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDASparseBlas.h @@ -0,0 +1,320 @@ +#pragma once + +/* + Provides a subset of cuSPARSE functions as templates: + + csrgeam2(...) + + where scalar_t is double, float, c10::complex or c10::complex. + The functions are available in at::cuda::sparse namespace. +*/ + +#include +#include + +// NOLINTBEGIN(misc-misplaced-const) +namespace at::cuda::sparse { + +#define CUSPARSE_CSRGEAM2_BUFFERSIZE_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, int m, int n, const scalar_t *alpha, \ + const cusparseMatDescr_t descrA, int nnzA, \ + const scalar_t *csrSortedValA, const int *csrSortedRowPtrA, \ + const int *csrSortedColIndA, const scalar_t *beta, \ + const cusparseMatDescr_t descrB, int nnzB, \ + const scalar_t *csrSortedValB, const int *csrSortedRowPtrB, \ + const int *csrSortedColIndB, const cusparseMatDescr_t descrC, \ + const scalar_t *csrSortedValC, const int *csrSortedRowPtrC, \ + const int *csrSortedColIndC, size_t *pBufferSizeInBytes + +template +inline void csrgeam2_bufferSizeExt( + CUSPARSE_CSRGEAM2_BUFFERSIZE_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::csrgeam2_bufferSizeExt: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void csrgeam2_bufferSizeExt( + CUSPARSE_CSRGEAM2_BUFFERSIZE_ARGTYPES(float)); +template <> +void csrgeam2_bufferSizeExt( + CUSPARSE_CSRGEAM2_BUFFERSIZE_ARGTYPES(double)); +template <> +void csrgeam2_bufferSizeExt>( + CUSPARSE_CSRGEAM2_BUFFERSIZE_ARGTYPES(c10::complex)); +template <> +void csrgeam2_bufferSizeExt>( + CUSPARSE_CSRGEAM2_BUFFERSIZE_ARGTYPES(c10::complex)); + +#define CUSPARSE_CSRGEAM2_NNZ_ARGTYPES() \ + cusparseHandle_t handle, int m, int n, const cusparseMatDescr_t descrA, \ + int nnzA, const int *csrSortedRowPtrA, const int *csrSortedColIndA, \ + const cusparseMatDescr_t descrB, int nnzB, const int *csrSortedRowPtrB, \ + const int *csrSortedColIndB, const cusparseMatDescr_t descrC, \ + int *csrSortedRowPtrC, int *nnzTotalDevHostPtr, void *workspace + +template +inline void csrgeam2Nnz(CUSPARSE_CSRGEAM2_NNZ_ARGTYPES()) { + TORCH_CUDASPARSE_CHECK(cusparseXcsrgeam2Nnz( + handle, + m, + n, + descrA, + nnzA, + csrSortedRowPtrA, + csrSortedColIndA, + descrB, + nnzB, + csrSortedRowPtrB, + csrSortedColIndB, + descrC, + csrSortedRowPtrC, + nnzTotalDevHostPtr, + workspace)); +} + +#define CUSPARSE_CSRGEAM2_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, int m, int n, const scalar_t *alpha, \ + const cusparseMatDescr_t descrA, int nnzA, \ + const scalar_t *csrSortedValA, const int *csrSortedRowPtrA, \ + const int *csrSortedColIndA, const scalar_t *beta, \ + const cusparseMatDescr_t descrB, int nnzB, \ + const scalar_t *csrSortedValB, const int *csrSortedRowPtrB, \ + const int *csrSortedColIndB, const cusparseMatDescr_t descrC, \ + scalar_t *csrSortedValC, int *csrSortedRowPtrC, int *csrSortedColIndC, \ + void *pBuffer + +template +inline void csrgeam2(CUSPARSE_CSRGEAM2_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::csrgeam2: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void csrgeam2(CUSPARSE_CSRGEAM2_ARGTYPES(float)); +template <> +void csrgeam2(CUSPARSE_CSRGEAM2_ARGTYPES(double)); +template <> +void csrgeam2>( + CUSPARSE_CSRGEAM2_ARGTYPES(c10::complex)); +template <> +void csrgeam2>( + CUSPARSE_CSRGEAM2_ARGTYPES(c10::complex)); + +#define CUSPARSE_BSRMM_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, cusparseDirection_t dirA, \ + cusparseOperation_t transA, cusparseOperation_t transB, int mb, int n, \ + int kb, int nnzb, const scalar_t *alpha, \ + const cusparseMatDescr_t descrA, const scalar_t *bsrValA, \ + const int *bsrRowPtrA, const int *bsrColIndA, int blockDim, \ + const scalar_t *B, int ldb, const scalar_t *beta, scalar_t *C, int ldc + +template +inline void bsrmm(CUSPARSE_BSRMM_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::bsrmm: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void bsrmm(CUSPARSE_BSRMM_ARGTYPES(float)); +template <> +void bsrmm(CUSPARSE_BSRMM_ARGTYPES(double)); +template <> +void bsrmm>(CUSPARSE_BSRMM_ARGTYPES(c10::complex)); +template <> +void bsrmm>(CUSPARSE_BSRMM_ARGTYPES(c10::complex)); + +#define CUSPARSE_BSRMV_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, cusparseDirection_t dirA, \ + cusparseOperation_t transA, int mb, int nb, int nnzb, \ + const scalar_t *alpha, const cusparseMatDescr_t descrA, \ + const scalar_t *bsrValA, const int *bsrRowPtrA, const int *bsrColIndA, \ + int blockDim, const scalar_t *x, const scalar_t *beta, scalar_t *y + +template +inline void bsrmv(CUSPARSE_BSRMV_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::bsrmv: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void bsrmv(CUSPARSE_BSRMV_ARGTYPES(float)); +template <> +void bsrmv(CUSPARSE_BSRMV_ARGTYPES(double)); +template <> +void bsrmv>(CUSPARSE_BSRMV_ARGTYPES(c10::complex)); +template <> +void bsrmv>(CUSPARSE_BSRMV_ARGTYPES(c10::complex)); + +#if AT_USE_HIPSPARSE_TRIANGULAR_SOLVE() + +#define CUSPARSE_BSRSV2_BUFFER_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, cusparseDirection_t dirA, \ + cusparseOperation_t transA, int mb, int nnzb, \ + const cusparseMatDescr_t descrA, scalar_t *bsrValA, \ + const int *bsrRowPtrA, const int *bsrColIndA, int blockDim, \ + bsrsv2Info_t info, int *pBufferSizeInBytes + +template +inline void bsrsv2_bufferSize(CUSPARSE_BSRSV2_BUFFER_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::bsrsv2_bufferSize: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void bsrsv2_bufferSize(CUSPARSE_BSRSV2_BUFFER_ARGTYPES(float)); +template <> +void bsrsv2_bufferSize(CUSPARSE_BSRSV2_BUFFER_ARGTYPES(double)); +template <> +void bsrsv2_bufferSize>( + CUSPARSE_BSRSV2_BUFFER_ARGTYPES(c10::complex)); +template <> +void bsrsv2_bufferSize>( + CUSPARSE_BSRSV2_BUFFER_ARGTYPES(c10::complex)); + +#define CUSPARSE_BSRSV2_ANALYSIS_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, cusparseDirection_t dirA, \ + cusparseOperation_t transA, int mb, int nnzb, \ + const cusparseMatDescr_t descrA, const scalar_t *bsrValA, \ + const int *bsrRowPtrA, const int *bsrColIndA, int blockDim, \ + bsrsv2Info_t info, cusparseSolvePolicy_t policy, void *pBuffer + +template +inline void bsrsv2_analysis(CUSPARSE_BSRSV2_ANALYSIS_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::bsrsv2_analysis: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void bsrsv2_analysis(CUSPARSE_BSRSV2_ANALYSIS_ARGTYPES(float)); +template <> +void bsrsv2_analysis(CUSPARSE_BSRSV2_ANALYSIS_ARGTYPES(double)); +template <> +void bsrsv2_analysis>( + CUSPARSE_BSRSV2_ANALYSIS_ARGTYPES(c10::complex)); +template <> +void bsrsv2_analysis>( + CUSPARSE_BSRSV2_ANALYSIS_ARGTYPES(c10::complex)); + +#define CUSPARSE_BSRSV2_SOLVE_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, cusparseDirection_t dirA, \ + cusparseOperation_t transA, int mb, int nnzb, const scalar_t *alpha, \ + const cusparseMatDescr_t descrA, const scalar_t *bsrValA, \ + const int *bsrRowPtrA, const int *bsrColIndA, int blockDim, \ + bsrsv2Info_t info, const scalar_t *x, scalar_t *y, \ + cusparseSolvePolicy_t policy, void *pBuffer + +template +inline void bsrsv2_solve(CUSPARSE_BSRSV2_SOLVE_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::bsrsv2_solve: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void bsrsv2_solve(CUSPARSE_BSRSV2_SOLVE_ARGTYPES(float)); +template <> +void bsrsv2_solve(CUSPARSE_BSRSV2_SOLVE_ARGTYPES(double)); +template <> +void bsrsv2_solve>( + CUSPARSE_BSRSV2_SOLVE_ARGTYPES(c10::complex)); +template <> +void bsrsv2_solve>( + CUSPARSE_BSRSV2_SOLVE_ARGTYPES(c10::complex)); + +#define CUSPARSE_BSRSM2_BUFFER_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, cusparseDirection_t dirA, \ + cusparseOperation_t transA, cusparseOperation_t transX, int mb, int n, \ + int nnzb, const cusparseMatDescr_t descrA, scalar_t *bsrValA, \ + const int *bsrRowPtrA, const int *bsrColIndA, int blockDim, \ + bsrsm2Info_t info, int *pBufferSizeInBytes + +template +inline void bsrsm2_bufferSize(CUSPARSE_BSRSM2_BUFFER_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::bsrsm2_bufferSize: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void bsrsm2_bufferSize(CUSPARSE_BSRSM2_BUFFER_ARGTYPES(float)); +template <> +void bsrsm2_bufferSize(CUSPARSE_BSRSM2_BUFFER_ARGTYPES(double)); +template <> +void bsrsm2_bufferSize>( + CUSPARSE_BSRSM2_BUFFER_ARGTYPES(c10::complex)); +template <> +void bsrsm2_bufferSize>( + CUSPARSE_BSRSM2_BUFFER_ARGTYPES(c10::complex)); + +#define CUSPARSE_BSRSM2_ANALYSIS_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, cusparseDirection_t dirA, \ + cusparseOperation_t transA, cusparseOperation_t transX, int mb, int n, \ + int nnzb, const cusparseMatDescr_t descrA, const scalar_t *bsrValA, \ + const int *bsrRowPtrA, const int *bsrColIndA, int blockDim, \ + bsrsm2Info_t info, cusparseSolvePolicy_t policy, void *pBuffer + +template +inline void bsrsm2_analysis(CUSPARSE_BSRSM2_ANALYSIS_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::bsrsm2_analysis: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void bsrsm2_analysis(CUSPARSE_BSRSM2_ANALYSIS_ARGTYPES(float)); +template <> +void bsrsm2_analysis(CUSPARSE_BSRSM2_ANALYSIS_ARGTYPES(double)); +template <> +void bsrsm2_analysis>( + CUSPARSE_BSRSM2_ANALYSIS_ARGTYPES(c10::complex)); +template <> +void bsrsm2_analysis>( + CUSPARSE_BSRSM2_ANALYSIS_ARGTYPES(c10::complex)); + +#define CUSPARSE_BSRSM2_SOLVE_ARGTYPES(scalar_t) \ + cusparseHandle_t handle, cusparseDirection_t dirA, \ + cusparseOperation_t transA, cusparseOperation_t transX, int mb, int n, \ + int nnzb, const scalar_t *alpha, const cusparseMatDescr_t descrA, \ + const scalar_t *bsrValA, const int *bsrRowPtrA, const int *bsrColIndA, \ + int blockDim, bsrsm2Info_t info, const scalar_t *B, int ldb, \ + scalar_t *X, int ldx, cusparseSolvePolicy_t policy, void *pBuffer + +template +inline void bsrsm2_solve(CUSPARSE_BSRSM2_SOLVE_ARGTYPES(scalar_t)) { + TORCH_INTERNAL_ASSERT( + false, + "at::cuda::sparse::bsrsm2_solve: not implemented for ", + typeid(scalar_t).name()); +} + +template <> +void bsrsm2_solve(CUSPARSE_BSRSM2_SOLVE_ARGTYPES(float)); +template <> +void bsrsm2_solve(CUSPARSE_BSRSM2_SOLVE_ARGTYPES(double)); +template <> +void bsrsm2_solve>( + CUSPARSE_BSRSM2_SOLVE_ARGTYPES(c10::complex)); +template <> +void bsrsm2_solve>( + CUSPARSE_BSRSM2_SOLVE_ARGTYPES(c10::complex)); + +#endif // AT_USE_HIPSPARSE_TRIANGULAR_SOLVE + +} // namespace at::cuda::sparse +// NOLINTEND(misc-misplaced-const) diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDASparseDescriptors.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDASparseDescriptors.h new file mode 100644 index 0000000000000000000000000000000000000000..7fc482f2a3fbd024e9c80afd0af8c19a13261de5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDASparseDescriptors.h @@ -0,0 +1,288 @@ +#pragma once + +#include +#include +#include + +#include + +#if defined(USE_ROCM) +#include +#endif + +namespace at::cuda::sparse { + +template +struct CuSparseDescriptorDeleter { + void operator()(T* x) { + if (x != nullptr) { + TORCH_CUDASPARSE_CHECK(destructor(x)); + } + } +}; + +template +class CuSparseDescriptor { + public: + T* descriptor() const { + return descriptor_.get(); + } + T* descriptor() { + return descriptor_.get(); + } + + protected: + std::unique_ptr> descriptor_; +}; + +#if AT_USE_CUSPARSE_CONST_DESCRIPTORS() || AT_USE_HIPSPARSE_CONST_DESCRIPTORS() +template +struct ConstCuSparseDescriptorDeleter { + void operator()(T* x) { + if (x != nullptr) { + TORCH_CUDASPARSE_CHECK(destructor(x)); + } + } +}; + +template +class ConstCuSparseDescriptor { + public: + T* descriptor() const { + return descriptor_.get(); + } + T* descriptor() { + return descriptor_.get(); + } + + protected: + std::unique_ptr> descriptor_; +}; +#endif // AT_USE_CUSPARSE_CONST_DESCRIPTORS || AT_USE_HIPSPARSE_CONST_DESCRIPTORS + +#if defined(USE_ROCM) +using cusparseMatDescr = std::remove_pointer_t; +using cusparseDnMatDescr = std::remove_pointer_t; +using cusparseDnVecDescr = std::remove_pointer_t; +using cusparseSpMatDescr = std::remove_pointer_t; +using cusparseSpMatDescr = std::remove_pointer_t; +using cusparseSpGEMMDescr = std::remove_pointer_t; +#if AT_USE_HIPSPARSE_TRIANGULAR_SOLVE() +using bsrsv2Info = std::remove_pointer_t; +using bsrsm2Info = std::remove_pointer_t; +#endif +#endif + +// NOTE: This is only needed for CUDA 11 and earlier, since CUDA 12 introduced +// API for const descriptors +cusparseStatus_t destroyConstDnMat(const cusparseDnMatDescr* dnMatDescr); + +class TORCH_CUDA_CPP_API CuSparseMatDescriptor + : public CuSparseDescriptor { + public: + CuSparseMatDescriptor() { + cusparseMatDescr_t raw_descriptor = nullptr; + TORCH_CUDASPARSE_CHECK(cusparseCreateMatDescr(&raw_descriptor)); + descriptor_.reset(raw_descriptor); + } + + CuSparseMatDescriptor(bool upper, bool unit) { + cusparseFillMode_t fill_mode = + upper ? CUSPARSE_FILL_MODE_UPPER : CUSPARSE_FILL_MODE_LOWER; + cusparseDiagType_t diag_type = + unit ? CUSPARSE_DIAG_TYPE_UNIT : CUSPARSE_DIAG_TYPE_NON_UNIT; + cusparseMatDescr_t raw_descriptor = nullptr; + TORCH_CUDASPARSE_CHECK(cusparseCreateMatDescr(&raw_descriptor)); + TORCH_CUDASPARSE_CHECK(cusparseSetMatFillMode(raw_descriptor, fill_mode)); + TORCH_CUDASPARSE_CHECK(cusparseSetMatDiagType(raw_descriptor, diag_type)); + descriptor_.reset(raw_descriptor); + } +}; + +#if AT_USE_HIPSPARSE_TRIANGULAR_SOLVE() + +class TORCH_CUDA_CPP_API CuSparseBsrsv2Info + : public CuSparseDescriptor { + public: + CuSparseBsrsv2Info() { + bsrsv2Info_t raw_descriptor = nullptr; + TORCH_CUDASPARSE_CHECK(cusparseCreateBsrsv2Info(&raw_descriptor)); + descriptor_.reset(raw_descriptor); + } +}; + +class TORCH_CUDA_CPP_API CuSparseBsrsm2Info + : public CuSparseDescriptor { + public: + CuSparseBsrsm2Info() { + bsrsm2Info_t raw_descriptor = nullptr; + TORCH_CUDASPARSE_CHECK(cusparseCreateBsrsm2Info(&raw_descriptor)); + descriptor_.reset(raw_descriptor); + } +}; + +#endif // AT_USE_HIPSPARSE_TRIANGULAR_SOLVE + +#if AT_USE_CUSPARSE_GENERIC_API() || AT_USE_HIPSPARSE_GENERIC_API() + +cusparseIndexType_t getCuSparseIndexType(const c10::ScalarType& scalar_type); + +#if AT_USE_CUSPARSE_NON_CONST_DESCRIPTORS() || AT_USE_HIPSPARSE_NON_CONST_DESCRIPTORS() +class TORCH_CUDA_CPP_API CuSparseDnMatDescriptor + : public CuSparseDescriptor { + public: + explicit CuSparseDnMatDescriptor(const Tensor& input, int64_t batch_offset = -1); +}; + +class TORCH_CUDA_CPP_API CuSparseConstDnMatDescriptor + : public CuSparseDescriptor { + public: + explicit CuSparseConstDnMatDescriptor(const Tensor& input, int64_t batch_offset = -1); + cusparseDnMatDescr* unsafe_mutable_descriptor() const { + return const_cast(descriptor()); + } + cusparseDnMatDescr* unsafe_mutable_descriptor() { + return const_cast(descriptor()); + } +}; + +class TORCH_CUDA_CPP_API CuSparseDnVecDescriptor + : public CuSparseDescriptor { + public: + explicit CuSparseDnVecDescriptor(const Tensor& input); +}; + +class TORCH_CUDA_CPP_API CuSparseSpMatDescriptor + : public CuSparseDescriptor {}; + +#elif AT_USE_CUSPARSE_CONST_DESCRIPTORS() || AT_USE_HIPSPARSE_CONST_DESCRIPTORS() + class TORCH_CUDA_CPP_API CuSparseDnMatDescriptor + : public ConstCuSparseDescriptor< + cusparseDnMatDescr, + &cusparseDestroyDnMat> { + public: + explicit CuSparseDnMatDescriptor( + const Tensor& input, + int64_t batch_offset = -1); + }; + + class TORCH_CUDA_CPP_API CuSparseConstDnMatDescriptor + : public ConstCuSparseDescriptor< + const cusparseDnMatDescr, + &destroyConstDnMat> { + public: + explicit CuSparseConstDnMatDescriptor( + const Tensor& input, + int64_t batch_offset = -1); + cusparseDnMatDescr* unsafe_mutable_descriptor() const { + return const_cast(descriptor()); + } + cusparseDnMatDescr* unsafe_mutable_descriptor() { + return const_cast(descriptor()); + } + }; + + class TORCH_CUDA_CPP_API CuSparseDnVecDescriptor + : public ConstCuSparseDescriptor< + cusparseDnVecDescr, + &cusparseDestroyDnVec> { + public: + explicit CuSparseDnVecDescriptor(const Tensor& input); + }; + + class TORCH_CUDA_CPP_API CuSparseSpMatDescriptor + : public ConstCuSparseDescriptor< + cusparseSpMatDescr, + &cusparseDestroySpMat> {}; +#endif // AT_USE_CUSPARSE_CONST_DESCRIPTORS() || AT_USE_HIPSPARSE_CONST_DESCRIPTORS() + +class TORCH_CUDA_CPP_API CuSparseSpMatCsrDescriptor + : public CuSparseSpMatDescriptor { + public: + explicit CuSparseSpMatCsrDescriptor(const Tensor& input, int64_t batch_offset = -1); + + std::tuple get_size() { + int64_t rows = 0, cols = 0, nnz = 0; + TORCH_CUDASPARSE_CHECK(cusparseSpMatGetSize( + this->descriptor(), + &rows, + &cols, + &nnz)); + return std::make_tuple(rows, cols, nnz); + } + + void set_tensor(const Tensor& input) { + auto crow_indices = input.crow_indices(); + auto col_indices = input.col_indices(); + auto values = input.values(); + + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(crow_indices.is_contiguous()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(col_indices.is_contiguous()); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(values.is_contiguous()); + TORCH_CUDASPARSE_CHECK(cusparseCsrSetPointers( + this->descriptor(), + crow_indices.data_ptr(), + col_indices.data_ptr(), + values.data_ptr())); + } + +#if AT_USE_CUSPARSE_GENERIC_SPSV() + void set_mat_fill_mode(bool upper) { + cusparseFillMode_t fill_mode = + upper ? CUSPARSE_FILL_MODE_UPPER : CUSPARSE_FILL_MODE_LOWER; + TORCH_CUDASPARSE_CHECK(cusparseSpMatSetAttribute( + this->descriptor(), + CUSPARSE_SPMAT_FILL_MODE, + &fill_mode, + sizeof(fill_mode))); + } + + void set_mat_diag_type(bool unit) { + cusparseDiagType_t diag_type = + unit ? CUSPARSE_DIAG_TYPE_UNIT : CUSPARSE_DIAG_TYPE_NON_UNIT; + TORCH_CUDASPARSE_CHECK(cusparseSpMatSetAttribute( + this->descriptor(), + CUSPARSE_SPMAT_DIAG_TYPE, + &diag_type, + sizeof(diag_type))); + } +#endif +}; + +#if AT_USE_CUSPARSE_GENERIC_SPSV() +class TORCH_CUDA_CPP_API CuSparseSpSVDescriptor + : public CuSparseDescriptor { + public: + CuSparseSpSVDescriptor() { + cusparseSpSVDescr_t raw_descriptor = nullptr; + TORCH_CUDASPARSE_CHECK(cusparseSpSV_createDescr(&raw_descriptor)); + descriptor_.reset(raw_descriptor); + } +}; +#endif + +#if AT_USE_CUSPARSE_GENERIC_SPSM() +class TORCH_CUDA_CPP_API CuSparseSpSMDescriptor + : public CuSparseDescriptor { + public: + CuSparseSpSMDescriptor() { + cusparseSpSMDescr_t raw_descriptor = nullptr; + TORCH_CUDASPARSE_CHECK(cusparseSpSM_createDescr(&raw_descriptor)); + descriptor_.reset(raw_descriptor); + } +}; +#endif + +class TORCH_CUDA_CPP_API CuSparseSpGEMMDescriptor + : public CuSparseDescriptor { + public: + CuSparseSpGEMMDescriptor() { + cusparseSpGEMMDescr_t raw_descriptor = nullptr; + TORCH_CUDASPARSE_CHECK(cusparseSpGEMM_createDescr(&raw_descriptor)); + descriptor_.reset(raw_descriptor); + } +}; + +#endif // AT_USE_CUSPARSE_GENERIC_API() || AT_USE_HIPSPARSE_GENERIC_API() + +} // namespace at::cuda::sparse diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDATensorMethods.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDATensorMethods.cuh new file mode 100644 index 0000000000000000000000000000000000000000..e4e89ea1cdb77da1d7866ffe99c64dabfd735d27 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDATensorMethods.cuh @@ -0,0 +1,15 @@ +#pragma once + +#include +#include + +#include +#include +#include + +namespace at { +template <> +inline __half* Tensor::data() const { + return reinterpret_cast<__half*>(data()); +} +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..d5f65dd6a572f9cab15dbae9983df8037b724a99 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CUDAUtils.h @@ -0,0 +1,20 @@ +#pragma once + +#include + +namespace at::cuda { + +// Check if every tensor in a list of tensors matches the current +// device. +inline bool check_device(ArrayRef ts) { + if (ts.empty()) { + return true; + } + Device curDevice = Device(kCUDA, current_device()); + for (const Tensor& t : ts) { + if (t.device() != curDevice) return false; + } + return true; +} + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CachingHostAllocator.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CachingHostAllocator.h new file mode 100644 index 0000000000000000000000000000000000000000..6c33dfaeb534f36a7ae79a12bb04964eb4da9899 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/CachingHostAllocator.h @@ -0,0 +1,42 @@ +#pragma once + +#include +#include +#include + +namespace at::cuda { + +// +// A caching allocator for CUDA host allocations (pinned memory). +// +// This provides a drop-in replacement for THCudaHostAllocator, which re-uses +// freed pinned (page-locked) memory allocations. This avoids device +// synchronizations due to cudaFreeHost calls. +// +// To ensure correct behavior, THCCachingHostAllocator_recordEvent must be +// called anytime a pointer from this allocator is used in a cudaMemcpyAsync +// call between host and device, and passed the corresponding context from the +// allocation. This is currently invoked by at::native::copy_kernel_cuda. +// +TORCH_CUDA_CPP_API c10::Allocator* getCachingHostAllocator(); + +// Records an event in the specified stream. The allocation corresponding to the +// input `ptr`/`ctx` will not be re-used until the event has occurred. +TORCH_CUDA_CPP_API bool CachingHostAllocator_recordEvent( + void* ptr, + void* ctx, + c10::cuda::CUDAStream stream); + +// Releases cached pinned memory allocations via cudaHostFree +TORCH_CUDA_CPP_API void CachingHostAllocator_emptyCache(); + +inline TORCH_CUDA_CPP_API at::DataPtr HostAlloc(size_t size) { + return getCachingHostAllocator()->allocate(size); +} + +TORCH_CUDA_CPP_API at::HostStats CachingHostAllocator_getStats(); + +TORCH_CUDA_CPP_API void CachingHostAllocator_resetAccumulatedStats(); +TORCH_CUDA_CPP_API void CachingHostAllocator_resetPeakStats(); + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/DeviceUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/DeviceUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..c0a2fc47c0069bed4e15beec249162a556f7dc3d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/DeviceUtils.cuh @@ -0,0 +1,121 @@ +#pragma once + +#include +#include +#include + +__device__ __forceinline__ unsigned int ACTIVE_MASK() +{ +#if !defined(USE_ROCM) + return __activemask(); +#else +// will be ignored anyway + return 0xffffffff; +#endif +} + +__device__ __forceinline__ void WARP_SYNC(unsigned mask = 0xffffffff) { +#if !defined(USE_ROCM) + return __syncwarp(mask); +#endif +} + +#if defined(USE_ROCM) +__device__ __forceinline__ unsigned long long int WARP_BALLOT(int predicate) +{ +return __ballot(predicate); +} +#else +__device__ __forceinline__ unsigned int WARP_BALLOT(int predicate, unsigned int mask = 0xffffffff) +{ +#if !defined(USE_ROCM) + return __ballot_sync(mask, predicate); +#else + return __ballot(predicate); +#endif +} +#endif + +template +__device__ __forceinline__ T WARP_SHFL_XOR(T value, int laneMask, int width = warpSize, unsigned int mask = 0xffffffff) +{ +#if !defined(USE_ROCM) + return __shfl_xor_sync(mask, value, laneMask, width); +#else + return __shfl_xor(value, laneMask, width); +#endif +} + +template +__device__ __forceinline__ T WARP_SHFL(T value, int srcLane, int width = warpSize, unsigned int mask = 0xffffffff) +{ +#if !defined(USE_ROCM) + return __shfl_sync(mask, value, srcLane, width); +#else + return __shfl(value, srcLane, width); +#endif +} + +template +__device__ __forceinline__ T WARP_SHFL_UP(T value, unsigned int delta, int width = warpSize, unsigned int mask = 0xffffffff) +{ +#if !defined(USE_ROCM) + return __shfl_up_sync(mask, value, delta, width); +#else + return __shfl_up(value, delta, width); +#endif +} + +template +__device__ __forceinline__ T WARP_SHFL_DOWN(T value, unsigned int delta, int width = warpSize, unsigned int mask = 0xffffffff) +{ +#if !defined(USE_ROCM) + return __shfl_down_sync(mask, value, delta, width); +#else + return __shfl_down(value, delta, width); +#endif +} + +#if defined(USE_ROCM) +template<> +__device__ __forceinline__ int64_t WARP_SHFL_DOWN(int64_t value, unsigned int delta, int width , unsigned int mask) +{ + //(HIP doesn't support int64_t). Trick from https://devblogs.nvidia.com/faster-parallel-reductions-kepler/ + int2 a = *reinterpret_cast(&value); + a.x = __shfl_down(a.x, delta); + a.y = __shfl_down(a.y, delta); + return *reinterpret_cast(&a); +} +#endif + +template<> +__device__ __forceinline__ c10::Half WARP_SHFL_DOWN(c10::Half value, unsigned int delta, int width, unsigned int mask) +{ + return c10::Half(WARP_SHFL_DOWN(value.x, delta, width, mask), c10::Half::from_bits_t{}); +} + +template +__device__ __forceinline__ c10::complex WARP_SHFL_DOWN(c10::complex value, unsigned int delta, int width = warpSize, unsigned int mask = 0xffffffff) +{ +#if !defined(USE_ROCM) + return c10::complex( + __shfl_down_sync(mask, value.real_, delta, width), + __shfl_down_sync(mask, value.imag_, delta, width)); +#else + return c10::complex( + __shfl_down(value.real_, delta, width), + __shfl_down(value.imag_, delta, width)); +#endif +} + +/** + * For CC 3.5+, perform a load using __ldg + */ +template +__device__ __forceinline__ T doLdg(const T* p) { +#if __CUDA_ARCH__ >= 350 && !defined(USE_ROCM) + return __ldg(p); +#else + return *p; +#endif +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/EmptyTensor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/EmptyTensor.h new file mode 100644 index 0000000000000000000000000000000000000000..2fd88a94b75d2ca72133c253eca800295a1771aa --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/EmptyTensor.h @@ -0,0 +1,44 @@ +#pragma once +#include + +namespace at::detail { + +TORCH_CUDA_CPP_API TensorBase empty_cuda( + IntArrayRef size, + ScalarType dtype, + std::optional device_opt, + std::optional memory_format_opt); + +TORCH_CUDA_CPP_API TensorBase empty_cuda( + IntArrayRef size, + std::optional dtype_opt, + std::optional layout_opt, + std::optional device_opt, + std::optional pin_memory_opt, + std::optional memory_format_opt); + +TORCH_CUDA_CPP_API TensorBase empty_cuda( + IntArrayRef size, + const TensorOptions &options); + +TORCH_CUDA_CPP_API TensorBase empty_strided_cuda( + IntArrayRef size, + IntArrayRef stride, + ScalarType dtype, + std::optional device_opt); + +TORCH_CUDA_CPP_API TensorBase empty_strided_cuda( + IntArrayRef size, + IntArrayRef stride, + std::optional dtype_opt, + std::optional layout_opt, + std::optional device_opt, + std::optional pin_memory_opt); + +TORCH_CUDA_CPP_API TensorBase empty_strided_cuda( + IntArrayRef size, + IntArrayRef stride, + const TensorOptions &options); + + +} // namespace at::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/Exceptions.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/Exceptions.h new file mode 100644 index 0000000000000000000000000000000000000000..7a24151df205eeb53b2fd0def4b7992ae4ef4876 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/Exceptions.h @@ -0,0 +1,234 @@ +#pragma once + +#include +#include +#include + +#if !defined(USE_ROCM) +#include +#else +#include +#endif + +#if defined(USE_CUDSS) +#include +#endif + +#include +#include +#include + + +namespace c10 { + +class CuDNNError : public c10::Error { + using Error::Error; +}; + +} // namespace c10 + +#define AT_CUDNN_FRONTEND_CHECK(EXPR, ...) \ + do { \ + auto error_object = EXPR; \ + if (!error_object.is_good()) { \ + TORCH_CHECK_WITH(CuDNNError, false, \ + "cuDNN Frontend error: ", error_object.get_message()); \ + } \ + } while (0) \ + +#define AT_CUDNN_CHECK_WITH_SHAPES(EXPR, ...) AT_CUDNN_CHECK(EXPR, "\n", ##__VA_ARGS__) + +// See Note [CHECK macro] +#define AT_CUDNN_CHECK(EXPR, ...) \ + do { \ + cudnnStatus_t status = EXPR; \ + if (status != CUDNN_STATUS_SUCCESS) { \ + if (status == CUDNN_STATUS_NOT_SUPPORTED) { \ + TORCH_CHECK_WITH(CuDNNError, false, \ + "cuDNN error: ", \ + cudnnGetErrorString(status), \ + ". This error may appear if you passed in a non-contiguous input.", ##__VA_ARGS__); \ + } else { \ + TORCH_CHECK_WITH(CuDNNError, false, \ + "cuDNN error: ", cudnnGetErrorString(status), ##__VA_ARGS__); \ + } \ + } \ + } while (0) + +namespace at::cuda::blas { +C10_EXPORT const char* _cublasGetErrorEnum(cublasStatus_t error); +} // namespace at::cuda::blas + +#define TORCH_CUDABLAS_CHECK(EXPR) \ + do { \ + cublasStatus_t __err = EXPR; \ + TORCH_CHECK(__err == CUBLAS_STATUS_SUCCESS, \ + "CUDA error: ", \ + at::cuda::blas::_cublasGetErrorEnum(__err), \ + " when calling `" #EXPR "`"); \ + } while (0) + +const char *cusparseGetErrorString(cusparseStatus_t status); + +#define TORCH_CUDASPARSE_CHECK(EXPR) \ + do { \ + cusparseStatus_t __err = EXPR; \ + TORCH_CHECK(__err == CUSPARSE_STATUS_SUCCESS, \ + "CUDA error: ", \ + cusparseGetErrorString(__err), \ + " when calling `" #EXPR "`"); \ + } while (0) + +#if defined(USE_CUDSS) +namespace at::cuda::cudss { +C10_EXPORT const char* cudssGetErrorMessage(cudssStatus_t error); +} // namespace at::cuda::solver + +#define TORCH_CUDSS_CHECK(EXPR) \ + do { \ + cudssStatus_t __err = EXPR; \ + if (__err == CUDSS_STATUS_EXECUTION_FAILED) { \ + TORCH_CHECK_LINALG( \ + false, \ + "cudss error: ", \ + at::cuda::cudss::cudssGetErrorMessage(__err), \ + ", when calling `" #EXPR "`", \ + ". This error may appear if the input matrix contains NaN. ");\ + } else { \ + TORCH_CHECK( \ + __err == CUDSS_STATUS_SUCCESS, \ + "cudss error: ", \ + at::cuda::cudss::cudssGetErrorMessage(__err), \ + ", when calling `" #EXPR "`. "); \ + } \ + } while (0) +#else +#define TORCH_CUDSS_CHECK(EXPR) EXPR +#endif + +namespace at::cuda::solver { +#if !defined(USE_ROCM) + +C10_EXPORT const char* cusolverGetErrorMessage(cusolverStatus_t status); + +constexpr const char* _cusolver_backend_suggestion = \ + "If you keep seeing this error, you may use " \ + "`torch.backends.cuda.preferred_linalg_library()` to try " \ + "linear algebra operators with other supported backends. " \ + "See https://pytorch.org/docs/stable/backends.html#torch.backends.cuda.preferred_linalg_library"; + +// When cuda < 11.5, cusolver raises CUSOLVER_STATUS_EXECUTION_FAILED when input contains nan. +// When cuda >= 11.5, cusolver normally finishes execution and sets info array indicating convergence issue. +#define TORCH_CUSOLVER_CHECK(EXPR) \ + do { \ + cusolverStatus_t __err = EXPR; \ + if ((CUDA_VERSION < 11500 && \ + __err == CUSOLVER_STATUS_EXECUTION_FAILED) || \ + (CUDA_VERSION >= 11500 && \ + __err == CUSOLVER_STATUS_INVALID_VALUE)) { \ + TORCH_CHECK_LINALG( \ + false, \ + "cusolver error: ", \ + at::cuda::solver::cusolverGetErrorMessage(__err), \ + ", when calling `" #EXPR "`", \ + ". This error may appear if the input matrix contains NaN. ", \ + at::cuda::solver::_cusolver_backend_suggestion); \ + } else { \ + TORCH_CHECK( \ + __err == CUSOLVER_STATUS_SUCCESS, \ + "cusolver error: ", \ + at::cuda::solver::cusolverGetErrorMessage(__err), \ + ", when calling `" #EXPR "`. ", \ + at::cuda::solver::_cusolver_backend_suggestion); \ + } \ + } while (0) + +#else // defined(USE_ROCM) + +C10_EXPORT const char* hipsolverGetErrorMessage(hipsolverStatus_t status); + +constexpr const char* _hipsolver_backend_suggestion = \ + "If you keep seeing this error, you may use " \ + "`torch.backends.cuda.preferred_linalg_library()` to try " \ + "linear algebra operators with other supported backends. " \ + "See https://pytorch.org/docs/stable/backends.html#torch.backends.cuda.preferred_linalg_library"; + +#define TORCH_CUSOLVER_CHECK(EXPR) \ + do { \ + hipsolverStatus_t __err = EXPR; \ + if (__err == HIPSOLVER_STATUS_INVALID_VALUE) { \ + TORCH_CHECK_LINALG( \ + false, \ + "hipsolver error: ", \ + at::cuda::solver::hipsolverGetErrorMessage(__err), \ + ", when calling `" #EXPR "`", \ + ". This error may appear if the input matrix contains NaN. ", \ + at::cuda::solver::_hipsolver_backend_suggestion); \ + } else { \ + TORCH_CHECK( \ + __err == HIPSOLVER_STATUS_SUCCESS, \ + "hipsolver error: ", \ + at::cuda::solver::hipsolverGetErrorMessage(__err), \ + ", when calling `" #EXPR "`. ", \ + at::cuda::solver::_hipsolver_backend_suggestion); \ + } \ + } while (0) +#endif +} // namespace at::cuda::solver + +#define AT_CUDA_CHECK(EXPR) C10_CUDA_CHECK(EXPR) + +// For CUDA Driver API +// +// This is here instead of in c10 because NVRTC is loaded dynamically via a stub +// in ATen, and we need to use its nvrtcGetErrorString. +// See NOTE [ USE OF NVRTC AND DRIVER API ]. +#if !defined(USE_ROCM) + +#define AT_CUDA_DRIVER_CHECK(EXPR) \ + do { \ + CUresult __err = EXPR; \ + if (__err != CUDA_SUCCESS) { \ + const char* err_str; \ + [[maybe_unused]] CUresult get_error_str_err = \ + at::globalContext().getNVRTC().cuGetErrorString(__err, &err_str); \ + if (get_error_str_err != CUDA_SUCCESS) { \ + TORCH_CHECK(false, "CUDA driver error: unknown error"); \ + } else { \ + TORCH_CHECK(false, "CUDA driver error: ", err_str); \ + } \ + } \ + } while (0) + +#else + +#define AT_CUDA_DRIVER_CHECK(EXPR) \ + do { \ + CUresult __err = EXPR; \ + if (__err != CUDA_SUCCESS) { \ + TORCH_CHECK(false, "CUDA driver error: ", static_cast(__err)); \ + } \ + } while (0) + +#endif + +// For CUDA NVRTC +// +// Note: As of CUDA 10, nvrtc error code 7, NVRTC_ERROR_BUILTIN_OPERATION_FAILURE, +// incorrectly produces the error string "NVRTC unknown error." +// The following maps it correctly. +// +// This is here instead of in c10 because NVRTC is loaded dynamically via a stub +// in ATen, and we need to use its nvrtcGetErrorString. +// See NOTE [ USE OF NVRTC AND DRIVER API ]. +#define AT_CUDA_NVRTC_CHECK(EXPR) \ + do { \ + nvrtcResult __err = EXPR; \ + if (__err != NVRTC_SUCCESS) { \ + if (static_cast(__err) != 7) { \ + TORCH_CHECK(false, "CUDA NVRTC error: ", at::globalContext().getNVRTC().nvrtcGetErrorString(__err)); \ + } else { \ + TORCH_CHECK(false, "CUDA NVRTC error: NVRTC_ERROR_BUILTIN_OPERATION_FAILURE"); \ + } \ + } \ + } while (0) diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/NumericLimits.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/NumericLimits.cuh new file mode 100644 index 0000000000000000000000000000000000000000..7081e94837caa7d5050128e0bfe19aa67f93cd39 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/NumericLimits.cuh @@ -0,0 +1,121 @@ +#pragma once + +#include +#include +#include +#include + +// NumericLimits.cuh is a holder for numeric limits definitions of commonly used +// types. This header is very specific to ROCm HIP and may be removed in the future. +// This header is derived from the legacy THCNumerics.cuh. + +// The lower_bound and upper_bound constants are same as lowest and max for +// integral types, but are -inf and +inf for floating point types. They are +// useful in implementing min, max, etc. + +namespace at { + +template +struct numeric_limits { +}; + +// WARNING: the following at::numeric_limits definitions are there only to support +// HIP compilation for the moment. Use std::numeric_limits if you are not +// compiling for ROCm. +// from @colesbury: "The functions on numeric_limits aren't marked with +// __device__ which is why they don't work with ROCm. CUDA allows them +// because they're constexpr." + +namespace { + // ROCm doesn't like INFINITY too. + constexpr double inf = INFINITY; +} + +template <> +struct numeric_limits { + static inline __host__ __device__ bool lowest() { return false; } + static inline __host__ __device__ bool max() { return true; } + static inline __host__ __device__ bool lower_bound() { return false; } + static inline __host__ __device__ bool upper_bound() { return true; } +}; + +template <> +struct numeric_limits { + static inline __host__ __device__ uint8_t lowest() { return 0; } + static inline __host__ __device__ uint8_t max() { return UINT8_MAX; } + static inline __host__ __device__ uint8_t lower_bound() { return 0; } + static inline __host__ __device__ uint8_t upper_bound() { return UINT8_MAX; } +}; + +template <> +struct numeric_limits { + static inline __host__ __device__ int8_t lowest() { return INT8_MIN; } + static inline __host__ __device__ int8_t max() { return INT8_MAX; } + static inline __host__ __device__ int8_t lower_bound() { return INT8_MIN; } + static inline __host__ __device__ int8_t upper_bound() { return INT8_MAX; } +}; + +template <> +struct numeric_limits { + static inline __host__ __device__ int16_t lowest() { return INT16_MIN; } + static inline __host__ __device__ int16_t max() { return INT16_MAX; } + static inline __host__ __device__ int16_t lower_bound() { return INT16_MIN; } + static inline __host__ __device__ int16_t upper_bound() { return INT16_MAX; } +}; + +template <> +struct numeric_limits { + static inline __host__ __device__ int32_t lowest() { return INT32_MIN; } + static inline __host__ __device__ int32_t max() { return INT32_MAX; } + static inline __host__ __device__ int32_t lower_bound() { return INT32_MIN; } + static inline __host__ __device__ int32_t upper_bound() { return INT32_MAX; } +}; + +template <> +struct numeric_limits { +#ifdef _MSC_VER + static inline __host__ __device__ int64_t lowest() { return _I64_MIN; } + static inline __host__ __device__ int64_t max() { return _I64_MAX; } + static inline __host__ __device__ int64_t lower_bound() { return _I64_MIN; } + static inline __host__ __device__ int64_t upper_bound() { return _I64_MAX; } +#else + static inline __host__ __device__ int64_t lowest() { return INT64_MIN; } + static inline __host__ __device__ int64_t max() { return INT64_MAX; } + static inline __host__ __device__ int64_t lower_bound() { return INT64_MIN; } + static inline __host__ __device__ int64_t upper_bound() { return INT64_MAX; } +#endif +}; + +template <> +struct numeric_limits { + static inline __host__ __device__ at::Half lowest() { return at::Half(0xFBFF, at::Half::from_bits()); } + static inline __host__ __device__ at::Half max() { return at::Half(0x7BFF, at::Half::from_bits()); } + static inline __host__ __device__ at::Half lower_bound() { return at::Half(0xFC00, at::Half::from_bits()); } + static inline __host__ __device__ at::Half upper_bound() { return at::Half(0x7C00, at::Half::from_bits()); } +}; + +template <> +struct numeric_limits { + static inline __host__ __device__ at::BFloat16 lowest() { return at::BFloat16(0xFF7F, at::BFloat16::from_bits()); } + static inline __host__ __device__ at::BFloat16 max() { return at::BFloat16(0x7F7F, at::BFloat16::from_bits()); } + static inline __host__ __device__ at::BFloat16 lower_bound() { return at::BFloat16(0xFF80, at::BFloat16::from_bits()); } + static inline __host__ __device__ at::BFloat16 upper_bound() { return at::BFloat16(0x7F80, at::BFloat16::from_bits()); } +}; + +template <> +struct numeric_limits { + static inline __host__ __device__ float lowest() { return -FLT_MAX; } + static inline __host__ __device__ float max() { return FLT_MAX; } + static inline __host__ __device__ float lower_bound() { return -static_cast(inf); } + static inline __host__ __device__ float upper_bound() { return static_cast(inf); } +}; + +template <> +struct numeric_limits { + static inline __host__ __device__ double lowest() { return -DBL_MAX; } + static inline __host__ __device__ double max() { return DBL_MAX; } + static inline __host__ __device__ double lower_bound() { return -inf; } + static inline __host__ __device__ double upper_bound() { return inf; } +}; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PeerToPeerAccess.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PeerToPeerAccess.h new file mode 100644 index 0000000000000000000000000000000000000000..5b63a855f3f46e8738f01749120f508d4fd7902e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PeerToPeerAccess.h @@ -0,0 +1,12 @@ +#include +#include +#include + +namespace at::cuda { +namespace detail { +void init_p2p_access_cache(int64_t num_devices); +} + +TORCH_CUDA_CPP_API bool get_p2p_access(c10::DeviceIndex source_dev, c10::DeviceIndex dest_dev); + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PhiloxCudaState.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PhiloxCudaState.h new file mode 100644 index 0000000000000000000000000000000000000000..dc4b131aa9c4b468092c5819f2c4aa321be8ca30 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PhiloxCudaState.h @@ -0,0 +1,5 @@ +#pragma once + +#include + +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PhiloxUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PhiloxUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..0b161b70d96f428512cf6c26c3acc1654da74bf0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PhiloxUtils.cuh @@ -0,0 +1,4 @@ +#pragma once + +#include +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PinnedMemoryAllocator.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PinnedMemoryAllocator.h new file mode 100644 index 0000000000000000000000000000000000000000..854f5d8dd1297e3b99fe347358291c9a97c37e1e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/PinnedMemoryAllocator.h @@ -0,0 +1,11 @@ +#pragma once + +#include +#include + +namespace at::cuda { + +inline TORCH_CUDA_CPP_API at::Allocator* getPinnedMemoryAllocator() { + return getCachingHostAllocator(); +} +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ScanUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ScanUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..fd8b9e91d48815761e7234b0d6fbcaab7f62fcee --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ScanUtils.cuh @@ -0,0 +1,78 @@ +#pragma once + +#include +#include +#include +#include + +// Collection of in-kernel scan / prefix sum utilities + +namespace at::cuda { + +// Inclusive prefix sum for binary vars using intra-warp voting + +// shared memory +template +__device__ void inclusiveBinaryPrefixScan(T* smem, bool in, T* out, BinaryFunction binop) { + // Within-warp, we use warp voting. +#if defined (USE_ROCM) + unsigned long long int vote = WARP_BALLOT(in); + T index = __popcll(getLaneMaskLe() & vote); + T carry = __popcll(vote); +#else + T vote = WARP_BALLOT(in); + T index = __popc(getLaneMaskLe() & vote); + T carry = __popc(vote); +#endif + + int warp = threadIdx.x / C10_WARP_SIZE; + + // Per each warp, write out a value + if (getLaneId() == 0) { + smem[warp] = carry; + } + + __syncthreads(); + + // Sum across warps in one thread. This appears to be faster than a + // warp shuffle scan for CC 3.0+ + if (threadIdx.x == 0) { + int current = 0; + for (int i = 0; i < blockDim.x / C10_WARP_SIZE; ++i) { + T v = smem[i]; + smem[i] = binop(smem[i], current); + current = binop(current, v); + } + } + + __syncthreads(); + + // load the carry from the preceding warp + if (warp >= 1) { + index = binop(index, smem[warp - 1]); + } + + *out = index; + + if (KillWARDependency) { + __syncthreads(); + } +} + +// Exclusive prefix sum for binary vars using intra-warp voting + +// shared memory +template +__device__ void exclusiveBinaryPrefixScan(T* smem, bool in, T* out, T* carry, BinaryFunction binop) { + inclusiveBinaryPrefixScan(smem, in, out, binop); + + // Inclusive to exclusive + *out -= (T) in; + + // The outgoing carry for all threads is the last warp's sum + *carry = smem[at::ceil_div(blockDim.x, C10_WARP_SIZE) - 1]; + + if (KillWARDependency) { + __syncthreads(); + } +} + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/Sleep.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/Sleep.h new file mode 100644 index 0000000000000000000000000000000000000000..ef5e83a832f739e19f13837500824c984013812e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/Sleep.h @@ -0,0 +1,13 @@ +#pragma once +#include +#include + +namespace at::cuda { + +// enqueues a kernel that spins for the specified number of cycles +TORCH_CUDA_CU_API void sleep(int64_t cycles); + +// flushes instruction cache for ROCm; no-op for CUDA +TORCH_CUDA_CU_API void flush_icache(); + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ThrustAllocator.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ThrustAllocator.h new file mode 100644 index 0000000000000000000000000000000000000000..85783c303534ec9f6190c2d6bb44a8faafd680f7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/ThrustAllocator.h @@ -0,0 +1,23 @@ +#pragma once + +#include +#include + +namespace at::cuda { + +/// Allocator for Thrust to re-route its internal device allocations +/// to the THC allocator +class ThrustAllocator { +public: + typedef char value_type; + + char* allocate(std::ptrdiff_t size) { + return static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(size)); + } + + void deallocate(char* p, size_t size) { + c10::cuda::CUDACachingAllocator::raw_delete(p); + } +}; + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/cub.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/cub.cuh new file mode 100644 index 0000000000000000000000000000000000000000..a1a7ab70630bd81e519b1129546937f41a88366b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/cub.cuh @@ -0,0 +1,626 @@ +#pragma once +#include + +#include +#include +#include +#include + +#include +#include + +#if USE_GLOBAL_CUB_WRAPPED_NAMESPACE() + +#include + +#else + +// include cub in a safe manner, see: +// https://github.com/pytorch/pytorch/pull/55292 +#undef CUB_NS_POSTFIX //undef to avoid redefinition warnings +#undef CUB_NS_PREFIX +#undef CUB_NS_QUALIFIER +#define CUB_NS_PREFIX namespace at_cuda_detail { +#define CUB_NS_POSTFIX } +#define CUB_NS_QUALIFIER ::at_cuda_detail::cub +#include +#undef CUB_NS_POSTFIX +#undef CUB_NS_PREFIX +#undef CUB_NS_QUALIFIER + +#endif + +#include +#include +#include + +// handle the temporary storage and 'twice' calls for cub API +#define CUB_WRAPPER(func, ...) do { \ + size_t temp_storage_bytes = 0; \ + func(nullptr, temp_storage_bytes, __VA_ARGS__); \ + auto& caching_allocator = *::c10::cuda::CUDACachingAllocator::get(); \ + auto temp_storage = caching_allocator.allocate(temp_storage_bytes); \ + func(temp_storage.get(), temp_storage_bytes, __VA_ARGS__); \ + AT_CUDA_CHECK(cudaGetLastError()); \ +} while (false) + +#ifdef USE_ROCM +#define NO_ROCM(x) +#define ROCM_HIPCUB(x) ::hipcub +#else +#define NO_ROCM(x) x +#define ROCM_HIPCUB(x) x +#endif + +#if (!defined(USE_ROCM) && !CUB_SUPPORTS_NV_BFLOAT16()) || defined(USE_ROCM) + +#if !defined(USE_ROCM) +namespace at_cuda_detail { +#endif + +// backport https://github.com/NVIDIA/cub/pull/306 for c10::BFloat16 + +template <> +struct ROCM_HIPCUB(cub)::FpLimits +{ + static __host__ __device__ __forceinline__ c10::BFloat16 Max() { + unsigned short max_word = 0x7F7F; + return reinterpret_cast(max_word); + } + + static __host__ __device__ __forceinline__ c10::BFloat16 Lowest() { + unsigned short lowest_word = 0xFF7F; + return reinterpret_cast(lowest_word); + } +}; + +template <> +struct ROCM_HIPCUB(cub)::NumericTraits: + ROCM_HIPCUB(cub)::BaseTraits {}; + +#if !defined(USE_ROCM) +} // namespace at_cuda_detail +#endif + +#endif + +#if !defined(USE_ROCM) +namespace at::native { +namespace cub = ::at_cuda_detail::cub; +} // namespace at::native +#endif + +namespace at::cuda::cub { + +namespace detail { + +template +struct cuda_type { + using type = T; +}; +template<> +struct cuda_type { + using type = __half; +}; + +#if !defined(USE_ROCM) && CUB_SUPPORTS_NV_BFLOAT16() + +template<> +struct cuda_type { + using type = __nv_bfloat16; +}; + +#elif defined(USE_ROCM) + +template<> +struct cuda_type { + using type = hip_bfloat16; +}; + +#endif + +} // namespace detail + +template +inline void segmented_sort_pairs( + const key_t *keys_in, key_t *keys_out, + const value_t *values_in, value_t *values_out, + int64_t num_elements, int64_t num_segments, + OffsetIteratorT begin_offsets, OffsetIteratorT end_offsets, + bool descending=false, int64_t begin_bit=0, int64_t end_bit=sizeof(key_t)*8 +) { + TORCH_CHECK(num_elements <= std::numeric_limits::max(), + "cub sort does not support sorting more than INT_MAX elements"); + TORCH_CHECK(num_segments <= std::numeric_limits::max(), + "cub sort does not support sorting more than INT_MAX elements"); + using key_t_ = typename detail::cuda_type::type; + + auto allocator = c10::cuda::CUDACachingAllocator::get(); + c10::DataPtr keys_out_owner; + + if (keys_out == nullptr) { + keys_out_owner = allocator->allocate(num_elements * sizeof(key_t)); + keys_out = reinterpret_cast(keys_out_owner.get()); + } + + const key_t_ *keys_in_ = reinterpret_cast(keys_in); + key_t_ *keys_out_ = reinterpret_cast(keys_out); + + if (descending) { + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceSegmentedRadixSort::SortPairsDescending, + keys_in_, keys_out_, values_in, values_out, + num_elements, num_segments, begin_offsets, end_offsets, + begin_bit, end_bit, c10::cuda::getCurrentCUDAStream()); + } else { + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceSegmentedRadixSort::SortPairs, + keys_in_, keys_out_, values_in, values_out, + num_elements, num_segments, begin_offsets, end_offsets, + begin_bit, end_bit, c10::cuda::getCurrentCUDAStream()); + } +} + +#if CUB_SUPPORTS_UNIQUE_BY_KEY() +template +inline void unique_by_key( + KeysInputIteratorT keys_in, ValuesInputIteratorT values_in, + ValuesOutputIteratorT values_out, + NumSelectedIteratorT num_selected, int64_t num_input_items) +{ + // TODO: use thrust::discard_iterator to handle null keys_out when https://github.com/NVIDIA/cub/issues/406 is fixed. + using KeyT = typename std::iterator_traits::value_type; + auto allocator = c10::cuda::CUDACachingAllocator::get(); + c10::DataPtr keys_out_owner; + keys_out_owner = allocator->allocate(num_input_items * sizeof(KeyT)); + auto keys_out_ = static_cast(keys_out_owner.get()); + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceSelect::UniqueByKey, + keys_in, values_in, keys_out_, values_out, num_selected, num_input_items, c10::cuda::getCurrentCUDAStream()); +} +#endif + +namespace impl { + +template +C10_LAUNCH_BOUNDS_1(1) +__global__ void transform_vals(InputIteratorT1 a, InputIteratorT2 b, OutputIteratorT out, ScanOpT scan_op){ + // NOTE: out here not the final scan output, but an intermediate of the accumulation type. + using acc_t = typename std::iterator_traits::value_type; + *out = scan_op(static_cast(*a), static_cast(*b)); +} + +#if !CUB_SUPPORTS_FUTURE_VALUE() +template +struct chained_iterator { + using iterator_category = std::random_access_iterator_tag; + using difference_type = std::ptrdiff_t; + using value_type = ValueT; + using pointer = ValueT*; + using reference = ValueT&; + + InputIteratorT iter; + ValueT *first; + difference_type offset = 0; + + __device__ ValueT operator[](difference_type i) { + i += offset; + if (i == 0) { + return *first; + } else { + return ValueT(iter[i - 1]); + } + } + __device__ chained_iterator operator+(difference_type i) { + return chained_iterator{iter, first, i}; + } + __device__ ValueT operator*() { + return (*this)[0]; + } +}; +#endif + +// even though cub is supposed to support tensors with int_max elements, in reality it doesn't, +// so split at int_max/2 +constexpr int max_cub_size = std::numeric_limits::max() / 2 + 1; // 2**30 +} + +// non synchronizing cub call +// even though cub is supposed to support tensors with int_max elements, in reality it doesn't, +// so split at int_max/2 +template +inline void inclusive_scan(InputIteratorT input, OutputIteratorT output, ScanOpT scan_op, int64_t num_items) { +#if defined(USE_ROCM) + //For ROCm, use hipCUB chained iterators + CUB_WRAPPER(NO_ROCM(detail)::hipcub::DeviceScan::InclusiveScan, + input, + output, + scan_op, + num_items, + at::cuda::getCurrentCUDAStream()); + C10_HIP_KERNEL_LAUNCH_CHECK(); +#else + // non synchronizing cub call + // even though cub is supposed to support tensors with int_max elements, in reality it doesn't, + // so split at int_max/2 + int size_cub = std::min(num_items, max_cub_size); + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceScan::InclusiveScan, + input, + output, + scan_op, + size_cub, + at::cuda::getCurrentCUDAStream()); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + using input_t = typename std::iterator_traits::value_type; + for (int64_t i = max_cub_size; i < num_items; i += max_cub_size) { + auto allocator = c10::cuda::CUDACachingAllocator::get(); + c10::DataPtr first_elem = allocator->allocate(sizeof(input_t)); + auto first_elem_ptr = reinterpret_cast(first_elem.get()); + + size_cub = std::min(num_items - i, max_cub_size); + impl::transform_vals<<<1, 1, 0, at::cuda::getCurrentCUDAStream()>>>( + output + i - 1, + input + i, + first_elem_ptr, + scan_op); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +#if !CUB_SUPPORTS_FUTURE_VALUE() + using ArgIndexInputIterator = NO_ROCM(at_cuda_detail)::cub::ArgIndexInputIterator; + using tuple = typename ArgIndexInputIterator::value_type; + auto input_iter_transform = [=] __device__ (const tuple &x)->input_t { + if (x.key == 0) { + return *first_elem_ptr; + } else { + return x.value; + } + }; + auto input_ = NO_ROCM(at_cuda_detail)::cub::TransformInputIterator( + ArgIndexInputIterator(input + i), input_iter_transform); + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceScan::InclusiveScan, + input_, + output + i, + scan_op, + size_cub, + at::cuda::getCurrentCUDAStream()); +#else + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceScan::ExclusiveScan, + input + i + 1, + output + i, + scan_op, + ::at_cuda_detail::cub::FutureValue(first_elem_ptr), + size_cub, + at::cuda::getCurrentCUDAStream()); +#endif + } +#endif +} + +# if (defined(CUDA_VERSION) && CUDA_VERSION > 11040) || defined(USE_ROCM) + +template +struct BlockPrefixCallbackOp +{ + public: + T running_total; + + __host__ __device__ BlockPrefixCallbackOp(T running_total) : running_total(running_total) {} + + // Callback operator to be entered by the first warp of threads in the block. + // Thread-0 is responsible for returning a value for seeding the block-wide scan. + __host__ __device__ T operator()(T block_aggregate) + { + T old_prefix = running_total; + running_total += block_aggregate; + return old_prefix; + } +}; + +template +__global__ void final_scan_kernel(const T* d_in, T* d_out, T* agg, int64_t nelem, int iters_per_cta) { + int64_t offset = BLOCK_THREADS * ITEMS_PER_THREAD * iters_per_cta * (int64_t)blockIdx.x; + int64_t remaining = nelem - offset; + if (remaining <= 0) { + return; + } + + d_in += offset; + d_out += offset; + + using BlockLoadT = ROCM_HIPCUB(at_cuda_detail::cub)::BlockLoad; + + // Specialize BlockStore type for our thread block (uses warp-striped loads for coalescing, then transposes in shared + // memory to a blocked arrangement) + using BlockStoreT = ROCM_HIPCUB(at_cuda_detail::cub)::BlockStore; + + // Specialize BlockScan type for our thread block + using BlockScanT = ROCM_HIPCUB(at_cuda_detail::cub)::BlockScan; + using BlockReduceT = ROCM_HIPCUB(at_cuda_detail::cub)::BlockReduce; + + + // Shared memory + __shared__ union TempStorage + { + typename BlockLoadT::TempStorage load; + typename BlockStoreT::TempStorage store; + typename BlockScanT::TempStorage scan; + typename BlockReduceT::TempStorage reduce; + } temp_storage; + + // load agg and reduce my starting value + T agg_data; + agg_data = threadIdx.x >= blockIdx.x ? T(0) : agg[threadIdx.x]; + // if there are fewer threads than previous values to be read, + // read another value + if (threadIdx.x + blockDim.x < blockIdx.x) { + agg_data += agg[threadIdx.x + blockDim.x]; + } + T aggregate = BlockReduceT(temp_storage.reduce).Sum(agg_data); + __syncthreads(); + BlockPrefixCallbackOp prefix_op(aggregate); + + + // Per-thread tile data + T data[ITEMS_PER_THREAD]; + + for (int i=0; i= BLOCK_THREADS * ITEMS_PER_THREAD) { + BlockLoadT(temp_storage.load).Load(d_in, data); + } else { + #pragma unroll + for (int j=0; j= BLOCK_THREADS * ITEMS_PER_THREAD) { + BlockStoreT(temp_storage.store).Store(d_out, data); + } else { + BlockStoreT(temp_storage.store).Store(d_out, data, remaining); + } + d_in += BLOCK_THREADS * ITEMS_PER_THREAD; + d_out += BLOCK_THREADS * ITEMS_PER_THREAD; + remaining -= BLOCK_THREADS * ITEMS_PER_THREAD; + if (remaining <= 0) return; + __syncthreads(); + } + +} + +template +struct TransformFunctor { + __device__ aggT operator()(T value) const { + if constexpr (!nonzero) { + return value; + } else { + return (value != T(0)) ? 1 : 0; + } + } +}; + +template +__global__ void calc_block_sums(const T * d_in, aggT * agg, int64_t nelem, int iters_per_cta){ + int64_t offset = BLOCK_THREADS * ITEMS_PER_THREAD * iters_per_cta * (int64_t)blockIdx.x; + int64_t remaining = nelem - offset; + if (remaining <= 0) { + return; + } + d_in += offset; + + using BlockLoadT = ROCM_HIPCUB(at_cuda_detail::cub)::BlockLoad; + using BlockReduceT = ROCM_HIPCUB(at_cuda_detail::cub)::BlockReduce; + // Shared memory + __shared__ union TempStorage + { + typename BlockLoadT::TempStorage load; + typename BlockReduceT::TempStorage reduce; + } temp_storage; + aggT data[ITEMS_PER_THREAD]; + aggT agg_val = 0; + TransformFunctor transform_functor; + auto iter_in = ROCM_HIPCUB(at_cuda_detail::cub)::TransformInputIterator, const T*>(d_in, transform_functor); + for (int i=0; i= BLOCK_THREADS * ITEMS_PER_THREAD) { + BlockLoadT(temp_storage.load).Load(iter_in, data); + __syncthreads(); + agg_val += BlockReduceT(temp_storage.reduce).Sum(data); + + } else { + BlockLoadT(temp_storage.load).Load(iter_in, data, remaining, aggT(0)); + __syncthreads(); + agg_val += BlockReduceT(temp_storage.reduce).Sum(data); + } + iter_in += BLOCK_THREADS * ITEMS_PER_THREAD; + remaining -= BLOCK_THREADS * ITEMS_PER_THREAD; + if (remaining <= 0) { + // for nonzeros we need to write out last blocks + // accumulated value to be able to compute + // total number of nonzeros + if (nonzero && threadIdx.x == 0) { + agg[blockIdx.x] = agg_val; + } + return; + } + __syncthreads(); + + } + if (threadIdx.x == 0) { + agg[blockIdx.x] = agg_val; + } + +} + +template +struct NonZeroOp { + __host__ __device__ __forceinline__ int operator()(const T& a) const { + return (a != T(0)); + } +}; + +template +constexpr int block_threads(){ + if constexpr (size >=16) { + return 128; + } else if constexpr (size >=8) { + return 256; + } else { + return 512; + } +} + +template +inline void inclusive_deterministic_scan(const scalar_t * input, scalar_t * output, ScanOpT scan_op, int64_t num_items) { + static_assert(std::is_same_v>, ""); + constexpr int BLOCK_THREADS = block_threads(); + constexpr int ITEMS_PER_THREAD = 16; + auto grid_size = (num_items + BLOCK_THREADS * ITEMS_PER_THREAD - 1) / (BLOCK_THREADS * ITEMS_PER_THREAD); + const int64_t num_sms = at::cuda::getCurrentDeviceProperties()->multiProcessorCount; + + const int iters_per_cta = (grid_size + num_sms - 1)/num_sms; + grid_size = std::min(num_sms, grid_size); + // simple reduction in scan kernel handles at most 2 items per thread + TORCH_INTERNAL_ASSERT(2 * BLOCK_THREADS >= grid_size); + auto& allocator = *c10::cuda::CUDACachingAllocator::get(); + auto agg = allocator.allocate(grid_size * sizeof(scalar_t)); + calc_block_sums + <<>>( + input, (scalar_t*)agg.get(), num_items, iters_per_cta); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + final_scan_kernel + <<>>( + input, output, (scalar_t*)agg.get(), num_items, iters_per_cta); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +#endif + +template +inline void exclusive_scan(InputIteratorT input, OutputIteratorT output, ScanOpT scan_op, InitValueT init_value, int64_t num_items) { +#if defined(USE_ROCM) + //For ROCm, use hipCUB chained iterators + CUB_WRAPPER(NO_ROCM(detail)::hipcub::DeviceScan::ExclusiveScan, + input, + output, + scan_op, + init_value, + num_items, + at::cuda::getCurrentCUDAStream()); + C10_HIP_KERNEL_LAUNCH_CHECK(); +#else + // non synchronizing cub call + // even though cub is supposed to support tensors with int_max elements, in reality it doesn't, + // so split at int_max/2 + int size_cub = std::min(num_items, max_cub_size); + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceScan::ExclusiveScan, + input, + output, + scan_op, + init_value, + size_cub, + at::cuda::getCurrentCUDAStream()); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + for (int64_t i = max_cub_size; i < num_items; i += max_cub_size) { + auto allocator = c10::cuda::CUDACachingAllocator::get(); + c10::DataPtr first_elem = allocator->allocate(sizeof(InitValueT)); + auto first_elem_ptr = reinterpret_cast(first_elem.get()); + + size_cub = std::min(num_items - i, max_cub_size); + impl::transform_vals<<<1, 1, 0, at::cuda::getCurrentCUDAStream()>>>( + output + i - 1, + input + i - 1, + first_elem_ptr, + scan_op); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +#if !CUB_SUPPORTS_FUTURE_VALUE() + auto input_ = impl::chained_iterator{ + input + i, first_elem_ptr}; + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceScan::InclusiveScan, + input_, + output + i, + scan_op, + size_cub, + at::cuda::getCurrentCUDAStream()); +#else + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceScan::ExclusiveScan, + input + i, + output + i, + scan_op, + ::at_cuda_detail::cub::FutureValue(first_elem_ptr), + size_cub, + at::cuda::getCurrentCUDAStream()); +#endif + } +#endif +} + +#if CUB_SUPPORTS_SCAN_BY_KEY() + +template +inline void inclusive_sum_by_key(KeysInputIteratorT keys, ValuesInputIteratorT input, ValuesOutputIteratorT output, int64_t num_items) { + TORCH_CHECK(num_items <= std::numeric_limits::max(), + "cub InclusiveSumByKey does not support more than INT_MAX elements"); +#if !defined(USE_ROCM) + CUB_WRAPPER(at_cuda_detail::cub::DeviceScan::InclusiveSumByKey, + keys, input, output, num_items, at_cuda_detail::cub::Equality(), at::cuda::getCurrentCUDAStream()); +#else + CUB_WRAPPER(cub::DeviceScan::InclusiveSumByKey, + keys, input, output, num_items, hipcub::Equality(), at::cuda::getCurrentCUDAStream()); +#endif +} + +template +inline void inclusive_scan_by_key(KeysInputIteratorT keys, ValuesInputIteratorT input, ValuesOutputIteratorT output, ScanOpT scan_op, int64_t num_items) { + TORCH_CHECK(num_items <= std::numeric_limits::max(), + "cub InclusiveSumByKey does not support more than INT_MAX elements"); +#if !defined(USE_ROCM) + CUB_WRAPPER(at_cuda_detail::cub::DeviceScan::InclusiveScanByKey, + keys, input, output, scan_op, num_items, at_cuda_detail::cub::Equality(), at::cuda::getCurrentCUDAStream()); +#else + CUB_WRAPPER(cub::DeviceScan::InclusiveScanByKey, + keys, input, output, scan_op, num_items, hipcub::Equality(), at::cuda::getCurrentCUDAStream()); +#endif +} + +#endif + +template +void unique(InputIteratorT input, OutputIteratorT output, + NumSelectedIteratorT num_selected_out, int64_t num_items) { + TORCH_CHECK(num_items <= std::numeric_limits::max(), + "cub unique does not support more than INT_MAX elements"); + CUB_WRAPPER(NO_ROCM(at_cuda_detail)::cub::DeviceSelect::Unique, + input, output, num_selected_out, num_items, at::cuda::getCurrentCUDAStream()); +} + +template +void run_length_encode(InputIteratorT input, OutputIteratorT output, CountsOutputIteratorT counts_out, + LengthOutputIteratorT length_out, int64_t num_items) { + TORCH_CHECK(num_items <= std::numeric_limits::max(), + "cub run_length_encode does not support more than INT_MAX elements"); + CUB_WRAPPER( + NO_ROCM(at_cuda_detail)::cub::DeviceRunLengthEncode::Encode, + input, output, counts_out, length_out, num_items, + at::cuda::getCurrentCUDAStream()); +} + +template +void reduce(InputIteratorT input, OutputIteratorT output, int64_t num_items, ReductionOpT op, T init) { + TORCH_CHECK(num_items <= std::numeric_limits::max(), + "cub reduce does not support more than INT_MAX elements"); + CUB_WRAPPER( + NO_ROCM(at_cuda_detail)::cub::DeviceReduce::Reduce, + input, output, num_items, op, init, + at::cuda::getCurrentCUDAStream()); + +} + +} // namespace at::cuda::cub diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/cub.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/cub.h new file mode 100644 index 0000000000000000000000000000000000000000..b18f1438a7088ccea4ae5cc9e1ddb114d7941015 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/cub.h @@ -0,0 +1,87 @@ +#pragma once +#include +#include +#include + +// NOTE: These templates are intentionally not defined in this header, +// which aviods re-compiling them for each translation unit. If you get +// a link error, you need to add an explicit instantiation for your +// types in cub.cu + +namespace at::cuda::cub { + +inline int get_num_bits(uint64_t max_key) { + int num_bits = 1; + while (max_key > 1) { + max_key >>= 1; + num_bits++; + } + return num_bits; +} + +namespace detail { + +// radix_sort_pairs doesn't interact with value_t other than to copy +// the data, so we can save template instantiations by reinterpreting +// it as an opaque type. +template struct alignas(N) OpaqueType { char data[N]; }; + +template +void radix_sort_pairs_impl( + const key_t *keys_in, key_t *keys_out, + const OpaqueType *values_in, OpaqueType *values_out, + int64_t n, bool descending, int64_t begin_bit, int64_t end_bit); + +} // namespace detail + +template +void radix_sort_pairs( + const key_t *keys_in, key_t *keys_out, + const value_t *values_in, value_t *values_out, + int64_t n, bool descending=false, int64_t begin_bit=0, int64_t end_bit=sizeof(key_t)*8) { + static_assert(std::is_trivially_copyable_v || + AT_ROCM_ENABLED(), // ROCm incorrectly fails this check for vector types + "radix_sort_pairs value type must be trivially copyable"); + // Make value type opaque, so all inputs of a certain size use the same template instantiation + using opaque_t = detail::OpaqueType; + static_assert(sizeof(value_t) <= 8 && (sizeof(value_t) & (sizeof(value_t) - 1)) == 0, + "This size of value_t is not instantiated. Please instantiate it in cub.cu" + " and modify this check."); + static_assert(sizeof(value_t) == alignof(value_t), "Expected value_t to be size-aligned"); + detail::radix_sort_pairs_impl( + keys_in, keys_out, + reinterpret_cast(values_in), + reinterpret_cast(values_out), + n, descending, begin_bit, end_bit); +} + +template +void radix_sort_keys( + const key_t *keys_in, key_t *keys_out, + int64_t n, bool descending=false, int64_t begin_bit=0, int64_t end_bit=sizeof(key_t)*8); + +// NOTE: Intermediate sums will be truncated to input_t precision +template +void inclusive_sum_truncating(const input_t *input, output_t *output, int64_t n); + +template +void inclusive_sum(const scalar_t *input, scalar_t *output, int64_t n) { + return inclusive_sum_truncating(input, output, n); +} + +// NOTE: Sums are done is common_type +template +void exclusive_sum_in_common_type(const input_t *input, output_t *output, int64_t n); + +template +void exclusive_sum(const scalar_t *input, scalar_t *output, int64_t n) { + return exclusive_sum_in_common_type(input, output, n); +} + +void mask_exclusive_sum(const uint8_t *mask, int64_t *output_idx, int64_t n); +inline void mask_exclusive_sum(const bool *mask, int64_t *output_idx, int64_t n) { + return mask_exclusive_sum( + reinterpret_cast(mask), output_idx, n); +} + +} // namespace at::cuda::cub diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/cub_definitions.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/cub_definitions.cuh new file mode 100644 index 0000000000000000000000000000000000000000..db7cc9120a099e36e9a63a4f424d9ef37b9b87fc --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/cub_definitions.cuh @@ -0,0 +1,53 @@ +#pragma once + +#if !defined(USE_ROCM) +#include // for CUDA_VERSION +#endif + +#if !defined(USE_ROCM) +#include +#else +#define CUB_VERSION 200001 +#endif + +// cub sort support for __nv_bfloat16 is added to cub 1.13 in: +// https://github.com/NVIDIA/cub/pull/306 +#if CUB_VERSION >= 101300 +#define CUB_SUPPORTS_NV_BFLOAT16() true +#else +#define CUB_SUPPORTS_NV_BFLOAT16() false +#endif + +// cub support for CUB_WRAPPED_NAMESPACE is added to cub 1.13.1 in: +// https://github.com/NVIDIA/cub/pull/326 +// CUB_WRAPPED_NAMESPACE is defined globally in cmake/Dependencies.cmake +// starting from CUDA 11.5 +#if defined(CUB_WRAPPED_NAMESPACE) || defined(THRUST_CUB_WRAPPED_NAMESPACE) +#define USE_GLOBAL_CUB_WRAPPED_NAMESPACE() true +#else +#define USE_GLOBAL_CUB_WRAPPED_NAMESPACE() false +#endif + +// cub support for UniqueByKey is added to cub 1.16 in: +// https://github.com/NVIDIA/cub/pull/405 +#if CUB_VERSION >= 101600 +#define CUB_SUPPORTS_UNIQUE_BY_KEY() true +#else +#define CUB_SUPPORTS_UNIQUE_BY_KEY() false +#endif + +// cub support for scan by key is added to cub 1.15 +// in https://github.com/NVIDIA/cub/pull/376 +#if CUB_VERSION >= 101500 +#define CUB_SUPPORTS_SCAN_BY_KEY() 1 +#else +#define CUB_SUPPORTS_SCAN_BY_KEY() 0 +#endif + +// cub support for cub::FutureValue is added to cub 1.15 in: +// https://github.com/NVIDIA/cub/pull/305 +#if CUB_VERSION >= 101500 +#define CUB_SUPPORTS_FUTURE_VALUE() true +#else +#define CUB_SUPPORTS_FUTURE_VALUE() false +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/CUDAHooks.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/CUDAHooks.h new file mode 100644 index 0000000000000000000000000000000000000000..d0be9d5f535c11e626a6ba4a33c8de5051580591 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/CUDAHooks.h @@ -0,0 +1,65 @@ +#pragma once + +#include + +#include + +// TODO: No need to have this whole header, we can just put it all in +// the cpp file + +namespace at::cuda::detail { + +// Set the callback to initialize Magma, which is set by +// torch_cuda_cu. This indirection is required so magma_init is called +// in the same library where Magma will be used. +TORCH_CUDA_CPP_API void set_magma_init_fn(void (*magma_init_fn)()); + + +// The real implementation of CUDAHooksInterface +struct CUDAHooks : public at::CUDAHooksInterface { + CUDAHooks(at::CUDAHooksArgs) {} + void init() const override; + Device getDeviceFromPtr(void* data) const override; + bool isPinnedPtr(const void* data) const override; + const Generator& getDefaultGenerator( + DeviceIndex device_index = -1) const override; + Generator getNewGenerator( + DeviceIndex device_index = -1) const override; + bool hasCUDA() const override; + bool hasMAGMA() const override; + bool hasCuDNN() const override; + bool hasCuSOLVER() const override; + bool hasCuBLASLt() const override; + bool hasROCM() const override; + const at::cuda::NVRTC& nvrtc() const override; + DeviceIndex current_device() const override; + bool isBuilt() const override {return true;} + bool isAvailable() const override {return hasCUDA();} + bool hasPrimaryContext(DeviceIndex device_index) const override; + Allocator* getCUDADeviceAllocator() const override; + Allocator* getPinnedMemoryAllocator() const override; + bool compiledWithCuDNN() const override; + bool compiledWithMIOpen() const override; + bool supportsDilatedConvolutionWithCuDNN() const override; + bool supportsDepthwiseConvolutionWithCuDNN() const override; + bool supportsBFloat16ConvolutionWithCuDNNv8() const override; + bool hasCUDART() const override; + long versionCUDART() const override; + long versionCuDNN() const override; + std::string showConfig() const override; + double batchnormMinEpsilonCuDNN() const override; + int64_t cuFFTGetPlanCacheMaxSize(DeviceIndex device_index) const override; + void cuFFTSetPlanCacheMaxSize(DeviceIndex device_index, int64_t max_size) const override; + int64_t cuFFTGetPlanCacheSize(DeviceIndex device_index) const override; + void cuFFTClearPlanCache(DeviceIndex device_index) const override; + int getNumGPUs() const override; + DeviceIndex deviceCount() const override; + DeviceIndex getCurrentDevice() const override; + +#ifdef USE_ROCM + bool isGPUArch(DeviceIndex device_index, const std::vector& archs) const override; +#endif + void deviceSynchronize(DeviceIndex device_index) const override; +}; + +} // at::cuda::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/DeviceThreadHandles.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/DeviceThreadHandles.h new file mode 100644 index 0000000000000000000000000000000000000000..1f80c863b63944a25aacb3aa8b95d0b82b6c110b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/DeviceThreadHandles.h @@ -0,0 +1,151 @@ +// Some stateful GPU libraries, such as cuDNN, cuBLAS, use handles to store states. +// These handles are tied to device, and these libraries requires/recommends not to +// share handles across host threads. +// +// These libraries recommend using one handle per host thread. We may not want to do +// this because threads are relatively light-weight, but creating and destroying +// handles is expensive (destroying the handle causes synchronizations). DataParallel, +// for example, creates new threads for each forward pass. +// +// This file implements a handle pool mechanism. The handle pool returns handles on +// demand as threads request them. If all existing handles in the pool are in use, +// it creates a new one. As threads terminate, they release handles back into the pool. +// In this way, the handle pool never creates more handles than the high-water mark of +// active threads, so it's efficient with DataParallel. + +#pragma once + +#include +#include +#include +#include +#include + +#include + +namespace at::cuda { namespace { + +template +struct DeviceThreadHandlePool : public std::enable_shared_from_this> { + + struct Handle { + Handle_t handle; + Handle(bool create = false) : handle(nullptr) + { + if(create) Create(&handle); + } + // std::vector.emplace() and push_back() may route through temporaries and call + // copy/move constructors along the way. If this is the case, we don't want + // the destructors of temporaries to call cudnnDestroy on the handle. + // We can achieve safety (for the narrow case of stashing within std::vectors) + // by making Handle moveable but not copyable, and transferring handle ownership + // to the latest constructed object. This is not a substitute for full-blown + // reference counting, but reference counting may be overkill here. + // Another alternative is to wrap the saved Handles in unique_ptrs, i.e., + // unordered_map>> created_handles; + Handle(const Handle& rhs) = delete; + // Following https://stackoverflow.com/questions/3279543/what-is-the-copy-and-swap-idiom + Handle(Handle&& rhs) noexcept : Handle() { std::swap(handle, rhs.handle); } + // operator= takes argument by value + Handle& operator=(Handle rhs) { std::swap(handle, rhs.handle); return *this; } + ~Handle() { + if(handle) Destroy(handle); + } + }; + + std::mutex mutex; + + // Handles are lazily created as different threads request them, + // but are never destroyed until the end of the process. + // The maximum number of handles this process will create for each device is equal + // to the high-water mark of the number of concurrently active threads that request + // handles for that device. + // When threads terminate, they release their handles back into the pool for reuse. + // Otherwise, new handles would be created every time new threads were spawned, + // resulting in poor performance for Python modules that repeatedly or frequently + // spawned new sets of threads (like DataParallel, which creates a new set of threads + // for each forward pass). + // + // To prevent potential deadlocks, we explicitly choose not to cap the number + // of handles that are created per device. + // Example of danger: If we cap the max handles at 4, and 5 threads are sharing a device, + // only 4 can make forward progress at any time. The other 4 will not release their + // handles until they exit, so the fifth cannot make progress until then. This is + // not a problem...UNLESS all 5 threads attempt some sort of synchronization at an + // intermediate point (ie, before any of them have exited). We have no way to anticipate + // or enforce that user threads will not attempt such intermediate synchronization. + // The only way to ensure safety is to avoid imposing a cap on the number of handles. + std::unordered_map> created_handles; + std::unordered_map> available_handles; + + // PoolWindow lazily creates and caches the handles that a particular thread is using, + // so in the common case handle access doesn't incur either handle creation or a mutex lock. + class PoolWindow + { + public: + PoolWindow(std::shared_ptr parent): weak_parent(std::move(parent)) {} + ~PoolWindow(){ release(); } + + Handle_t reserve(int device) + { + // If this thread already has a handle for this device, return it + if(my_handles.find(device) != my_handles.end()) + return my_handles[device]; + + // otherwise, either grab a handle from the pool if one is available, + // or if not, create a new one. + auto parent = weak_parent.lock(); + TORCH_CHECK(parent, "Cannot create handle during program termination"); + std::lock_guard guard(parent->mutex); + + if(parent->available_handles[device].size() > 0) + { + my_handles[device] = parent->available_handles[device].back(); + parent->available_handles[device].pop_back(); + } + else + { + // In local testing, I do observe that emplace_back sometimes routes through temporaries + // that incur move-constructor and destructor calls. See comments in Handle above. + parent->created_handles[device].emplace_back(true /*create*/); + my_handles[device] = parent->created_handles[device].back().handle; + } + + return my_handles[device]; + } + + private: + // Stores the per-device handles currently owned by this thread + std::unordered_map my_handles; + + std::weak_ptr weak_parent; + + // Called by the destructor. Releases this thread's handles back into the pool. + void release() { + if(my_handles.size() > 0) { + auto parent = weak_parent.lock(); + if (!parent) { + // If this thread exits after atexit handlers have completed, the + // cuda context itself may be invalid, so we must leak the handles. + return; + } + + std::lock_guard guard(parent->mutex); + for(auto d_h : my_handles) + parent->available_handles[d_h.first].push_back(d_h.second); + } + } + }; + + // Warning: + // If you want to change this function, be aware that this function will be called + // by multiple threads and there is no mutex guarding the call of this function, so + // make sure your implementation is thread-safe. + PoolWindow *newPoolWindow() { + // The returned pointer will be owned by a thread local variable + // so that different threads does not share the same PoolWindow. + return new PoolWindow(this->shared_from_this()); + } +}; + +}} // namespace at::cuda::detail:: diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/IndexUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/IndexUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..367ab10d3d3bb1de30412afc047fc25154247701 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/IndexUtils.cuh @@ -0,0 +1,36 @@ +#pragma once + +#include +#include +#include + +namespace at::cuda::detail { + +TORCH_CUDA_CU_API bool maybeOverlappingIndices(const at::TensorBase &t); +using at::native::canUse32BitIndexMath; + +template +TensorInfo +getTensorInfo(const at::TensorBase &t) { + IndexType sz[MAX_TENSORINFO_DIMS]; + IndexType st[MAX_TENSORINFO_DIMS]; + + int dims = t.dim(); + for (int i = 0; i < dims; ++i) { + sz[i] = t.size(i); + st[i] = t.stride(i); + } + + scalar* data_ptr = nullptr; + + if constexpr (std::is_const_v) { + data_ptr = t.const_data_ptr(); + } else { + data_ptr = t.mutable_data_ptr(); + } + + return TensorInfo( + data_ptr, dims, sz, st); +} + +} // namespace at::cuda::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/IntegerDivider.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/IntegerDivider.cuh new file mode 100644 index 0000000000000000000000000000000000000000..e8a26b5e06a6ffeeeaf5df26f09175a2c903aa01 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/IntegerDivider.cuh @@ -0,0 +1,124 @@ +#pragma once + +#include +#if defined(__CUDA_ARCH__) || defined(__HIP_DEVICE_COMPILE__) +#include +#endif + +namespace at::cuda::detail { + +// A utility class to implement integer division by multiplication, given a fixed +// divisor. +// +// WARNING: The fast divider algorithm is only implemented for unsigned int; +// otherwise we default to plain integer division. For unsigned int, +// we further assume that the dividend is at most INT32_MAX. Thus, +// IntDivider must NOT be used for general integer division. +// +// This reduced range is enough for our purpose, and it allows us to +// slightly simplify the computation. +// +// (NOTE: Below, "2^k" denotes exponentiation, i.e., 1< 0), we can find a "magic number" m (2^N +// <= m < 2^(N+1)) and shift s such that: +// +// \floor(n / d) = \floor((m * n) / 2^(N+s)). +// +// Given such m and s, the integer division can be then implemented as: +// +// let m' = m - 2^N // 0 <= m' < 2^N +// +// fast_integer_division(n): +// // Multiply two N-bit unsigned integers: the result is a 2N-bit unsigned +// // integer. Then take the higher N bits. +// t = (m' * n) >> N +// +// // Here we use the fact that n is less than 2^(N-1): otherwise the value +// // of (t + n) may not fit in an N-bit integer. +// return (t + n) >> s +// +// Finding such a magic number is surprisingly easy: +// +// s = \ceil(\log_2 d) +// m' = \floor(2^N * (2^s - d) / d) + 1 // Need 2N-bit integer arithmetic. +// +// See also: +// - Division by Invariant Integers Using Multiplication, +// Torbjörn Granlund and Peter L. Montgomery, 1994. +// +// - http://www.hackersdelight.org/magic.htm +// +// - http://ridiculousfish.com/blog/posts/labor-of-division-episode-i.html + +// Result of div/mod operation stored together. +template +struct DivMod { + Value div, mod; + + C10_HOST_DEVICE DivMod(Value div, Value mod) : div(div), mod(mod) { } +}; + +// Base case: we only have an implementation for uint32_t for now. For +// everything else, we use plain division. +template +struct IntDivider { + IntDivider() = default; + IntDivider(Value d) : divisor(d) { } + + C10_HOST_DEVICE inline Value div(Value n) const { return n / divisor; } + C10_HOST_DEVICE inline Value mod(Value n) const { return n % divisor; } + C10_HOST_DEVICE inline DivMod divmod(Value n) const { + return DivMod(n / divisor, n % divisor); + } + + Value divisor; +}; + +// Implement fast integer division. +template <> +struct IntDivider { + static_assert(sizeof(unsigned int) == 4, "Assumes 32-bit unsigned int."); + + IntDivider() = default; + + IntDivider(unsigned int d) : divisor(d) { + assert(divisor >= 1 && divisor <= INT32_MAX); + + // TODO: gcc/clang has __builtin_clz() but it's not portable. + for (shift = 0; shift < 32; shift++) if ((1U << shift) >= divisor) break; + + uint64_t one = 1; + uint64_t magic = ((one << 32) * ((one << shift) - divisor)) / divisor + 1; + m1 = magic; + assert(m1 > 0 && m1 == magic); // m1 must fit in 32 bits. + } + + C10_HOST_DEVICE inline unsigned int div(unsigned int n) const { +#if defined(__CUDA_ARCH__) || defined(__HIP_DEVICE_COMPILE__) + // 't' is the higher 32-bits of unsigned 32-bit multiplication of 'n' and + // 'm1'. + unsigned int t = __umulhi(n, m1); + return (t + n) >> shift; +#else + // Using uint64_t so that the addition does not overflow. + uint64_t t = ((uint64_t) n * m1) >> 32; + return (t + n) >> shift; +#endif + } + + C10_HOST_DEVICE inline unsigned int mod(unsigned int n) const { + return n - div(n) * divisor; + } + + C10_HOST_DEVICE inline DivMod divmod(unsigned int n) const { + unsigned int q = div(n); + return DivMod(q, n - q * divisor); + } + + unsigned int divisor; // d above. + unsigned int m1; // Magic number: m' above. + unsigned int shift; // Shift amounts. +}; + +} // namespace at::cuda::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/KernelUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/KernelUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..b20001569da7275b001ba631bbdd7e1b0ffac163 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/KernelUtils.h @@ -0,0 +1,37 @@ +#pragma once + +#include +#include + +namespace at::cuda::detail { + +// CUDA: grid stride looping +// +// int64_t _i_n_d_e_x specifically prevents overflow in the loop increment. +// If input.numel() < INT_MAX, _i_n_d_e_x < INT_MAX, except after the final +// iteration of the loop where _i_n_d_e_x += blockDim.x * gridDim.x can be +// greater than INT_MAX. But in that case _i_n_d_e_x >= n, so there are no +// further iterations and the overflowed value in i=_i_n_d_e_x is not used. +#define CUDA_KERNEL_LOOP_TYPE(i, n, index_type) \ + int64_t _i_n_d_e_x = ((int64_t) blockIdx.x) * blockDim.x + threadIdx.x; \ + for (index_type i=_i_n_d_e_x; _i_n_d_e_x < (n); _i_n_d_e_x+=blockDim.x * gridDim.x, i=_i_n_d_e_x) + +#define CUDA_KERNEL_LOOP(i, n) CUDA_KERNEL_LOOP_TYPE(i, n, int) + + +// Use 1024 threads per block, which requires cuda sm_2x or above +constexpr int CUDA_NUM_THREADS = 1024; + +// CUDA: number of blocks for threads. +inline int GET_BLOCKS(const int64_t N, const int64_t max_threads_per_block=CUDA_NUM_THREADS) { + TORCH_INTERNAL_ASSERT(N > 0, "CUDA kernel launch blocks must be positive, but got N=", N); + constexpr int64_t max_int = std::numeric_limits::max(); + + // Round up division for positive number that cannot cause integer overflow + auto block_num = (N - 1) / max_threads_per_block + 1; + TORCH_INTERNAL_ASSERT(block_num <= max_int, "Can't schedule too many blocks on CUDA device"); + + return static_cast(block_num); +} + +} // namespace at::cuda::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/LazyNVRTC.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/LazyNVRTC.h new file mode 100644 index 0000000000000000000000000000000000000000..95e52c94377bf568060c25f887454dbbaf2054b7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/LazyNVRTC.h @@ -0,0 +1,11 @@ +#pragma once +#include +namespace at::cuda { +// Forward-declares at::cuda::NVRTC +struct NVRTC; + +namespace detail { +extern NVRTC lazyNVRTC; +} // namespace detail + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/OffsetCalculator.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/OffsetCalculator.cuh new file mode 100644 index 0000000000000000000000000000000000000000..60e1a19c1aacfe43830295f75fa6d2496e3b7d52 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/OffsetCalculator.cuh @@ -0,0 +1,118 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + +// If element_sizes is nullptr, then the strides will be in bytes, otherwise +// the strides will be in # of elements. +// Operands that share the same shape, but may have different strides. +// OffsetCalculator iterates the tensor in a column-major order + +#if defined(USE_ROCM) +constexpr int MAX_DIMS = 16; +#else +constexpr int MAX_DIMS = 25; +#endif + +template +struct OffsetCalculator { + // We allow having negative strides to implement some operations like torch.flip + using stride_t = std::conditional_t, + index_t>; + // The offset for each argument. Wrapper around fixed-size array. + // On CUDA, zero sized array is not allowed, so when we are handling nullary + // operators, we need to create a size 1 offset to avoid compiler failure. + // This size 1 offset is just a placeholder, and we will not use it. + using offset_type = std::array(NARGS, 1)>; + + // if element_sizes is nullptr, then the strides will be in bytes, otherwise + // the strides will be in # of elements. + OffsetCalculator(int dims, const int64_t* sizes, const int64_t* const* strides, const int64_t* element_sizes=nullptr) : dims(dims) { + TORCH_CHECK(dims <= MAX_DIMS, "tensor has too many (>", MAX_DIMS, ") dims"); + for (int i=0; i < dims; i++){ + sizes_[i] = at::cuda::detail::IntDivider(sizes[i]); + for (int arg = 0; arg < NARGS; arg++) { + int64_t element_size = (element_sizes == nullptr ? 1LL : element_sizes[arg]); + strides_[i][arg] = strides[arg][i] / element_size; + } + } + } + + C10_HOST_DEVICE offset_type get(index_t linear_idx) const { + offset_type offsets; + #pragma unroll + for (int arg = 0; arg < NARGS; arg++) { + offsets[arg] = 0; + } + + #pragma unroll + for (int dim = 0; dim < MAX_DIMS; ++dim) { + if (dim == dims) { + break; + } + auto divmod = sizes_[dim].divmod(linear_idx); + linear_idx = divmod.div; + + #pragma unroll + for (int arg = 0; arg < NARGS; arg++) { + offsets[arg] += divmod.mod * strides_[dim][arg]; + } + + } + return offsets; + } + + int dims; + at::cuda::detail::IntDivider sizes_[MAX_DIMS]; + stride_t strides_[MAX_DIMS][std::max(NARGS, 1)]; +}; + +template +struct TrivialOffsetCalculator { + // The offset for each argument. Wrapper around fixed-size array. + // The offsets are in # of elements, not in bytes. + // On CUDA, zero sized array is not allowed, so when we are handling nullary + // operators, we need to create a size 1 offset to avoid compiler failure. + // This size 1 offset is just a placeholder, and we will not use it. + using offset_type = std::array(NARGS, 1)>; + + C10_HOST_DEVICE offset_type get(index_t linear_idx) const { + offset_type offsets; + #pragma unroll + for (int arg = 0; arg < NARGS; arg++) { + offsets[arg] = linear_idx; + } + return offsets; + } +}; + +// Make an OffsetCalculator with byte offsets +template +static OffsetCalculator make_offset_calculator(const at::TensorIteratorBase& iter) { + TORCH_INTERNAL_ASSERT(N <= iter.ntensors()); + std::array strides; + for (int i = 0; i < N; i++) { + strides[i] = iter.strides(i).data(); + } + return OffsetCalculator(iter.ndim(), iter.shape().data(), strides.data()); +} + +// Make an OffsetCalculator with element offsets +template +static OffsetCalculator make_element_offset_calculator( + const at::TensorIteratorBase& iter) { + TORCH_INTERNAL_ASSERT(N <= iter.ntensors()); + std::array strides; + std::array element_sizes; + for (int i = 0; i < N; i++) { + strides[i] = iter.strides(i).data(); + element_sizes[i] = iter.element_size(i); + } + return OffsetCalculator( + iter.ndim(), iter.shape().data(), strides.data(), element_sizes.data()); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/PhiloxCudaStateRaw.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/PhiloxCudaStateRaw.cuh new file mode 100644 index 0000000000000000000000000000000000000000..231cd167cacb4f9b4f2f48e159431b30f3d6dc28 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/PhiloxCudaStateRaw.cuh @@ -0,0 +1,43 @@ +// No "#pragma once" because this is a raw definition that can be copied by jit codegen. +// Eager mode clients should not include this file directly, instead, +// they should #include , which has a #pragma once. + +// Stores RNG state values. Passed as a kernel argument. +// See Note [CUDA Graph-safe RNG states]. +// +// The raw definition lives in its own file so jit codegen can easily copy it. +namespace at { + +struct PhiloxCudaState { + PhiloxCudaState() = default; + // Called if graph capture is not underway + PhiloxCudaState(uint64_t seed, + uint64_t offset) { + seed_.val = seed; + offset_.val = offset; + } + // Called if graph capture is underway + PhiloxCudaState(int64_t* seed, + int64_t* offset_extragraph, + uint32_t offset_intragraph) { + seed_.ptr = seed; + offset_.ptr = offset_extragraph; + offset_intragraph_ = offset_intragraph; + captured_ = true; + } + + // Public members, directly accessible by at::cuda::philox::unpack. + // If we made them private with getters/setters, the getters/setters + // would have to be __device__, and we can't declare __device__ in ATen. + union Payload { + uint64_t val; + int64_t* ptr; + }; + + Payload seed_{}; + Payload offset_{}; + uint32_t offset_intragraph_ = 0; + bool captured_ = false; +}; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/TensorInfo.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/TensorInfo.cuh new file mode 100644 index 0000000000000000000000000000000000000000..a320000ae881faa7416bae6ed1f37793f357a73a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/TensorInfo.cuh @@ -0,0 +1,116 @@ +#pragma once + +#include + +namespace at::cuda::detail { + +#define MAX_TENSORINFO_DIMS 25 + +// CUDA kernel argument that defines tensor layout +template +struct TensorInfo { + TensorInfo(); + TensorInfo(T* p, + int dim, + IndexType sz[MAX_TENSORINFO_DIMS], + IndexType st[MAX_TENSORINFO_DIMS]); + + // Set the size of the given dimension to 1, as if it were a + // reduction dim (allows you to calculate offsets of the reduction + // slice) + void reduceDim(int dim); + + // See note on [collapse dims]. + int collapseDims(const int excludeDim = -1); + + // Contiguous tensors of more than one dimension are collapsed down + // to one tensor + __host__ __device__ inline bool isContiguous() const { + return (dims == 1 && strides[0] == 1); + } + + T* data; + IndexType sizes[MAX_TENSORINFO_DIMS]; + IndexType strides[MAX_TENSORINFO_DIMS]; + int dims; +}; + +template +TensorInfo::TensorInfo() { + data = nullptr; + dims = 0; +} + +template +TensorInfo::TensorInfo(T* p, + int dim, + IndexType sz[MAX_TENSORINFO_DIMS], + IndexType st[MAX_TENSORINFO_DIMS]) { + data = p; + dims = dim; + TORCH_CHECK(dims < MAX_TENSORINFO_DIMS, "CUDA Tensors cannot have more than 25 dimensions"); + + for (int i = 0; i < dim; ++i) { + sizes[i] = sz[i]; + strides[i] = st[i]; + } +} + +template +void +TensorInfo::reduceDim(int dim) { + TORCH_CHECK(dim < dims && dim >= 0, "expected dim between 0 and dims - 1"); + sizes[dim] = 1; +} + +template +int +TensorInfo::collapseDims(const int excludeDim) { + auto result = at::collapse_dims(sizes, strides, dims, excludeDim); + dims = std::get<1>(result); + return std::get<0>(result); +} + +// Translate a linear index for the apply to a T* offset; +// specialized on `Dims` to reduce nvcc compilation time +template +struct IndexToOffset { + static __host__ __device__ IndexType get( + IndexType linearId, + const TensorInfo& info) { + + IndexType offset = 0; + + // Uses static dims + for (int i = Dims - 1; i > 0; --i) { + IndexType curDimIndex = linearId % info.sizes[i]; + IndexType curDimOffset = curDimIndex * info.strides[i]; + offset += curDimOffset; + linearId /= info.sizes[i]; + } + + return offset + linearId * info.strides[0]; + } +}; + +// Uses dynamic (runtime) instead of static (compiletime) dims +template +struct IndexToOffset { + static inline __host__ __device__ IndexType get( + IndexType linearId, + const TensorInfo& info) { + + IndexType offset = 0; + + for (int i = info.dims - 1; i > 0; --i) { + IndexType curDimIndex = linearId % info.sizes[i]; + IndexType curDimOffset = curDimIndex * info.strides[i]; + offset += curDimOffset; + linearId /= info.sizes[i]; + } + + return offset + linearId * info.strides[0]; + } +}; + +} // namespace at::cuda::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/UnpackRaw.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/UnpackRaw.cuh new file mode 100644 index 0000000000000000000000000000000000000000..3a458c756daf96173dec9d26e7078d49ea975f72 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/detail/UnpackRaw.cuh @@ -0,0 +1,34 @@ +// No "#pragma once" because this is a raw definition that can be copied by jit codegen. +// Eager mode clients should not include this file directly, instead, +// they should #include , which has a #pragma once. + +namespace at::cuda::philox { + +// In-kernel call to retrieve philox seed and offset from a PhiloxCudaState instance whether +// that instance was created with graph capture underway or not. +// See Note [CUDA Graph-safe RNG states]. +// +// We can't write a __device__ function in CUDAGeneratorImpl.h, because it's in ATen. +// Also, whatever call unpacks PhiloxCudaState in consumer kernels must be inlineable. +// Easiest thing that comes to mind is, define a __device__ unpack helper here, in ATen/cuda. +// +// The raw definition lives in its own file so jit codegen can easily copy it. +__host__ __device__ __forceinline__ std::tuple +unpack(at::PhiloxCudaState arg) { + if (arg.captured_) { + // static_cast avoids "warning: invalid narrowing conversion from "long" to "unsigned long". + // *(arg.offset_.ptr) is a broadcast load of a single int64_t to the entire kernel. + // For most threads' reads it will hit in cache, so it shouldn't hurt performance. + return std::make_tuple(static_cast(*arg.seed_.ptr), static_cast(*(arg.offset_.ptr) + arg.offset_intragraph_)); + } else { + return std::make_tuple(arg.seed_.val, arg.offset_.val); + } +} + +// Adapted from TE +// extract seed and offset from PhiloxCudaState +__global__ void unpack_cudnn(at::PhiloxCudaState arg, int64_t* seed_ptr, int64_t* offset_ptr); + +void unpack_cudnn_wrapper(at::PhiloxCudaState arg, int64_t* seed_ptr, int64_t* offset_ptr, cudaStream_t stream); + +} // namespace at::cuda::philox diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/jiterator.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/jiterator.h new file mode 100644 index 0000000000000000000000000000000000000000..a7a440cd7b614732d5ad16eb28c56e71bb20b6e1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/jiterator.h @@ -0,0 +1,40 @@ +#pragma once +#include + +#if AT_USE_JITERATOR() + +#include +#include +#include + +#include +#include + +namespace at::cuda { + +TORCH_CUDA_CPP_API c10::SmallVector CompileAndLaunchKernel( + const std::string& code_string, + const std::string& kernel_name, + const int num_outputs, + const c10::SmallVector& tensors, + const c10::SmallVector& extra_args, + bool return_by_ref); + +} // namespace at::cuda + +#else + +namespace at::cuda { + +TORCH_CUDA_CPP_API c10::SmallVector CompileAndLaunchKernel( + const std::string& code_string, + const std::string& kernel_name, + const int num_outputs, + const c10::SmallVector& tensors, + const c10::SmallVector& extra_args, + bool return_by_ref) { + TORCH_CHECK(false, "Jiterator is not supported"); + } +} // namespace at::cuda + +#endif // AT_USE_JITERATOR() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/jiterator_impl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/jiterator_impl.h new file mode 100644 index 0000000000000000000000000000000000000000..334403b39f7a57373021eff71481d7067a56dfd5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/jiterator_impl.h @@ -0,0 +1,250 @@ +#pragma once +#include + +#if AT_USE_JITERATOR() + +#include +#include +#include +#include +#include + +#include +#include +#include +#include + +namespace at::native { + + +#define AT_FOR_8_CASES(_) \ + _(1) \ + _(2) \ + _(3) \ + _(4) \ + _(5) \ + _(6) \ + _(7) \ + _(8) + +#define AT_FOR_8_CASES_WITH_COMMA(_) \ + _(1) , \ + _(2) , \ + _(3) , \ + _(4) , \ + _(5) , \ + _(6) , \ + _(7) , \ + _(8) + +c10::SmallVector get_extra_args_typenames(const c10::SmallVector& extra_args) { + c10::SmallVector args_typenames(extra_args.size()); + for (const auto i : c10::irange(extra_args.size())) { + args_typenames[i] = at::cuda::jit::typeName(extra_args[i].type()); + } + return args_typenames; +} + +int can_vectorize_up_to(at::ScalarType type, char* pointer) { + switch(type) { +#define DEFINE_CASE(ctype, scalartype) \ + case ScalarType::scalartype : return memory::can_vectorize_up_to(pointer); + + AT_FORALL_SCALAR_TYPES_WITH_COMPLEX(DEFINE_CASE) +#undef DEFINE_CASE + + default: TORCH_INTERNAL_ASSERT(false, "Unrecognized ScalarType: ", type); + } +} + +// jitted version of the above +// See Note [Jiterator], this relies on the assumptions enumerated there +int jitted_can_vectorize_up_to(const TensorIteratorBase& iter) { + const at::ScalarType common_dtype = iter.common_dtype(); + const at::ScalarType result_dtype = common_dtype; + + // Deals with output + int result = can_vectorize_up_to(result_dtype, static_cast(iter.data_ptr(0))); + + // Incorporates input(s) + for (auto i = 1; i < iter.ntensors(); ++i) { + result = std::min(result, can_vectorize_up_to(common_dtype, static_cast(iter.data_ptr(i)))); + } + + return result; +} + +template +static std::unique_ptr> make_unique_offset_calculator( + const TensorIteratorBase& iter) { + // array size can not be 0, this happens when N == 0 + constexpr int array_size = std::max(N, 1); + TORCH_INTERNAL_ASSERT(N == (IS_INPUT ? iter.ninputs() : iter.noutputs())); + + std::array strides; + int64_t element_sizes[array_size]; + for (int i = 0; i < N; i++) { + int index = IS_INPUT ? i + iter.noutputs() : i; + strides[i] = iter.strides(index).data(); + element_sizes[i] = iter.element_size(index); + } + return std::make_unique>(iter.ndim(), iter.shape().data(), strides.data(), element_sizes); +} + +template +struct OffsetCalculatorVariant { +#define DEFINE_CASE(index) std::unique_ptr> + using OffsetCalculatorTypes = std::variant< + AT_FOR_8_CASES_WITH_COMMA(DEFINE_CASE) + >; +#undef DEFINE_CASE + + OffsetCalculatorVariant(const TensorIteratorBase& iter) { + int num = IS_INPUT ? iter.ninputs() : iter.noutputs(); + + switch(num) { +#define DEFINE_CASE(index) \ + case index : v = make_unique_offset_calculator(iter); break; + + AT_FOR_8_CASES(DEFINE_CASE) +#undef DEFINE_CASE + default: + TORCH_CHECK(false, "OffsetCalculatorVariant is not implemented for num_tensor = ", num); + } + } + + void* data_ptr() { + return std::visit([](auto & v){ return static_cast(v.get()); }, v); + } + + private: + OffsetCalculatorTypes v{}; +}; + +struct ArrayVariant { +// works for up to 8 input + 8 outputs +#define DEFINE_CASE(index) std::array, std::array + using ArrayTypes = std::variant< + AT_FOR_8_CASES_WITH_COMMA(DEFINE_CASE) + >; +#undef DEFINE_CASE + + ArrayVariant(const TensorIteratorBase& iter) { + int ntensors = iter.ntensors(); + switch(ntensors) { +#define DEFINE_CASE(index) \ + case index: array = std::array{}; break; \ + case index+8: array = std::array{}; break; + + AT_FOR_8_CASES(DEFINE_CASE) +#undef DEFINE_CASE + + default: + TORCH_CHECK(false, "ArrayVariant is not implemented for ntensors = ", ntensors); + } + + std::visit([&](auto& a) { + for (auto i = 0; i < ntensors; ++i) { + a[i] = (char*)iter.data_ptr(i); + } + }, array); + } + + void* data_ptr() { + return std::visit([](auto & a){ return static_cast(&a); }, array); + } + +private: + ArrayTypes array; +}; + +struct TrivialOffsetCalculatorVariant { +#define DEFINE_CASE(index) TrivialOffsetCalculator + using TrivialOffsetCalculatorTypes = std::variant< + AT_FOR_8_CASES_WITH_COMMA(DEFINE_CASE) + >; +#undef DEFINE_CASE + + TrivialOffsetCalculatorVariant(int num) { + switch(num) { +#define DEFINE_CASE(index) \ + case index: v = TrivialOffsetCalculator(); break; + + AT_FOR_8_CASES(DEFINE_CASE) +#undef DEFINE_CASE + + default: + TORCH_CHECK(false, "TrivialOffsetCalculatorVariant is not implemented for num_tensors = ", num); + } + } + + void* data_ptr() { + return std::visit([](auto & v){ return static_cast(&v); }, v); + } + +private: + TrivialOffsetCalculatorTypes v{}; +}; + +struct LoadWithCastVariant { +#define DEFINE_CASE(index) std::unique_ptr> + using LoadWithCastPtr = std::variant< + AT_FOR_8_CASES_WITH_COMMA(DEFINE_CASE) + >; +#undef DEFINE_CASE + + LoadWithCastVariant(const TensorIteratorBase& iter) { + int arity = iter.ninputs(); + switch(arity) { +#define DEFINE_CASE(index) \ + case index: v = std::make_unique>(iter); break; + + AT_FOR_8_CASES(DEFINE_CASE) +#undef DEFINE_CASE + + default: + TORCH_CHECK(false, "LoadWithCastVariant is not implemented for ninputs = ", arity); + } + } + + void* data_ptr() { + return std::visit([](auto & v){ return static_cast(v.get()); }, v); + } + +private: + LoadWithCastPtr v{}; +}; + +struct StoreWithCastVariant { +#define DEFINE_CASE(index) std::unique_ptr> + using StoreWithCastPtr = std::variant< + AT_FOR_8_CASES_WITH_COMMA(DEFINE_CASE) + >; +#undef DEFINE_CASE + + StoreWithCastVariant(const TensorIteratorBase& iter) { + int num = iter.noutputs(); + switch(num) { +#define DEFINE_CASE(index) \ + case index: v = std::make_unique>(iter); break; + + AT_FOR_8_CASES(DEFINE_CASE) +#undef DEFINE_CASE + + default: + TORCH_CHECK(false, "StoreWithCastVariant is not implemented for noutputs = ", num); + } + } + + void* data_ptr() { + return std::visit([](auto & v){ return static_cast(v.get()); }, v); + } + +private: + StoreWithCastPtr v{}; +}; + +} // namespace at::native + + +#endif // AT_USE_JITERATOR() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/llvm_jit_strings.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/llvm_jit_strings.h new file mode 100644 index 0000000000000000000000000000000000000000..aba40d4f42eac74ee9435d904ac3fb82d1e988c4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/llvm_jit_strings.h @@ -0,0 +1,14 @@ +#pragma once + +#include +#include + +namespace at::cuda { + +TORCH_CUDA_CPP_API const std::string &get_traits_string(); +TORCH_CUDA_CPP_API const std::string &get_cmath_string(); +TORCH_CUDA_CPP_API const std::string &get_complex_body_string(); +TORCH_CUDA_CPP_API const std::string &get_complex_half_body_string(); +TORCH_CUDA_CPP_API const std::string &get_complex_math_string(); + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/GemmCommon.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/GemmCommon.h new file mode 100644 index 0000000000000000000000000000000000000000..c8817bdb05c81ee9ef0703007bb8de020776c4f9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/GemmCommon.h @@ -0,0 +1,685 @@ +// Original TunableOp is from onnxruntime. +// https://github.com/microsoft/onnxruntime/blob/main/onnxruntime/core/framework/tunable.h +// https://github.com/microsoft/onnxruntime/tree/main/onnxruntime/core/providers/rocm/tunable +// Copyright (c) Microsoft Corporation. +// Licensed under the MIT license. +// +// Adapting TunableOp into PyTorch +// Copyright (c) Advanced Micro Devices, Inc. +// +#pragma once + +#include +#include + +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#include +#else +#include +#include +#endif +#include +#include + +namespace at::cuda::tunable { + +enum class BlasOp { + N = 0, + T = 1 +}; + +inline char BlasOpToString(BlasOp op) { + switch (op) { + case BlasOp::N: + return 'N'; + case BlasOp::T: + return 'T'; + } + TORCH_CHECK(false, "unrecognized BlasOp"); + return 'N'; +} + +template +inline const char* BLASTypeName(T v) { + return "unknown"; +} + +template <> +inline const char* BLASTypeName(float v) { + return "f32_r"; +} + +template <> +inline const char* BLASTypeName(double v) { + return "f64_r"; +} + +template <> +inline const char* BLASTypeName(BFloat16 v) { + return "bf16_r"; +} + +template <> +inline const char* BLASTypeName(Half v) { + return "f16_r"; +} + +//https://github.com/ROCm/hipBLASLt/blob/develop/library/src/include/auxiliary.hpp#L175 +template <> +inline const char* BLASTypeName(Float8_e4m3fn v) { + return "f8_r"; +} + +template <> +inline const char* BLASTypeName(Float8_e5m2 v) { + return "bf8_r"; +} + +template <> +inline const char* BLASTypeName(Float8_e4m3fnuz v) { + return "f8_fnuz_r"; +} + +template <> +inline const char* BLASTypeName(Float8_e5m2fnuz v) { + return "bf8_fnuz_r"; +} + +template <> +inline const char* BLASTypeName(c10::complex v) { + return "f64_r"; +} + +template <> +inline const char* BLASTypeName(c10::complex v) { + return "f32_r"; +} + +inline std::string ScalarTypeToBLASType(c10::ScalarType scalar_type) { + std::string BLASType; + switch (scalar_type) { + case c10::ScalarType::Float:{ + BLASType = "f32_r"; + break; + } + case c10::ScalarType::Double:{ + BLASType = "f64_r"; + break; + } + case c10::ScalarType::BFloat16:{ + BLASType = "bf16_r"; + break; + } + case c10::ScalarType::Half: { + BLASType = "f16_r"; + break; + } + case c10::ScalarType::Float8_e4m3fn: { + BLASType = "f8_r"; + break; + } + case c10::ScalarType::Float8_e5m2: { + BLASType = "bf8_r"; + break; + } + case c10::ScalarType::Float8_e4m3fnuz: { + BLASType = "f8_fnuz_r"; + break; + } + case c10::ScalarType::Float8_e5m2fnuz: { + BLASType = "bf8_fnuz_r"; + break; + } + case c10::ScalarType::ComplexFloat:{ + BLASType = "f32_c"; + break; + } + case c10::ScalarType::ComplexDouble:{ + BLASType = "f64_c"; + break; + } + default: + BLASType = "unknown"; + } + return BLASType; +} + +// Similar to Compute Type in GemmRocblas.h +template +inline std::string ComputeTypeFor() { + return "Unknown ComputeType"; +} + +// This is a union of the compute types for +// ROCBLAS and hipBLASLt. +template <> +inline std::string ComputeTypeFor() { + if (!at::globalContext().allowTF32CuBLAS()) { + return "f32_r"; + } else { + return "xf32_r"; + } +} + +template <> +inline std::string ComputeTypeFor() { + return "f64_r"; +} + +template <> +inline std::string ComputeTypeFor() { + return "f32_r"; +} + +template <> +inline std::string ComputeTypeFor() { + return "f32_r"; +} + +template <> +inline std::string ComputeTypeFor>() { + return "f32_c"; +} + +template <> +inline std::string ComputeTypeFor>() { + return "f64_c"; +} + +template <> +inline std::string ComputeTypeFor() { + return "f32_r"; +} + +template <> +inline std::string ComputeTypeFor() { + return "f32_r"; +} + +template <> +inline std::string ComputeTypeFor() { + return "f32_r"; +} + +template <> +inline std::string ComputeTypeFor() { + return "f32_r"; +} + +// Convert opmath_type to string +template +inline std::string to_string_opmath(const at::opmath_type& value) { + if constexpr (std::is_same_v, c10::complex> || + std::is_same_v, c10::complex>) { + return fmt::format("({:.4f}, {:.4f})", value.real(), value.imag()); + } else { + return fmt::format("{:.4f}", value); + } +} + +// convert activation epilogue to string +inline std::string to_string_epilogue(const at::cuda::blas::GEMMAndBiasActivationEpilogue& value) { + switch (value) { + case at::cuda::blas::GEMMAndBiasActivationEpilogue::None: + return std::string("None"); + break; + case at::cuda::blas::GEMMAndBiasActivationEpilogue::RELU: + return std::string("RELU"); + break; + case cuda::blas::GEMMAndBiasActivationEpilogue::GELU: + return std::string("GELU"); + break; + default: + return std::string("unknown"); + } +} + +namespace detail { + +static bool NumericalCheck(ScalarType dtype, void* c, void* other_c, int64_t size) { + auto options = at::TensorOptions().dtype(dtype).device(at::kCUDA); + // comparison done as 1D tensor + at::Tensor ref = at::from_blob(c, {size}, options); + at::Tensor oth = at::from_blob(other_c, {size}, options); + at::Tensor ref_float = ref.to(at::kFloat); + at::Tensor oth_float = oth.to(at::kFloat); + std::vector atols{1e-1, 1e-2, 1e-3, 1e-4, 1e-5}; + std::vector rtols{1e-1, 1e-2, 1e-3, 1e-4, 1e-5}; + double last_succeed_atol = 1; + double last_succeed_rtol = 1; + for (auto& atol : atols) { + for (auto& rtol : rtols) { + if (at::allclose(ref_float, oth_float, rtol, atol)) { + last_succeed_atol = atol; + last_succeed_rtol = rtol; + } + } + } + if (last_succeed_atol == 1) { + return false; + } + else { + TUNABLE_LOG3("├──verify numerics: atol=", last_succeed_atol, ", rtol=", last_succeed_rtol); + } + + return true; +} + +} + +// Note on GetSizeA et al. +// Tensors can be dense or arbitrarily strided. We only need our copies to be large enough. +// Our copies must be at least as large as the m n k shapes dictate, but could be larger +// depending on the lda ldb ldc values. Similarly for the batched case. + +template +struct GemmParams : OpParams { + GemmParams() = default; + + std::string BLASSignature() const override { + std::string alpha_str = to_string_opmath(alpha); + std::string beta_str = to_string_opmath(beta); + return fmt::sprintf("- { function: matmul, M: %ld, N: %ld, K: %ld, lda: %ld, ldb: %ld, ldc: %ld, ldd: %ld, stride_a: 0, stride_b: 0, stride_c: 0, stride_d: 0, " + "alpha: %s, beta: %s, transA: %c, transB: %c, batch_count: 1, a_type: %s, b_type: %s, c_type: %s, d_type: %s, scale_type: %s, bias_type: %s, compute_type: %s }", + m, n, k, lda, ldb, ldc, ldc, alpha_str, beta_str, transa, transb, + BLASTypeName(T{}), BLASTypeName(T{}), BLASTypeName(T{}), BLASTypeName(T{}), ComputeTypeFor(), ComputeTypeFor(), ComputeTypeFor()); + } + + std::string Signature() const override { + return fmt::sprintf("%c%c_%ld_%ld_%ld_ld_%ld_%ld_%ld", transa, transb, m, n, k, lda, ldb, ldc); + } + + size_t GetSizeA() const { + size_t size_stride = lda * ((transa == 'n' || transa == 'N') ? k : m); + size_t size_dense = m * k; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSizeB() const { + size_t size_stride = ldb * ((transb == 'n' || transb == 'N') ? n : k); + size_t size_dense = k * n; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSizeC() const { + size_t size_stride = ldc * n; + size_t size_dense = m * n; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSize(bool duplicate_inputs) const { + size_t size = GetSizeC(); + if (duplicate_inputs) { + size += GetSizeA(); + size += GetSizeB(); + } + return size; + } + + GemmParams* DeepCopy(bool duplicate_inputs) const { + GemmParams* copy = new GemmParams; + *copy = *this; + c10::DeviceIndex device = 0; + AT_CUDA_CHECK(c10::cuda::GetDevice(&device)); + size_t c_size = GetSizeC(); + copy->c = static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(c_size)); + AT_CUDA_CHECK(c10::cuda::CUDACachingAllocator::memcpyAsync( + copy->c, device, c, device, c_size, getCurrentCUDAStream(device), true)); + if (duplicate_inputs) { + size_t a_size = GetSizeA(); + size_t b_size = GetSizeB(); + copy->a = static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(a_size)); + copy->b = static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(b_size)); + copy->duplicate_inputs_ = true; + } + return copy; + } + + // only call on object returned by DeepCopy + void Delete() { + c10::cuda::CUDACachingAllocator::raw_delete(c); + if (duplicate_inputs_) { + // NOLINTNEXTLINE(*const-cast*) + c10::cuda::CUDACachingAllocator::raw_delete(const_cast(a)); + // NOLINTNEXTLINE(*const-cast*) + c10::cuda::CUDACachingAllocator::raw_delete(const_cast(b)); + } + } + + TuningStatus NumericalCheck(GemmParams *other) { + auto c_dtype = c10::CppTypeToScalarType::value; + return detail::NumericalCheck(c_dtype, c, other->c, GetSizeC()/sizeof(T)) ? OK : FAIL; + } + + char transa{}; + char transb{}; + int64_t m{}; + int64_t n{}; + int64_t k{}; + at::opmath_type alpha; + const T* a{}; + int64_t lda{}; + const T* b{}; + int64_t ldb{}; + at::opmath_type beta; + T* c{}; + int64_t ldc{}; +private: + bool duplicate_inputs_{false}; +}; + +template +struct GemmAndBiasParams : OpParams { + std::string BLASSignature() const override { + std::string alpha_str = to_string_opmath(alpha); + std::string activation_str = to_string_epilogue(activation); + return fmt::sprintf("- { function: matmul, M: %ld, N: %ld, K: %ld, lda: %ld, ldb: %ld, ldc: %ld, ldd: %ld, stride_a: 0, stride_b: 0, stride_c: 0, stride_d: 0, " + "alpha: %s, transA: %c, transB: %c, batch_count: 1, a_type: %s, b_type: %s, c_type: %s, d_type: %s, activation: %s, bias_type: %s, scale_type: %s, compute_type: %s }", + m, n, k, lda, ldb, ldc, ldc, alpha_str, transa, transb, + BLASTypeName(T{}), BLASTypeName(T{}), BLASTypeName(T{}), BLASTypeName(T{}), activation_str, BLASTypeName(T{}), ComputeTypeFor(), ComputeTypeFor(), ComputeTypeFor()); + } + + std::string Signature() const override { + return fmt::sprintf("%c%c_%ld_%ld_%ld_ld_%ld_%ld_%ld", transa, transb, m, n, k, lda, ldb, ldc); + } + + size_t GetSizeA() const { + size_t size_stride = lda * ((transa == 'n' || transa == 'N') ? k : m); + size_t size_dense = m * k; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSizeB() const { + size_t size_stride = ldb * ((transb == 'n' || transb == 'N') ? n : k); + size_t size_dense = k * n; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSizeC() const { + size_t size_stride = ldc * n; + size_t size_dense = m * n; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSize(bool duplicate_inputs) const { + size_t size = GetSizeC(); + if (duplicate_inputs) { + size += GetSizeA(); + size += GetSizeB(); + } + return size; + } + + GemmAndBiasParams* DeepCopy(bool duplicate_inputs) const { + GemmAndBiasParams* copy = new GemmAndBiasParams; + *copy = *this; + c10::DeviceIndex device = 0; + AT_CUDA_CHECK(c10::cuda::GetDevice(&device)); + size_t c_size = GetSizeC(); + copy->c = static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(c_size)); + AT_CUDA_CHECK(c10::cuda::CUDACachingAllocator::memcpyAsync( + copy->c, device, c, device, c_size, getCurrentCUDAStream(device), true)); + if (duplicate_inputs) { + size_t a_size = GetSizeA(); + size_t b_size = GetSizeB(); + copy->a = static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(a_size)); + copy->b = static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(b_size)); + copy->duplicate_inputs_ = true; + } + return copy; + } + + // only call on object returned by DeepCopy + void Delete() { + c10::cuda::CUDACachingAllocator::raw_delete(c); + if (duplicate_inputs_) { + // NOLINTNEXTLINE(*const-cast) + c10::cuda::CUDACachingAllocator::raw_delete(const_cast(a)); + // NOLINTNEXTLINE(*const-cast) + c10::cuda::CUDACachingAllocator::raw_delete(const_cast(b)); + } + } + + TuningStatus NumericalCheck(GemmAndBiasParams *other) { + auto c_dtype = c10::CppTypeToScalarType::value; + return detail::NumericalCheck(c_dtype, c, other->c, GetSizeC()/sizeof(T)) ? OK : FAIL; + } + + char transa{}; + char transb{}; + int64_t m{}; + int64_t n{}; + int64_t k{}; + at::opmath_type alpha{}; + const T* a{}; + int64_t lda{}; + const T* b{}; + int64_t ldb{}; + T* c{}; + int64_t ldc{}; + const T* bias{}; + at::cuda::blas::GEMMAndBiasActivationEpilogue activation{}; +private: + bool duplicate_inputs_{false}; +}; + +template +struct GemmStridedBatchedParams : OpParams { + std::string BLASSignature() const override { + std::string alpha_str = to_string_opmath(alpha); + std::string beta_str = to_string_opmath(beta); + return fmt::sprintf("- { function: matmul, M: %ld, N: %ld, K: %ld, lda: %ld, ldb: %ld, ldc: %ld, ldd: %ld, stride_a: %ld, stride_b: %ld, stride_c: %ld, stride_d: %ld, " + "alpha: %s, beta: %s, transA: %c, transB: %c, batch_count: %ld, a_type: %s, b_type: %s, c_type: %s, d_type: %s, scale_type: %s, compute_type: %s }", + m, n, k, lda, ldb, ldc, ldc, stride_a, stride_b, stride_c, stride_c, alpha_str, beta_str, transa, transb, batch, + BLASTypeName(T{}), BLASTypeName(T{}), BLASTypeName(T{}), BLASTypeName(T{}), ComputeTypeFor(), ComputeTypeFor()); + } + + std::string Signature() const override { + return fmt::sprintf("%c%c_%ld_%ld_%ld_B_%ld_ld_%ld_%ld_%ld", transa, transb, m, n, k, batch, lda, ldb, ldc); + } + + size_t GetSizeA() const { + size_t size_stride = stride_a * batch; + size_t size_dense = m * k * batch; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSizeB() const { + size_t size_stride = stride_b * batch; + size_t size_dense = k * n * batch; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSizeC() const { + size_t size_stride = stride_c * batch; + size_t size_dense = m * n * batch; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSize(bool duplicate_inputs) const { + size_t size = GetSizeC(); + if (duplicate_inputs) { + size += GetSizeA(); + size += GetSizeB(); + } + return size; + } + + GemmStridedBatchedParams* DeepCopy(bool duplicate_inputs) const { + GemmStridedBatchedParams* copy = new GemmStridedBatchedParams; + *copy = *this; + c10::DeviceIndex device = 0; + AT_CUDA_CHECK(c10::cuda::GetDevice(&device)); + size_t c_size = GetSizeC(); + copy->c = static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(c_size)); + AT_CUDA_CHECK(c10::cuda::CUDACachingAllocator::memcpyAsync( + copy->c, device, c, device, c_size, getCurrentCUDAStream(device), true)); + if (duplicate_inputs) { + size_t a_size = GetSizeA(); + size_t b_size = GetSizeB(); + // NOLINTNEXTLINE(*const-cast*) + copy->a = static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(a_size)); + // NOLINTNEXTLINE(*const-cast*) + copy->b = static_cast(c10::cuda::CUDACachingAllocator::raw_alloc(b_size)); + copy->duplicate_inputs_ = true; + } + return copy; + } + + // only call on object returned by DeepCopy + void Delete() { + c10::cuda::CUDACachingAllocator::raw_delete(c); + if (duplicate_inputs_) { + // NOLINTNEXTLINE(*const-cast*) + c10::cuda::CUDACachingAllocator::raw_delete(const_cast(a)); + // NOLINTNEXTLINE(*const-cast*) + c10::cuda::CUDACachingAllocator::raw_delete(const_cast(b)); + } + } + + TuningStatus NumericalCheck(GemmStridedBatchedParams *other) { + auto c_dtype = c10::CppTypeToScalarType::value; + return detail::NumericalCheck(c_dtype, c, other->c, GetSizeC()/sizeof(T)) ? OK : FAIL; + } + + char transa{}; + char transb{}; + int64_t m{}; + int64_t n{}; + int64_t k{}; + at::opmath_type alpha{}; + const T* a{}; + int64_t lda{}; + int64_t stride_a{}; + const T* b{}; + int64_t ldb{}; + int64_t stride_b{}; + at::opmath_type beta; + T* c{}; + int64_t ldc{}; + int64_t stride_c{}; + int64_t batch{}; +private: + bool duplicate_inputs_{false}; +}; + +template +struct ScaledGemmParams : OpParams { + ScaledGemmParams() = default; + + std::string BLASSignature() const override { + // Excluding use_fast_accum and use_rowise booleans for now + return fmt::sprintf("- { function: matmul, M: %ld, N: %ld, K: %ld, lda: %ld, ldb: %ld, ldc: %ld, ldd: %ld, stride_a: 0, stride_b: 0, stride_c: 0, stride_d: 0, " + "transA: %c, transB: %c, batch_count: 1, scaleA: f32_r, scaleB: f32_r, a_type: %s, b_type: %s, c_type: %s, d_type: %s, bias_type: %s, scale_type: %s, compute_type: %s }", + m, n, k, lda, ldb, ldc, ldc, transa, transb, + ScalarTypeToBLASType(a_dtype), ScalarTypeToBLASType(b_dtype), ScalarTypeToBLASType(c_dtype), ScalarTypeToBLASType(c_dtype), ScalarTypeToBLASType(bias_dtype), + ComputeTypeFor(), ComputeTypeFor()); + } + + std::string Signature() const override { + // In Blas.cpp, code defaults to a bias_dtype of Half even when there is no bias vector. + // Search for this line:: + // params.bias_dtype = bias ? bias->scalar_type() : isFloat8Type(out_dtype_) ? at::ScalarType::Half : out_dtype_; + // + // In TunableOp, we must distinguish in param signature these two cases: with and without a bias vector. + return fmt::sprintf("%c%c_%ld_%ld_%ld_ld_%ld_%ld_%ld_rw_%d_bias_%s", + transa, transb, m, n, k, lda, ldb, ldc, use_rowwise, + bias_ptr == nullptr ? "None" : at::toString(bias_dtype)); + } + + size_t GetSizeA() const { + size_t size_stride = lda * ((transa == 'n' || transa == 'N') ? k : m); + size_t size_dense = m * k; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSizeB() const { + size_t size_stride = ldb * ((transb == 'n' || transb == 'N') ? n : k); + size_t size_dense = k * n; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSizeC() const { + size_t size_stride = ldc * n; + size_t size_dense = m * n; + return sizeof(T) * (size_stride > size_dense ? size_stride : size_dense); + } + + size_t GetSize(bool duplicate_inputs) const { + size_t size = GetSizeC(); + if (duplicate_inputs) { + size += GetSizeA(); + size += GetSizeB(); + } + return size; + } + + ScaledGemmParams* DeepCopy(bool duplicate_inputs) const { + ScaledGemmParams* copy = new ScaledGemmParams; + *copy = *this; + c10::DeviceIndex device = 0; + AT_CUDA_CHECK(c10::cuda::GetDevice(&device)); + size_t c_size = GetSizeC(); + copy->c = c10::cuda::CUDACachingAllocator::raw_alloc(c_size); + AT_CUDA_CHECK(c10::cuda::CUDACachingAllocator::memcpyAsync( + copy->c, device, c, device, c_size, getCurrentCUDAStream(device), true)); + if (duplicate_inputs) { + size_t a_size = GetSizeA(); + size_t b_size = GetSizeB(); + copy->a = c10::cuda::CUDACachingAllocator::raw_alloc(a_size); + copy->b = c10::cuda::CUDACachingAllocator::raw_alloc(b_size); + copy->duplicate_inputs_ = true; + } + return copy; + } + + // only call on object returned by DeepCopy + void Delete() { + c10::cuda::CUDACachingAllocator::raw_delete(c); + if (duplicate_inputs_) { + // NOLINTNEXTLINE(*const-cast*) + c10::cuda::CUDACachingAllocator::raw_delete(const_cast(a)); + // NOLINTNEXTLINE(*const-cast*) + c10::cuda::CUDACachingAllocator::raw_delete(const_cast(b)); + } + } + + TuningStatus NumericalCheck(ScaledGemmParams *other) { + return detail::NumericalCheck(c_dtype, c, other->c, GetSizeC()/sizeof(T)) ? OK : FAIL; + } + + char transa{}; + char transb{}; + int64_t m{}; + int64_t n{}; + int64_t k{}; + const void* a{}; + const void* a_scale_ptr{}; + int64_t lda{}; + ScalarType a_dtype{}; + ScalarType a_scale_dtype{}; + const void* b{}; + const void* b_scale_ptr{}; + int64_t ldb{}; + ScalarType b_dtype{}; + ScalarType b_scale_dtype{}; + const void* bias_ptr{}; + ScalarType bias_dtype{}; + void* c{}; + const void* c_scale_ptr{}; + int64_t ldc{}; + ScalarType c_dtype{}; + void* amax_ptr{}; + bool use_fast_accum{}; + bool use_rowwise{}; +private: + bool duplicate_inputs_{false}; +}; + +} // namespace at::cuda::tunable diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/GemmHipblaslt.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/GemmHipblaslt.h new file mode 100644 index 0000000000000000000000000000000000000000..bf66acb3c42cecb12a7ab338afbf321efae4f55a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/GemmHipblaslt.h @@ -0,0 +1,663 @@ +// Copyright (c) Microsoft Corporation. All rights reserved. +// Licensed under the MIT License. + +#pragma once + +#include +#include +#include +#include +#include +#include +#include + +#include +#include + +#define TORCH_HIPBLASLT_CHECK(EXPR) \ + do { \ + hipblasStatus_t __err = EXPR; \ + TORCH_CHECK(__err == HIPBLAS_STATUS_SUCCESS, \ + "hipblaslt error: ", \ + hipblasStatusToString(__err), \ + " when calling `" #EXPR "`"); \ + } while (0) + +namespace at::cuda::tunable { + +template +constexpr hipDataType HipDataTypeFor(); + +template <> +constexpr hipDataType HipDataTypeFor() { + return HIP_R_32F; +} + +template <> +constexpr hipDataType HipDataTypeFor() { + return HIP_R_16F; +} + +template <> +constexpr hipDataType HipDataTypeFor() { + return HIP_R_16BF; +} + +template <> +constexpr hipDataType HipDataTypeFor() { + return HIP_R_64F; +} + +template <> +constexpr hipDataType HipDataTypeFor() { + return HIP_R_8F_E4M3_FNUZ; +} + +template <> +constexpr hipDataType HipDataTypeFor() { + return HIP_R_8F_E5M2_FNUZ; +} + +// This code is instantiated regardless of ROCm version. +// Prior to ROCm 6.3, we hard-code the known enum values. +template <> +constexpr hipDataType HipDataTypeFor() { +#if ROCM_VERSION >= 60300 + return HIP_R_8F_E4M3; +#else + return static_cast(28); +#endif +} + +template <> +constexpr hipDataType HipDataTypeFor() { +#if ROCM_VERSION >= 60300 + return HIP_R_8F_E5M2; +#else + return static_cast(29); +#endif +} + +// This type is not intended for matrix types but rather a scale factor. +// Return a dummy value to satisfy linker. +template <> +constexpr hipDataType HipDataTypeFor() { + return static_cast(500); +} + +template +int GetBatchFromParams(const GemmParams* params) { + return 1; +} + +template +int GetBatchFromParams(const GemmAndBiasParams* params) { + return 1; +} + +template +int GetBatchFromParams(const GemmStridedBatchedParams* params) { + return params->batch; +} + +template +int GetBatchFromParams(const ScaledGemmParams* params) { + return 1; +} + +template +int GetStrideAFromParams(const GemmParams* params) { + return 1; +} + +template +int GetStrideAFromParams(const GemmAndBiasParams* params) { + return 1; +} + +template +int GetStrideAFromParams(const GemmStridedBatchedParams* params) { + return params->stride_a; +} + +template +int GetStrideAFromParams(const ScaledGemmParams* params) { + return 1; +} + +template +int GetStrideBFromParams(const GemmParams* params) { + return 1; +} + +template +int GetStrideBFromParams(const GemmAndBiasParams* params) { + return 1; +} + +template +int GetStrideBFromParams(const GemmStridedBatchedParams* params) { + return params->stride_b; +} + +template +int GetStrideBFromParams(const ScaledGemmParams* params) { + return 1; +} + +template +int GetStrideCFromParams(const GemmParams* params) { + return 1; +} + +template +int GetStrideCFromParams(const GemmAndBiasParams* params) { + return 1; +} + +template +int GetStrideCFromParams(const GemmStridedBatchedParams* params) { + return params->stride_c; +} + +template +int GetStrideCFromParams(const ScaledGemmParams* params) { + return 1; +} + +template +float GetAlphaFromParams(const GemmParams* params) { + return params->alpha; +} + +template +float GetAlphaFromParams(const GemmAndBiasParams* params) { + return params->alpha; +} + +template +float GetAlphaFromParams(const GemmStridedBatchedParams* params) { + return params->alpha; +} + +template +float GetAlphaFromParams(const ScaledGemmParams* params) { + return 1.0; +} + +template +float GetBetaFromParams(const GemmParams* params) { + return params->beta; +} + +template +float GetBetaFromParams(const GemmAndBiasParams* params) { + return 0.0; +} + +template +float GetBetaFromParams(const GemmStridedBatchedParams* params) { + return params->beta; +} + +template +float GetBetaFromParams(const ScaledGemmParams* params) { + return 0.0; +} + +template +bool GetUseRowwiseFromParams(const GemmParams* params) { + return false; +} + +template +bool GetUseRowwiseFromParams(const GemmAndBiasParams* params) { + return false; +} + +template +bool GetUseRowwiseFromParams(const GemmStridedBatchedParams* params) { + return false; +} + +template +bool GetUseRowwiseFromParams(const ScaledGemmParams* params) { + return params->use_rowwise; +} + +template +const void* GetAScalePointerFromParams(const GemmParams* params) { + return nullptr; +} + +template +const void* GetAScalePointerFromParams(const GemmAndBiasParams* params) { + return nullptr; +} + +template +const void* GetAScalePointerFromParams(const GemmStridedBatchedParams* params) { + return nullptr; +} + +template +const void* GetAScalePointerFromParams(const ScaledGemmParams* params) { + return params->a_scale_ptr; +} + +template +const void* GetBScalePointerFromParams(const GemmParams* params) { + return nullptr; +} + +template +const void* GetBScalePointerFromParams(const GemmAndBiasParams* params) { + return nullptr; +} + +template +const void* GetBScalePointerFromParams(const GemmStridedBatchedParams* params) { + return nullptr; +} + +template +const void* GetBScalePointerFromParams(const ScaledGemmParams* params) { + return params->b_scale_ptr; +} + +template +const void* GetDScalePointerFromParams(const GemmParams* params) { + return nullptr; +} + +template +const void* GetDScalePointerFromParams(const GemmAndBiasParams* params) { + return nullptr; +} + +template +const void* GetDScalePointerFromParams(const GemmStridedBatchedParams* params) { + return nullptr; +} + +template +const void* GetDScalePointerFromParams(const ScaledGemmParams* params) { + return params->c_scale_ptr; +} + +template +const void* GetBiasPointerFromParams(const GemmParams* params) { + return nullptr; +} + +template +const void* GetBiasPointerFromParams(const GemmAndBiasParams* params) { + return params->bias; +} + +template +const void* GetBiasPointerFromParams(const GemmStridedBatchedParams* params) { + return nullptr; +} + +template +const void* GetBiasPointerFromParams(const ScaledGemmParams* params) { + return params->bias_ptr; +} + +template +hipDataType GetBiasTypeFromParams(const GemmParams* params) { + return HIP_R_32F; +} + +template +hipDataType GetBiasTypeFromParams(const GemmAndBiasParams* params) { + return HipDataTypeFor(); +} + +template +hipDataType GetBiasTypeFromParams(const GemmStridedBatchedParams* params) { + return HIP_R_32F; +} + +template +hipDataType GetBiasTypeFromParams(const ScaledGemmParams* params) { + return at::cuda::ScalarTypeToCudaDataType(params->bias_dtype); +} + +template +at::cuda::blas::GEMMAndBiasActivationEpilogue GetActivationFromParams(const GemmParams* params) { + return at::cuda::blas::GEMMAndBiasActivationEpilogue::None; +} + +template +at::cuda::blas::GEMMAndBiasActivationEpilogue GetActivationFromParams(const GemmAndBiasParams* params) { + return params->activation; +} + +template +at::cuda::blas::GEMMAndBiasActivationEpilogue GetActivationFromParams(const GemmStridedBatchedParams* params) { + return at::cuda::blas::GEMMAndBiasActivationEpilogue::None; +} + +template +at::cuda::blas::GEMMAndBiasActivationEpilogue GetActivationFromParams(const ScaledGemmParams* params) { + return at::cuda::blas::GEMMAndBiasActivationEpilogue::None; +} + +static hipblasOperation_t _hipblasOpFromChar(char op) { + switch (op) { + case 'n': + case 'N': + return HIPBLAS_OP_N; + case 't': + case 'T': + return HIPBLAS_OP_T; + case 'c': + case 'C': + return HIPBLAS_OP_C; + } + TORCH_CHECK(false, + "_hipblasOpFromChar input should be 't', 'n' or 'c' but got `", op, "`"); +} + +static char _charFromhipblasOp(hipblasOperation_t op) { + switch (op) { + case HIPBLAS_OP_N: + return 'N'; + case HIPBLAS_OP_T: + return 'T'; + case HIPBLAS_OP_C: + return 'C'; + } + TORCH_CHECK(false, + "_charFromhipblasOp input should be HIPBLAS_OP_N/T/C but got `", op, "`"); +} + +static hipblasOperation_t MapLayoutToHipBlasLt(BlasOp layout) { + if (layout == BlasOp::N) { + return HIPBLAS_OP_N; + } + return HIPBLAS_OP_T; +} + +static size_t GetHipblasltWorkspaceSize() { + static const char * env = getenv("HIPBLASLT_WORKSPACE_SIZE"); + // 256MB is max workspace size allowed for hipblaslt + // hipblaslt-bench uses 32MB + // recommendation from hipblaslt author was 76MB + // TunableOp hipBLASLt workspace size is aligned with + // PyTorch's default in CUDABlas.cpp (_parseChosenWorkspaceSize) + size_t workspace_size = 76*1024; + if (env) { + try { + workspace_size = std::stoi(env); + } catch(std::invalid_argument const& e) { + TORCH_WARN("invalid HIPBLASLT_WORKSPACE_SIZE,", + " using default workspace size of ", workspace_size, " KiB."); + } catch(std::out_of_range const& e) { + TORCH_WARN("HIPBLASLT_WORKSPACE_SIZE out of range,", + " using default workspace size of ", workspace_size, " KiB."); + } + } + return workspace_size * 1024; +} + +template +struct HipBlasLtDeleter { + void operator()(T* x) { + if (x != nullptr) { + TORCH_CUDABLAS_CHECK(destructor(x)); + } + } +}; + +template +class HipBlasLtDescriptor { + public: + T* descriptor() const { + return descriptor_.get(); + } + T* descriptor() { + return descriptor_.get(); + } + + protected: + std::unique_ptr> descriptor_; +}; + +class HipBlasLtMatmulDescriptor : public HipBlasLtDescriptor< + hipblasLtMatmulDescOpaque_t, + &hipblasLtMatmulDescDestroy> { + public: + HipBlasLtMatmulDescriptor( + hipblasComputeType_t compute_type, + hipDataType scale_type) { + hipblasLtMatmulDesc_t raw_descriptor = nullptr; + TORCH_HIPBLASLT_CHECK( + hipblasLtMatmulDescCreate(&raw_descriptor, compute_type, scale_type)); + descriptor_.reset(raw_descriptor); + } + template + inline void setAttribute(hipblasLtMatmulDescAttributes_t attr, const T value) { + TORCH_HIPBLASLT_CHECK(::hipblasLtMatmulDescSetAttribute(descriptor(), attr, &value, sizeof(T))); + } +}; + +template +class HipblasltGemmOp : public Callable { + public: + HipblasltGemmOp(hipblasLtMatmulAlgo_t algo) : algo_{algo} {} + + TuningStatus Call(const ParamsT* params) override { + hipblasOperation_t transa_outer = MapLayoutToHipBlasLt(ALayout); + hipblasOperation_t transb_outer = MapLayoutToHipBlasLt(BLayout); + auto a_datatype = HipDataTypeFor(); + auto b_datatype = HipDataTypeFor(); + auto in_out_datatype = HipDataTypeFor(); + auto opa = _hipblasOpFromChar(params->transa); + auto opb = _hipblasOpFromChar(params->transb); + + TORCH_CHECK(transa_outer == opa && transb_outer == opb, "trans mismatch, shouldn't happen"); + + float alpha = GetAlphaFromParams(params); + float beta = GetBetaFromParams(params); + + hipblasLtMatrixLayout_t mat_a, mat_b, mat_c; + if (opa == HIPBLAS_OP_N) { + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutCreate(&mat_a, a_datatype, params->m, params->k, params->lda)); + } + else { + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutCreate(&mat_a, a_datatype, params->k, params->m, params->lda)); + } + if (opb == HIPBLAS_OP_N) { + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutCreate(&mat_b, b_datatype, params->k, params->n, params->ldb)); + } + else { + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutCreate(&mat_b, b_datatype, params->n, params->k, params->ldb)); + } + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutCreate(&mat_c, in_out_datatype, params->m, params->n, params->ldc)); + + // specific to batched gemmm + int batch = GetBatchFromParams(params); + if (batch > 1) { + int64_t stride_a = GetStrideAFromParams(params); + int64_t stride_b = GetStrideBFromParams(params); + int64_t stride_c = GetStrideCFromParams(params); + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutSetAttribute( + mat_a, HIPBLASLT_MATRIX_LAYOUT_BATCH_COUNT, &batch, sizeof(batch))); + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutSetAttribute( + mat_a, HIPBLASLT_MATRIX_LAYOUT_STRIDED_BATCH_OFFSET, &stride_a, sizeof(stride_a))); + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutSetAttribute( + mat_b, HIPBLASLT_MATRIX_LAYOUT_BATCH_COUNT, &batch, sizeof(batch))); + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutSetAttribute( + mat_b, HIPBLASLT_MATRIX_LAYOUT_STRIDED_BATCH_OFFSET, &stride_b, sizeof(stride_b))); + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutSetAttribute( + mat_c, HIPBLASLT_MATRIX_LAYOUT_BATCH_COUNT, &batch, sizeof(batch))); + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutSetAttribute( + mat_c, HIPBLASLT_MATRIX_LAYOUT_STRIDED_BATCH_OFFSET, &stride_c, sizeof(stride_c))); + } + + HipBlasLtMatmulDescriptor matmul(HIPBLAS_COMPUTE_32F, HIP_R_32F); + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_TRANSA, opa); + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_TRANSB, opb); + + // specific to scaled gemm + const void* mat1_scale_ptr = GetAScalePointerFromParams(params); + const void* mat2_scale_ptr = GetBScalePointerFromParams(params); + const void* result_scale_ptr = GetDScalePointerFromParams(params); + if (mat1_scale_ptr && mat2_scale_ptr) { +#ifdef HIPBLASLT_VEC_EXT + if (GetUseRowwiseFromParams(params)) { + // swapped + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_A_SCALE_POINTER_VEC_EXT, mat2_scale_ptr); + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_B_SCALE_POINTER_VEC_EXT, mat1_scale_ptr); + } + else +#endif + { + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_A_SCALE_POINTER, mat1_scale_ptr); + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_B_SCALE_POINTER, mat2_scale_ptr); + } + } + if (result_scale_ptr) { + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_D_SCALE_POINTER, result_scale_ptr); + } + + const void* bias_ptr = GetBiasPointerFromParams(params); + auto bias_datatype = GetBiasTypeFromParams(params); + if (bias_ptr) { + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_BIAS_POINTER, bias_ptr); + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_BIAS_DATA_TYPE, bias_datatype); + auto activation = GetActivationFromParams(params); + if (activation == at::cuda::blas::GEMMAndBiasActivationEpilogue::RELU) { + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_EPILOGUE, HIPBLASLT_EPILOGUE_RELU_BIAS); + } + else if (activation == at::cuda::blas::GEMMAndBiasActivationEpilogue::GELU) { + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_EPILOGUE, HIPBLASLT_EPILOGUE_GELU_BIAS); + } + else { + matmul.setAttribute(HIPBLASLT_MATMUL_DESC_EPILOGUE, HIPBLASLT_EPILOGUE_BIAS); + } + } + + size_t workspace_size = GetHipblasltWorkspaceSize(); + + auto op_handle = at::cuda::getCurrentCUDABlasLtHandle(); + + size_t ret_workspace_size = 0; + auto status = hipblaslt_ext::matmulIsAlgoSupported(op_handle, + matmul.descriptor(), + &alpha, + mat_a, + mat_b, + &beta, + mat_c, + mat_c, + algo_, + ret_workspace_size); + + if (status == HIPBLAS_STATUS_SUCCESS) { + if (ret_workspace_size >= workspace_size) { + return FAIL; + } + } + else { + return FAIL; + } + + void* workspace_buffer = nullptr; + if (workspace_size > 0) { + workspace_buffer = c10::cuda::CUDACachingAllocator::raw_alloc(workspace_size); + } + + TORCH_HIPBLASLT_CHECK(hipblasLtMatmul(op_handle, + matmul.descriptor(), + &alpha, + params->a, + mat_a, + params->b, + mat_b, + &beta, + params->c, + mat_c, + params->c, + mat_c, + &algo_, + workspace_buffer, + workspace_size, + at::cuda::getCurrentCUDAStream())); + + //TORCH_HIPBLASLT_CHECK(hipblasLtMatmulDescDestroy(matmul)); + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutDestroy(mat_a)); + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutDestroy(mat_b)); + TORCH_HIPBLASLT_CHECK(hipblasLtMatrixLayoutDestroy(mat_c)); + if (workspace_size > 0) { + c10::cuda::CUDACachingAllocator::raw_delete(workspace_buffer); + } + return OK; + } + + private: + hipblasLtMatmulAlgo_t algo_; +}; + +template +auto GetHipBlasLtTypeStringAndOps() { + hipblasOperation_t transa_outer = MapLayoutToHipBlasLt(ALayout); + hipblasOperation_t transb_outer = MapLayoutToHipBlasLt(BLayout); + auto a_datatype = HipDataTypeFor(); + auto b_datatype = HipDataTypeFor(); + auto in_out_datatype = HipDataTypeFor(); + std::vector heuristic_result; + + hipblasLtHandle_t handle; + TORCH_HIPBLASLT_CHECK(hipblasLtCreate(&handle)); + TORCH_HIPBLASLT_CHECK(hipblaslt_ext::getAllAlgos(handle, + hipblaslt_ext::GemmType::HIPBLASLT_GEMM, + transa_outer, + transb_outer, + a_datatype, + b_datatype, + in_out_datatype, + in_out_datatype, + HIPBLAS_COMPUTE_32F, + heuristic_result)); + TORCH_HIPBLASLT_CHECK(hipblasLtDestroy(handle)); + + int returned_algo_count = heuristic_result.size(); + std::vector>>> ret; + for (int i = 0; i < returned_algo_count; i++) { + auto algo = heuristic_result[i].algo; + int algo_index = hipblaslt_ext::getIndexFromAlgo(algo); + auto callable = std::make_unique>(algo); + std::string type_string = fmt::sprintf("Gemm_Hipblaslt_%d", algo_index); + ret.emplace_back(type_string, std::move(callable)); + } + + return ret; +} + +template +auto GetHipBlasLtGemmTypeStringAndOps() { + return GetHipBlasLtTypeStringAndOps>(); +} + +template +auto GetHipBlasLtGemmAndBiasTypeStringAndOps() { + return GetHipBlasLtTypeStringAndOps>(); +} + +template +auto GetHipBlasLtGemmStridedBatchedTypeStringAndOps() { + return GetHipBlasLtTypeStringAndOps>(); +} + +template +auto GetHipBlasLtScaledGemmTypeStringAndOps() { + return GetHipBlasLtTypeStringAndOps>(); +} + +#undef TORCH_HIPBLASLT_CHECK + +} // namespace at::cuda::tunable diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/GemmRocblas.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/GemmRocblas.h new file mode 100644 index 0000000000000000000000000000000000000000..182d597fe29c557741899889cbdb4de027fbed45 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/GemmRocblas.h @@ -0,0 +1,273 @@ +// Copyright (c) Microsoft Corporation. All rights reserved. +// Licensed under the MIT License. + +#pragma once + +#include +#include +#include +#include +#include + +#define ROCBLAS_BETA_FEATURES_API +#include + +#define TORCH_ROCBLAS_CHECK(EXPR) \ + do { \ + rocblas_status __err = EXPR; \ + TORCH_CHECK(__err == rocblas_status_success, \ + "rocblas error: ", \ + rocblas_status_to_string(__err), \ + " when calling `" #EXPR "`"); \ + } while (0) + +namespace at::cuda::tunable { + +template +constexpr rocblas_datatype RocBlasDataTypeFor(); + +template <> +constexpr rocblas_datatype RocBlasDataTypeFor() { + return rocblas_datatype_f32_r; +} + +template <> +constexpr rocblas_datatype RocBlasDataTypeFor() { + return rocblas_datatype_f64_r; +} + +template <> +constexpr rocblas_datatype RocBlasDataTypeFor() { + return rocblas_datatype_f16_r; +} + +template <> +constexpr rocblas_datatype RocBlasDataTypeFor() { + return rocblas_datatype_bf16_r; +} + +template <> +constexpr rocblas_datatype RocBlasDataTypeFor>() { + return rocblas_datatype_f32_c; +} + +template <> +constexpr rocblas_datatype RocBlasDataTypeFor>() { + return rocblas_datatype_f64_c; +} + +template +constexpr rocblas_datatype RocBlasComputeTypeFor(); + +template <> +constexpr rocblas_datatype RocBlasComputeTypeFor() { + return rocblas_datatype_f32_r; +} + +template <> +constexpr rocblas_datatype RocBlasComputeTypeFor() { + return rocblas_datatype_f64_r; +} + +template <> +constexpr rocblas_datatype RocBlasComputeTypeFor() { + // Note that we're returning the _compute_ type for a given datatype. + // As of 12/2022, using compute type FP16 for 16-bit floats was much + // slower than using compute type FP32. So we use FP32 compute even for + // FP16 datatypes. This is how GEMM is implemented even in the function + // rocblasGemmHelper (see fpgeneric.h) + return rocblas_datatype_f32_r; +} + +template <> +constexpr rocblas_datatype RocBlasComputeTypeFor() { + // Note that we're returning the _compute_ type for a given datatype. + // As of 12/2022, using compute type FP16 for 16-bit floats was much + // slower than using compute type FP32. So we use FP32 compute even for + // BF16 datatypes. This is how GEMM is implemented even in the function + // rocblasGemmHelper (see fpgeneric.h) + return rocblas_datatype_f32_r; +} + +template <> +constexpr rocblas_datatype RocBlasComputeTypeFor>() { + return rocblas_datatype_f32_c; +} + +template <> +constexpr rocblas_datatype RocBlasComputeTypeFor>() { + return rocblas_datatype_f64_c; +} + +template +auto DoCastForHalfOrBfloat16(const T fp) { + return fp; +} + +template <> +inline auto DoCastForHalfOrBfloat16(const Half fp) { + // alpha and beta should be the same as compute_type, in Half case it is float. + float h = fp; + return h; +} + +template <> +inline auto DoCastForHalfOrBfloat16(const BFloat16 fp) { + // alpha and beta should be the same as compute_type, in bfloat16 case it is float. + float h = fp; + return h; +} + +static rocblas_operation _rocblasOpFromChar(char op) { + switch (op) { + case 'n': + case 'N': + return rocblas_operation_none; + case 't': + case 'T': + return rocblas_operation_transpose; + case 'c': + case 'C': + return rocblas_operation_conjugate_transpose; + } + TORCH_CHECK(false, + "_rocblasOpFromChar input should be 't', 'n' or 'c' but got `", op, "`"); +} + +template +class RocblasGemmOp : public Callable> { + public: + RocblasGemmOp(int solution) : solution_{solution} {} + + TuningStatus Call(const GemmParams* params) override { + auto input_output_type = RocBlasDataTypeFor(); + auto compute_type = RocBlasComputeTypeFor(); + auto h_a = DoCastForHalfOrBfloat16(params->alpha); + auto h_b = DoCastForHalfOrBfloat16(params->beta); + auto status = rocblas_gemm_ex( + (rocblas_handle)at::cuda::getCurrentCUDABlasHandle(), + _rocblasOpFromChar(params->transa), + _rocblasOpFromChar(params->transb), + params->m, params->n, params->k, + &h_a, + params->a, input_output_type, params->lda, + params->b, input_output_type, params->ldb, + &h_b, + params->c, input_output_type, params->ldc, + params->c, input_output_type, params->ldc, + compute_type, + rocblas_gemm_algo_solution_index, + solution_, + rocblas_gemm_flags_none); + if (status != rocblas_status_success) { + return FAIL; + } + return OK; + } + + private: + int solution_; +}; + +template +auto GetRocBlasGemmTypeStringAndOps() { + rocblas_handle handle = (rocblas_handle)at::cuda::getCurrentCUDABlasHandle(); + int solution_size; + auto input_output_type = RocBlasDataTypeFor(); + auto compute_type = RocBlasComputeTypeFor(); + // Get the number of available solutions + TORCH_ROCBLAS_CHECK(rocblas_gemm_ex_get_solutions_by_type(handle, + input_output_type, + input_output_type, + compute_type, + rocblas_gemm_flags_none, + nullptr, + &solution_size)); + std::vector solutions(solution_size); + // Get the list of available solutions + TORCH_ROCBLAS_CHECK(rocblas_gemm_ex_get_solutions_by_type(handle, + input_output_type, + input_output_type, + compute_type, + rocblas_gemm_flags_none, + solutions.data(), + &solution_size)); + std::vector>>>> ret; + for (size_t i = 0; i < solutions.size(); ++i) { + auto callable = std::make_unique>(solutions[i]); + ret.emplace_back(std::make_pair(fmt::sprintf("Gemm_Rocblas_%d", solutions[i]), std::move(callable))); + } + return ret; +} + +template +class RocblasGemmStridedBatchedOp : public Callable> { + public: + RocblasGemmStridedBatchedOp(int solution) : solution_{solution} {} + + TuningStatus Call(const GemmStridedBatchedParams* params) override { + auto input_output_type = RocBlasDataTypeFor(); + auto compute_type = RocBlasComputeTypeFor(); + auto h_a = DoCastForHalfOrBfloat16(params->alpha); + auto h_b = DoCastForHalfOrBfloat16(params->beta); + auto status = rocblas_gemm_strided_batched_ex( + (rocblas_handle)at::cuda::getCurrentCUDABlasHandle(), + _rocblasOpFromChar(params->transa), + _rocblasOpFromChar(params->transb), + params->m, params->n, params->k, + &h_a, + params->a, input_output_type, params->lda, params->stride_a, + params->b, input_output_type, params->ldb, params->stride_b, + &h_b, + params->c, input_output_type, params->ldc, params->stride_c, + params->c, input_output_type, params->ldc, params->stride_c, + params->batch, + compute_type, + rocblas_gemm_algo_solution_index, + solution_, + rocblas_gemm_flags_none); + if (status != rocblas_status_success) { + return FAIL; + } + return OK; + } + + private: + int solution_; +}; + +template +auto GetRocBlasGemmStridedBatchedTypeStringAndOps() { + rocblas_handle handle = (rocblas_handle)at::cuda::getCurrentCUDABlasHandle(); + int solution_size; + auto input_output_type = RocBlasDataTypeFor(); + auto compute_type = RocBlasComputeTypeFor(); + // Get the number of available solutions + TORCH_ROCBLAS_CHECK(rocblas_gemm_ex_get_solutions_by_type(handle, + input_output_type, + input_output_type, + compute_type, + rocblas_gemm_flags_none, + nullptr, + &solution_size)); + std::vector solutions(solution_size); + // Get the list of available solutions + TORCH_ROCBLAS_CHECK(rocblas_gemm_ex_get_solutions_by_type(handle, + input_output_type, + input_output_type, + compute_type, + rocblas_gemm_flags_none, + solutions.data(), + &solution_size)); + // Sort the solutions in ascending order to make the solution vector deterministic across runs + std::sort(solutions.begin(), solutions.end()); + + std::vector>>>> ret; + for (size_t i = 0; i < solutions.size(); ++i) { + auto callable = std::make_unique>(solutions[i]); + ret.emplace_back(std::make_pair(c10::str("Gemm_Rocblas_", solutions[i]), std::move(callable))); + } + return ret; +} + +} // namespace at::cuda::tunable diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/StreamTimer.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/StreamTimer.h new file mode 100644 index 0000000000000000000000000000000000000000..15ed5e769975a9d1d14d365610a0d352d375249c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/StreamTimer.h @@ -0,0 +1,50 @@ +// Original TunableOp is from onnxruntime. +// https://github.com/microsoft/onnxruntime/blob/main/onnxruntime/core/framework/tunable.h +// https://github.com/microsoft/onnxruntime/tree/main/onnxruntime/core/providers/rocm/tunable +// Copyright (c) Microsoft Corporation. +// Licensed under the MIT license. +// +// Adapting TunableOp into PyTorch +// Copyright (c) Advanced Micro Devices, Inc. +// +#pragma once + +#include + +#include + +namespace at::cuda::tunable { + +class StreamTimer : public ITimer { + public: + StreamTimer(); + ~StreamTimer() override; + + void Start() override; + + void End() override; + + float Duration() override; + + private: + cudaEvent_t start_{}; + cudaEvent_t end_{}; +}; + +class StreamTimerNoSync : public ITimer { + public: + StreamTimerNoSync(); + ~StreamTimerNoSync() override; + + void Start() override; + + void End() override; + + float Duration() override; + + private: + cudaEvent_t start_{}; + cudaEvent_t end_{}; +}; + +} // namespace at::cuda::tunable diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/Tunable.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/Tunable.h new file mode 100644 index 0000000000000000000000000000000000000000..b8187b4254bfea8b687a3226b1db6bb81797c046 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/Tunable.h @@ -0,0 +1,241 @@ +// Original TunableOp is from onnxruntime. +// https://github.com/microsoft/onnxruntime/blob/main/onnxruntime/core/framework/tunable.h +// https://github.com/microsoft/onnxruntime/tree/main/onnxruntime/core/providers/rocm/tunable +// Copyright (c) Microsoft Corporation. +// Licensed under the MIT license. +// +// Adapting TunableOp into PyTorch +// Copyright (c) Advanced Micro Devices, Inc. +// +#pragma once + +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#define TUNABLE_LOGV(LEVEL, ...) getTuningContext()->Log(LEVEL, __VA_ARGS__) +#define TUNABLE_LOG1(...) TUNABLE_LOGV(1, __VA_ARGS__) +#define TUNABLE_LOG2(...) TUNABLE_LOGV(2, __VA_ARGS__) +#define TUNABLE_LOG3(...) TUNABLE_LOGV(3, __VA_ARGS__) + +namespace at::cuda::tunable { + +enum TORCH_CUDA_CPP_API TuningStatus { + OK = 0, + FAIL = 1, + UNSUPPORTED = 2, +}; + +// Mapping from params signature to kernel id +class TORCH_CUDA_CPP_API ResultEntry { + public: + explicit ResultEntry(std::string key, double time) : key_(std::move(key)), time_(time) {} + explicit ResultEntry(std::string key, double time, const std::string& blas_sig ) : key_(std::move(key)), time_(time), blas_sig_(blas_sig) {} + bool operator==(const ResultEntry& other) { return key_ == other.key_; } + bool operator!=(const ResultEntry& other) { return key_ != other.key_; } + operator std::string () { return key_; } + std::string GetKey() const { return key_; } + double GetTime() const { return time_; } + friend std::ostream& operator<<(std::ostream& stream, const ResultEntry& entry); + static ResultEntry Null() { return ResultEntry("Null", 0.0); } + static ResultEntry Default() { return ResultEntry("Default", 0.0); } + + private: + std::string key_; + double time_; + std::string blas_sig_; +}; + +typedef std::unordered_map KernelMap; +typedef std::unordered_map ResultsMap; +typedef std::unordered_map> UntunedMap; + +struct TORCH_CUDA_CPP_API TuningResults { + // Validates if these results are compatible with the libraries + std::unordered_map validators; + + // Mapping from Callable signature to Callable's tuning result + ResultsMap results; +}; + +class TORCH_CUDA_CPP_API TuningResultsManager { + public: + TuningResultsManager() = default; + ~TuningResultsManager() = default; + + KernelMap Lookup(const std::string& op_signature); + + ResultEntry Lookup(const std::string& op_signature, const std::string& params_signature); + + void AddImpl(const std::string& op_signature, + const std::string& params_signature, + ResultEntry best, + KernelMap& kernel_map); + + void Add(const std::string& op_signature, + const std::string& params_signature, + ResultEntry best); + + void Delete(const std::string& op_signature, const std::string& params_signature); + + void DisjointMergeImpl( + const std::string& op_signature, + const KernelMap& kernel_map, + /*out*/ ResultsMap& results); + + void Load(const ResultsMap& results_to_load); + + ResultsMap Dump(); + + void DisjointMerge(const std::string& op_signature, const KernelMap& kernel_map); + + size_t GetSize(); + + void RecordUntuned( std::ofstream& untuned_file, const std::string& op_signature, + const std::string& params_signature, const std::string& blas_signature); + private: + std::mutex lock_; + ResultsMap results_; + UntunedMap untuned_results_; + +}; + +class TORCH_CUDA_CPP_API TuningResultsValidator { + public: + using GetFunc = std::function; + using ValidateFunc = std::function; + using GetValidateFuncs = std::unordered_map>; + + TuningResultsValidator(); + ~TuningResultsValidator() = default; + + std::unordered_map GetAllValidators() const; + TuningStatus ValidateAll(const std::unordered_map& to_validate) const; + void RegisterValidator(const std::string& key, const GetFunc& gf, const ValidateFunc& vf); + + protected: + static std::string GetPyTorchVersion() ; + TuningStatus ValidatePyTorchVersion(const std::string& value) const; + + public: + static constexpr const std::array mandatory_keys{"PT_VERSION"}; + + private: + GetValidateFuncs validators_; +}; + +class TORCH_CUDA_CPP_API TuningContext { + public: + TuningContext(); + ~TuningContext(); + TuningContext(TuningContext &) = delete; + TuningContext(TuningContext &&) = delete; + TuningContext &operator=(TuningContext &) = delete; + TuningContext &operator=(TuningContext &&) = delete; + + void EnableTunableOp(bool value); + bool IsTunableOpEnabled() const; + + void EnableTuning(bool value); + bool IsTuningEnabled() const; + + void EnableRecordUntuned(bool value); + bool IsRecordUntunedEnabled() const; + std::ofstream& GetUntunedFile(); + + void EnableNumericsCheck(bool value); + bool IsNumericsCheckEnabled() const; + + void SetMaxTuningDurationMs(int max_duration_ms); + int GetMaxTuningDurationMs() const; + + void SetMaxTuningIterations(int max_iter); + int GetMaxTuningIterations() const; + + void SetMaxWarmupDurationMs(int max_duration_ms); + int GetMaxWarmupDurationMs() const; + + void SetMaxWarmupIterations(int max_iter); + int GetMaxWarmupIterations() const; + + void EnableICacheFlush(bool value); + bool IsICacheFlushEnabled() const; + + void SetRotatingBufferSize(int size); + int GetRotatingBufferSize() const; + + TuningResultsManager& GetTuningResultsManager(); + + TuningResultsValidator& GetTuningResultsValidator(); + + TuningResults GetTuningResults(); + + TuningStatus LoadTuningResults(const TuningResults& tr); + + void SetFilename(const std::string& filename, bool insert_device_ordinal=false); + std::string GetFilename() const; + + void WriteFileOnExit(bool value); + + bool ReadFile(const std::string& filename={}); + bool WriteFile(const std::string& filename={}); + + template + void Log(int level, Types... args) { + if (GetLogOkay() && GetLogLevel() >= level) { + GetLog() << c10::str(args...) << std::endl; + } + } + + private: + std::string GetLogFilename() const; + int GetLogLevel() const; + bool GetLogOkay() const; + std::ostream& GetLog() const; + + bool enable_; + bool tuning_enable_; + bool record_untuned_enable_; + bool manager_initialized_; + bool write_file_on_exit_; + bool numerics_check_enable_; + int max_tuning_duration_ms_; + int max_tuning_iterations_; + int max_warmup_duration_ms_; + int max_warmup_iterations_; + bool icache_flush_; + int rotating_buffer_size_; + mutable TuningResultsManager manager_; + mutable c10::once_flag manager_init_once_; + TuningResultsValidator validator_; + std::string filename_; + std::ofstream untuned_file_; + size_t results_count_from_input_file_; + bool is_shutting_down_; +}; + +TORCH_CUDA_CPP_API TuningContext* getTuningContext(); + +class ITimer { + public: + ITimer() = default; + virtual ~ITimer() = default; + + virtual void Start() = 0; + virtual void End() = 0; + + /// Computes the elapsed time in milliseconds between Start() and End() + virtual float Duration() = 0; +}; + +} // namespace at::cuda::tunable diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/TunableGemm.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/TunableGemm.h new file mode 100644 index 0000000000000000000000000000000000000000..f1c3729c93df191c7b087ac739603d5c5b940087 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/TunableGemm.h @@ -0,0 +1,323 @@ +// Original TunableOp is from onnxruntime. +// https://github.com/microsoft/onnxruntime/blob/main/onnxruntime/core/framework/tunable.h +// https://github.com/microsoft/onnxruntime/tree/main/onnxruntime/core/providers/rocm/tunable +// Copyright (c) Microsoft Corporation. +// Licensed under the MIT license. +// +// Adapting TunableOp into PyTorch +// Copyright (c) Advanced Micro Devices, Inc. +// +#pragma once + +#include +#ifdef USE_ROCM +#include +#include +#endif +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at::cuda::tunable { + +template +class DefaultGemmOp : public Callable> { + public: + TuningStatus Call(const GemmParams* params) override { + at::cuda::blas::gemm_internal( + params->transa, params->transb, + params->m, params->n, params->k, + params->alpha, + params->a, params->lda, + params->b, params->ldb, + params->beta, + params->c, params->ldc); + return OK; + } +}; + +static bool _transposeBoolFromChar(char op) { + return op == 't' || op == 'T'; +} + +template +class DefaultGemmAndBiasOp : public Callable> { + public: + TuningStatus Call(const GemmAndBiasParams* params) override { + at::cuda::blas::gemm_and_bias( + _transposeBoolFromChar(params->transa), + _transposeBoolFromChar(params->transb), + params->m, params->n, params->k, + params->alpha, + params->a, params->lda, + params->b, params->ldb, + params->bias, + params->c, params->ldc, + params->activation); + return OK; + } +}; + +template +class DefaultGemmStridedBatchedOp : public Callable> { + public: + TuningStatus Call(const GemmStridedBatchedParams* params) override { + at::cuda::blas::bgemm_internal( + params->transa, params->transb, + params->m, params->n, params->k, + params->alpha, + params->a, params->lda, params->stride_a, + params->b, params->ldb, params->stride_b, + params->beta, + params->c, params->ldc, params->stride_c, + params->batch); + return OK; + } +}; + +template +class DefaultScaledGemmOp : public Callable> { + public: + TuningStatus Call(const ScaledGemmParams* params) override { + at::cuda::blas::scaled_gemm( + params->transa, + params->transb, + params->m, + params->n, + params->k, + params->a, + params->a_scale_ptr, + params->lda, + params->a_dtype, + params->a_scale_dtype, + params->b, + params->b_scale_ptr, + params->ldb, + params->b_dtype, + params->b_scale_dtype, + params->bias_ptr, + params->bias_dtype, + params->c, + params->c_scale_ptr, + params->ldc, + params->c_dtype, + params->use_fast_accum, + params->use_rowwise); + return OK; + } +}; + +template +inline bool IsZero(T v) { + return v == 0.0f; +} + +template <> +inline bool IsZero(BFloat16 v) { + return v.x == 0; +} + +template <> +inline bool IsZero(Half v) { + return float(v) == 0.0f; +} + +template <> +inline bool IsZero(c10::complex v) { + return v == 0.0; +} + +template <> +inline bool IsZero(c10::complex v) { + return v == 0.0f; +} + +template +inline const char* TypeName(T v) { + return "unknown"; +} + +template <> +inline const char* TypeName(float v) { + return "float"; +} + +template <> +inline const char* TypeName(double v) { + return "double"; +} + +template <> +inline const char* TypeName(BFloat16 v) { + return "BFloat16"; +} + +template <> +inline const char* TypeName(Half v) { + return "Half"; +} + +template <> +inline const char* TypeName(Float8_e4m3fn v) { + return "Float8_e4m3fn"; +} + +template <> +inline const char* TypeName(Float8_e5m2 v) { + return "Float8_e5m2"; +} + +template <> +inline const char* TypeName(Float8_e4m3fnuz v) { + return "Float8_e4m3fnuz"; +} + +template <> +inline const char* TypeName(Float8_e5m2fnuz v) { + return "Float8_e5m2fnuz"; +} + +template <> +inline const char* TypeName(Float8_e8m0fnu v) { + return "Float8_e8m0fnu"; +} + +template <> +inline const char* TypeName(c10::complex v) { + return "c10::complex"; +} + +template <> +inline const char* TypeName(c10::complex v) { + return "c10::complex"; +} + +template +class GemmTunableOp : public TunableOp> { + public: + GemmTunableOp() { + this->RegisterOp(std::string("Default"), std::make_unique>()); + +#ifdef USE_ROCM + static const auto env_rocblas = c10::utils::check_env("PYTORCH_TUNABLEOP_ROCBLAS_ENABLED"); + if (!env_rocblas.has_value() || env_rocblas.value()) { + for (auto&& [name, op] : GetRocBlasGemmTypeStringAndOps()) { + this->RegisterOp(std::move(name), std::move(op)); + } + } + + static const auto env_hipblaslt = c10::utils::check_env("PYTORCH_TUNABLEOP_HIPBLASLT_ENABLED"); + if (!env_hipblaslt.has_value() || env_hipblaslt.value()) { + // disallow tuning of hipblaslt with c10::complex + if constexpr ( + !std::is_same_v> && + !std::is_same_v>) { + for (auto&& [name, op] : GetHipBlasLtGemmTypeStringAndOps()) { + this->RegisterOp(std::move(name), std::move(op)); + } + } + } +#endif + + this->RegisterOp(std::string("Default"), std::make_unique>()); + } + + std::string Signature() override { + return fmt::sprintf("GemmTunableOp_%s_%c%c", TypeName(T{}), BlasOpToString(ALayout), BlasOpToString(BLayout)); + } +}; + +template +class GemmAndBiasTunableOp : public TunableOp> { + public: + GemmAndBiasTunableOp() { + this->RegisterOp(std::string("Default"), std::make_unique>()); + +#ifdef USE_ROCM + static const auto env_hipblaslt = c10::utils::check_env("PYTORCH_TUNABLEOP_HIPBLASLT_ENABLED"); + if (!env_hipblaslt.has_value() || env_hipblaslt.value()) { + // disallow tuning of hipblaslt with c10::complex + if constexpr ( + !std::is_same_v> && + !std::is_same_v>) { + for (auto&& [name, op] : GetHipBlasLtGemmAndBiasTypeStringAndOps()) { + this->RegisterOp(std::move(name), std::move(op)); + } + } + } +#endif + + this->RegisterOp(std::string("Default"), std::make_unique>()); + } + + std::string Signature() override { + return fmt::sprintf("GemmAndBiasTunableOp_%s_%c%c", TypeName(T{}), BlasOpToString(ALayout), BlasOpToString(BLayout)); + } +}; + +template +class GemmStridedBatchedTunableOp : public TunableOp> { + public: + GemmStridedBatchedTunableOp() { + this->RegisterOp(std::string("Default"), std::make_unique>()); + +#ifdef USE_ROCM + static const auto env_rocblas = c10::utils::check_env("PYTORCH_TUNABLEOP_ROCBLAS_ENABLED"); + if (!env_rocblas.has_value() || env_rocblas.value()) { + for (auto&& [name, op] : GetRocBlasGemmStridedBatchedTypeStringAndOps()) { + this->RegisterOp(std::move(name), std::move(op)); + } + } + + static const auto env_hipblaslt = c10::utils::check_env("PYTORCH_TUNABLEOP_HIPBLASLT_ENABLED"); + if (!env_hipblaslt.has_value() || env_hipblaslt.value()) { + // disallow tuning of hipblaslt with c10::complex + if constexpr ( + !std::is_same_v> && + !std::is_same_v>) { + for (auto&& [name, op] : GetHipBlasLtGemmStridedBatchedTypeStringAndOps()) { + this->RegisterOp(std::move(name), std::move(op)); + } + } + } +#endif + + this->RegisterOp(std::string("Default"), std::make_unique>()); + } + + std::string Signature() override { + return fmt::sprintf("GemmStridedBatchedTunableOp_%s_%c%c", TypeName(T{}), BlasOpToString(ALayout), BlasOpToString(BLayout)); + } +}; + +template +class ScaledGemmTunableOp : public TunableOp> { + public: + ScaledGemmTunableOp() { + this->RegisterOp(std::string("Default"), std::make_unique>()); + +#ifdef USE_ROCM + for (auto&& [name, op] : GetHipBlasLtScaledGemmTypeStringAndOps()) { + this->RegisterOp(std::move(name), std::move(op)); + } +#endif + + this->RegisterOp(std::string("Default"), std::make_unique>()); + } + + std::string Signature() override { + return fmt::sprintf("ScaledGemmTunableOp_%s_%s_%s_%c%c", + TypeName(AT{}), + TypeName(BT{}), + TypeName(CT{}), + BlasOpToString(ALayout), BlasOpToString(BLayout)); + } +}; + +} // namespace at::cuda::tunable diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/TunableOp.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/TunableOp.h new file mode 100644 index 0000000000000000000000000000000000000000..6ca9e213e1489d64b22dfe00d7633901117a2dad --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cuda/tunable/TunableOp.h @@ -0,0 +1,430 @@ +// Original TunableOp is from onnxruntime. +// https://github.com/microsoft/onnxruntime/blob/main/onnxruntime/core/framework/tunable.h +// https://github.com/microsoft/onnxruntime/tree/main/onnxruntime/core/providers/rocm/tunable +// Copyright (c) Microsoft Corporation. +// Licensed under the MIT license. +// +// Adapting TunableOp into PyTorch +// Copyright (c) Advanced Micro Devices, Inc. +// +#pragma once + +#include +#include +#include +#include + +#ifndef _WIN32 +#include +#endif + +#include +#include +#include +#include + +namespace at::cuda::tunable { + +template +class Callable { + public: + virtual ~Callable() = default; + virtual TuningStatus Call(const ParamsT*) { + return FAIL; + } + virtual TuningStatus IsSupported(const ParamsT* params) { + return Call(params); + } +}; + +namespace { + +/** http://en.wikipedia.org/wiki/Algorithms_for_calculating_variance */ + +class Stats { + public: + Stats() { + _n = 0UL; + _mean = 0.0; + _M2 = 0.0; + _sum = 0.0; + _min = 0.0; + _max = 0.0; + } + + void sample_value(const double x) { + double delta = 0; + _sum = _sum + x; + if (0UL == _n) { + _min = x; + _max = x; + } + else { + _min = _min < x ? _min : x; + _max = _max > x ? _max : x; + } + _n = _n + 1UL; + delta = x - _mean; + _mean = _mean + delta/_n; + _M2 = _M2 + delta * (x - _mean); + } + + double variance() const { + return _M2/(_n-1); + } + + double stddev() const { + return std::sqrt(variance()); + } + + unsigned long _n; + double _mean; + double _M2; + double _sum; + double _min; + double _max; +}; + +class FixedSizeStack { + private: + std::deque stack; + const size_t max_size; + + public: + FixedSizeStack(size_t size) : max_size(size) {} + + void push(const std::string& value) { + if (stack.size() >= max_size) { + stack.pop_front(); // Remove the oldest entry + } + stack.push_back(value); // Add new entry + } + + auto rbegin() { return stack.rbegin(); } + auto rend() { return stack.rend(); } +}; + +} // anonymous namespace + +template +class TunableOp { + public: + virtual ~TunableOp() = default; + + TuningStatus operator()(const ParamsT* params) { + ResultEntry result = ResultEntry::Null(); + TuningContext* ctx = getTuningContext(); + if (ctx->IsTunableOpEnabled()) { + auto& mgr = ctx->GetTuningResultsManager(); + auto op_sig = Signature(); + auto params_sig = params->Signature(); + auto blas_sig = params->BLASSignature(); + result = mgr.Lookup(op_sig, params_sig); + // If there is not previous tuning result been found, we do the tuning iff tuning is enabled + if (result == ResultEntry::Null()) { + if (ctx->IsTuningEnabled()) { + result = FindFastest(params); + mgr.Add(op_sig, params_sig, result); + } + else if (ctx->IsRecordUntunedEnabled()) { + // or record the gemm into file + mgr.RecordUntuned(ctx->GetUntunedFile(), op_sig, params_sig, blas_sig); + } + } + } + else { + result = ResultEntry::Default(); + } + if (result == ResultEntry::Null()) { + TUNABLE_LOG2("no result, using default"); + result = ResultEntry::Default(); + } + auto iter = ops_.find(result); + TORCH_CHECK(iter != ops_.end()); + return iter->second->Call(params); + } + + virtual std::string Signature() { + // According to C++17 standard https://wg21.link/n4659 section 15.7.4 + // > if the operand of typeid refers to the + // > object under construction or destruction, typeid yields the std::type_info object representing the constructor + // > or destructor’s class. + // So delay the op signature generation. + c10::call_once(signature_init_once_, [this]() { signature_ = CreateSignature(); }); + return signature_; + } + + protected: + void RegisterOp(const std::string& name, std::unique_ptr> op) { + this->op_names_.emplace_back(name); + this->ops_.emplace(name, std::move(op)); + } + + private: + static void WarmUp(Callable *op, const std::vector ¶m, size_t num_iter, size_t &offset) { + TuningContext* ctx = getTuningContext(); + bool do_flush = ctx->IsICacheFlushEnabled(); + for (size_t i = 0; i < num_iter; i++) { + if (do_flush) { + at::cuda::flush_icache(); + } + TORCH_CHECK(op->Call(param[(i+offset++)%param.size()]) == OK); + } + } + + static double ProfileSimple(Callable *op, const std::vector ¶m, size_t num_iter, size_t &offset) { + TuningContext* ctx = getTuningContext(); + bool do_flush = ctx->IsICacheFlushEnabled(); + StreamTimerNoSync timer{}; + + // Small Mandatory Warmup + // Reduces outliers + for (size_t i = 0; i < 2; i++) { + TORCH_CHECK(op->Call(param[(i+offset++)%param.size()]) == OK); + } + + timer.Start(); + for (size_t i = 0; i < num_iter; i++) { + if (do_flush) { + at::cuda::flush_icache(); + } + TORCH_CHECK(op->Call(param[(i+offset++)%param.size()]) == OK); + } + timer.End(); + return timer.Duration() / num_iter; + } + + static Stats ProfileStats(Callable *op, const std::vector ¶m, size_t num_iter, size_t &offset) { + TuningContext* ctx = getTuningContext(); + bool do_flush = ctx->IsICacheFlushEnabled(); + std::vector timer(num_iter); + + // Small Mandatory Warmup + // Reduces outliers + for (size_t i = 0; i < 2; i++) { + TORCH_CHECK(op->Call(param[(i+offset++)%param.size()]) == OK); + } + + for (size_t i = 0; i < num_iter; i++) { + timer[i].Start(); + TORCH_CHECK(op->Call(param[(i+offset++)%param.size()]) == OK); + timer[i].End(); + if (do_flush) { + at::cuda::flush_icache(); + } + } + Stats s; + for (size_t i = 0; i < num_iter; i++) { + s.sample_value(timer[i].Duration()); + } + return s; + } + + protected: + virtual ResultEntry FindFastest(const ParamsT* params) { + TuningContext* ctx = getTuningContext(); + auto op_sig = Signature(); + auto params_sig = params->Signature(); + auto blas_sig = params->BLASSignature(); + TUNABLE_LOG2("finding fastest for ", op_sig, '(', params_sig, ')', " out of ", op_names_.size(), " candidates"); + auto min_duration_ms = std::numeric_limits::infinity(); + std::string id_name = "Default"; + ParamsT* reference_params = nullptr; + auto top_solns = FixedSizeStack(5); + + // numeric check option is controlled by non-static env var, so check it once per tuned operator + bool do_numerics_check = ctx->IsNumericsCheckEnabled(); + + // calcaulte a reference answer for numerical check + if (do_numerics_check) { + reference_params = params->DeepCopy(false); + TORCH_CHECK(ops_[ResultEntry::Default()]->Call(reference_params) == OK); + } + + // need copies of params to reuse + // make as many copies as will fill the requested rotating buffer size, if requested + // rotating_size guaranteed to be >= 0 even though GetRotatingBufferSize() returns int + size_t rotating_size = ctx->GetRotatingBufferSize(); + bool use_buffer_rotation = (rotating_size > 0); + size_t param_size = params->GetSize(use_buffer_rotation); + size_t param_count = (rotating_size / param_size) + 1; + constexpr size_t MB = 1024ull*1024; + if (use_buffer_rotation) { + TUNABLE_LOG2("Rotating buffer ", rotating_size/MB, " MiB. ", + "Needed Size: ", param_size/MB, " MiB. ", + "Needed number of param copies: ", param_count); + } + TORCH_CHECK(param_count > 0); + + std::vector reusable_params(param_count); + for (size_t i = 0; i < param_count; i++) { + reusable_params[i] = params->DeepCopy(use_buffer_rotation); + } + + // for rotating buffer + size_t offset = 0; + + for (size_t i = 0; i < op_names_.size(); i++) { + auto* candidate = ops_[op_names_[i]].get(); // borrow pointer + + if (do_numerics_check) { + ParamsT* numerical_params = params->DeepCopy(false); + auto status = candidate->Call(numerical_params); + if (status != OK) { + numerical_params->Delete(); + TUNABLE_LOG3("├──unsupported id=", i, ", ", op_sig, '(', params_sig, ") ", op_names_[i]); + continue; + } + status = reference_params->NumericalCheck(numerical_params); + numerical_params->Delete(); + if (status != OK) { + TUNABLE_LOG3("├──numerics check failed for id=", i, ", ", op_sig, '(', params_sig, ") ", op_names_[i]); + continue; + } + } + else { + auto status = candidate->Call(reusable_params[0]); + if (status != OK) { + TUNABLE_LOG3("├──unsupported id=", i, ", ", op_sig, '(', params_sig, ") ", op_names_[i]); + continue; + } + } + + // collect a small profile + int approx_num_iter = 3; + auto s = ProfileStats(candidate, reusable_params, approx_num_iter, offset); + double approx_duration = s._mean; + // bail if too slow + if (approx_duration > 1.5 * min_duration_ms) { + TUNABLE_LOG3("├──skip slow instance id=", i, ", ", op_sig, '(', params_sig, ") ", op_names_[i]); + continue; + } + + // 2nd phase skip, more aggressive + approx_num_iter = 10; + s = ProfileStats(candidate, reusable_params, approx_num_iter, offset); + approx_duration = s._mean; + // bail if too slow + if (approx_duration > 1.15 * min_duration_ms) { + TUNABLE_LOG3("├──2nd skip slow instance id=", i, ", ", op_sig, '(', params_sig, ") ", op_names_[i]); + continue; + } + + // for warmup does user set max duration, max iters, or both? + // warmup is skipped by default, i.e. warmup_iter = 0 + // warmup will be set to the non-zero value of max_warmup_duration + // or max_warmup_iter + // if both are non-zero, we take the smaller of the two. + double max_warmup_duration = ctx->GetMaxWarmupDurationMs(); + int max_warmup_iter = ctx->GetMaxWarmupIterations(); + int warmup_iter = 0; // default + if (max_warmup_duration > 0) { + int duration_iters = max_warmup_duration / approx_duration; + if (max_warmup_iter > 0) { + warmup_iter = std::min(max_warmup_iter, duration_iters); + } + else { + warmup_iter = duration_iters; + } + } + else if (max_warmup_iter > 0) { + warmup_iter = max_warmup_iter; + } + + // for tuning does user set max duration, max iters, or both? + double max_tuning_duration = ctx->GetMaxTuningDurationMs(); + int max_tuning_iter = ctx->GetMaxTuningIterations(); + int tuning_iter = 100; // default + if (max_tuning_duration > 0) { + int duration_iters = max_tuning_duration / approx_duration; + if (max_tuning_iter > 0) { + tuning_iter = std::min(max_tuning_iter, duration_iters); + } + else { + tuning_iter = duration_iters; + } + } + else if (max_tuning_iter > 0) { + tuning_iter = max_tuning_iter; + } + // tuning must run at least 1 iteration + tuning_iter = std::max(1, tuning_iter); + + // do the full warmup followed by tuning + double warmup_ms = warmup_iter * approx_duration; + double tuning_ms = tuning_iter * approx_duration; + TUNABLE_LOG3("├──tuning using " + "warmup iters ", warmup_iter, " [", warmup_ms, " ms] " + "and tuning iters ", tuning_iter, " [", tuning_ms, " ms] ", + "instance id=", i, ", ", op_sig, "(", params_sig, ") ", op_names_[i]); + TUNABLE_LOG3("├──offset at ", offset); + WarmUp(candidate, reusable_params, warmup_iter, offset); + s = ProfileStats(candidate, reusable_params, tuning_iter, offset); + auto s_stddev = s.stddev(); + // Assume normal distribution. + // Solution with smallest mean + 2*sigma will be a better solution? + // if ((s._mean + 2*s_stddev) < (min_duration_ms + 2*min_stddev_ms)) { + if (s._mean < min_duration_ms) { + TUNABLE_LOG3("├──found better instance id=", i, ". " , s._mean, "ms. ", op_names_[i], + " min ", s._min, + " max ", s._max, + " mean ", s._mean, + " std ", s_stddev); + min_duration_ms = s._mean; + id_name = op_names_[i]; + std::string current_soln = std::to_string(s._mean) + " " + op_names_[i]; + top_solns.push(current_soln); + } + else { + TUNABLE_LOG3("├──found slower instance id=", i, ". " , s._mean, "ms. ", op_names_[i], + " min ", s._min, + " max ", s._max, + " mean ", s._mean, + " std ", s_stddev); + } + } + + for (size_t i = 0; i < reusable_params.size(); i++) { + reusable_params[i]->Delete(); + } + if (reference_params) { + reference_params->Delete(); + } + + TUNABLE_LOG2("└──found fastest for ", op_sig, '(', params_sig, ") ", id_name); + TUNABLE_LOG2("└──top five solutions for ", op_sig, '(', params_sig, ") "); + for (auto it = top_solns.rbegin(); it != top_solns.rend(); ++it) { + TUNABLE_LOG2(" ", *it); + } + return ResultEntry(id_name, min_duration_ms, blas_sig); + } + + private: + std::string CreateSignature() { +#ifndef _WIN32 + const auto* name = typeid(*this).name(); + // NOLINTNEXTLINE(*array*) + char buf[256]; + size_t buf_len = 256; + abi::__cxa_demangle(name, buf, &buf_len, nullptr); + buf[255] = '\0'; + return buf; +#else + return typeid(*this).name(); +#endif + } + + mutable c10::once_flag signature_init_once_; + std::string signature_; + + std::unordered_map>> ops_; + std::vector op_names_; +}; + +struct OpParams { + virtual ~OpParams() = default; + virtual std::string Signature() const = 0; + virtual std::string BLASSignature() const = 0; +}; + +} // namespace at::cuda::tunable diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Descriptors.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Descriptors.h new file mode 100644 index 0000000000000000000000000000000000000000..6c2492b12e6b9ba1cabf87502feafa751dc816fd --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Descriptors.h @@ -0,0 +1,409 @@ +#pragma once + +#include + +#include +#include + +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + +#if defined(CUDNN_VERSION) && CUDNN_VERSION >= 8907 +#define USE_CUDNN_RNN_V8_API +#endif + +namespace at::native { + +std::string cudnnTypeToString(cudnnDataType_t dtype); + +// TODO: Add constructors for all of the descriptors + +inline int dataSize(cudnnDataType_t dataType) +{ + switch (dataType) { + case CUDNN_DATA_BFLOAT16: + case CUDNN_DATA_HALF: return 2; + case CUDNN_DATA_FLOAT: return 4; + default: return 8; + } +} + +// The stride for a size-1 dimensions is not uniquely determined; in +// fact, it can be anything you want, because the fact that the +// tensor is size 1 at this dimension means that you will never actually +// try advancing your pointer by this stride. +// +// However, CuDNN has a much more stringent requirement on strides: +// if you are passing a contiguous input, it better be the case +// that the stride for dim i is the product of the sizes of dims +// i+1 to the end. This stride is indeed uniquely determined. This +// function modifies 'stride' in place so this invariant holds. +template +static inline void fixSizeOneDimStride(int dim, const T *size, T *stride, bool nhwc) { + int64_t z = 1; + int index = 0; + std::vector permutation(dim); + + if (nhwc) { + permutation[index++] = 1; + } + for (int d = dim-1; d > 1; d--) { + permutation[index++] = d; + } + if (!nhwc) { + permutation[index++] = 1; + } + permutation[index++] = 0; + for (int d : permutation) { + if (size[d] == 1) { + stride[d] = z; + } else { + z *= size[d]; + } + } +} + +template +struct DescriptorDeleter { + void operator()(T* x) { + if (x != nullptr) { + AT_CUDNN_CHECK(dtor(x)); + } + } +}; + +// A generic class for wrapping cuDNN descriptor types. All you need +// is to give the underlying type the Descriptor_t points to (usually, +// if it's cudnnTensorDescriptor_t it points to cudnnTensorStruct), +// the constructor and the destructor. Subclasses are responsible +// for defining a set() function to actually set the descriptor. +// +// Descriptors default construct to a nullptr, and have a descriptor +// initialized the first time you call set() or any other initializing +// function. +template +// NOLINTNEXTLINE(bugprone-exception-escape) +class TORCH_CUDA_CPP_API Descriptor { + public: + // TODO: Figure out why const-correctness doesn't work here + + // Use desc() to access the underlying descriptor pointer in + // a read-only fashion. Most client code should use this. + // If the descriptor was never initialized, this will return + // nullptr. + T* desc() const { return desc_.get(); } + T* desc() { return desc_.get(); } + + // Use mut_desc() to access the underlying descriptor pointer + // if you intend to modify what it points to (e.g., using + // cudnnSetFooDescriptor). This will ensure that the descriptor + // is initialized. Code in this file will use this function. + T* mut_desc() { init(); return desc_.get(); } +protected: + void init() { + if (desc_ == nullptr) { + T* raw_desc = nullptr; + AT_CUDNN_CHECK(ctor(&raw_desc)); + desc_.reset(raw_desc); + } + } +private: + std::unique_ptr> desc_; +}; + +class TORCH_CUDA_CPP_API RNNDataDescriptor : public Descriptor< + cudnnRNNDataStruct, + &cudnnCreateRNNDataDescriptor, + &cudnnDestroyRNNDataDescriptor> { +public: + void set(const at::Tensor &t, cudnnRNNDataLayout_t layout, int maxSeqLength, int batchSize, int vectorSize, const int* seqLengthArray); +private: + void set(cudnnDataType_t dataType, cudnnRNNDataLayout_t layout, int maxSeqLength, int batchSize, int vectorSize, const int* seqLengthArray) { + AT_CUDNN_CHECK(cudnnSetRNNDataDescriptor(mut_desc(), dataType, layout, maxSeqLength, batchSize, vectorSize, seqLengthArray, nullptr)); + } +}; + +class TORCH_CUDA_CPP_API TensorDescriptor : public Descriptor< + cudnnTensorStruct, + &cudnnCreateTensorDescriptor, + &cudnnDestroyTensorDescriptor> { + public: + TensorDescriptor() = default; + explicit TensorDescriptor(const at::Tensor &t, size_t pad = 0) { + set(t, pad); + } + + // Note [CuDNN broadcast padding] + // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + // pad specifies the minimum dimensionality of the tensor descriptor + // we produce (it doesn't have anything to do with, e.g., convolution + // padding). If 't' is lower-dimensional than 'pad', the remaining + // dimensions (on the right) are padded with ones. This doesn't + // affect the underlying data layout. This is particularly useful for + // dealing with a peculiarity of the CuDNN API, which is that broadcasting in CuDNN is + // done in two steps: first, the client code is expected to pad out + // (the dimensions) input tensors to be the same dimension as the + // target broadcast, and then second, CuDNN takes of actually + // broadcasting size 1 dimensions. + + void set(const at::Tensor &t, size_t pad = 0); + void set(const at::Tensor &t, at::MemoryFormat memory_format, size_t pad = 0); + void set(cudnnDataType_t dataType, IntArrayRef sizes, IntArrayRef strides, size_t pad = 0); + + void print(); + +private: + void set(cudnnDataType_t dataType, IntArrayRef sizes, IntArrayRef strides, size_t pad, bool nhwc); + + void set(cudnnDataType_t dataType, int dim, int* size, int* stride, bool nhwc) { + std::vector strides_copy(stride, stride + dim); + fixSizeOneDimStride(dim, size, strides_copy.data(), nhwc); + AT_CUDNN_CHECK(cudnnSetTensorNdDescriptor(mut_desc(), dataType, dim, size, strides_copy.data())); + } +}; + +std::ostream& operator<<(std::ostream & out, const TensorDescriptor& d); + +class TORCH_CUDA_CPP_API FilterDescriptor : public Descriptor< + cudnnFilterStruct, + &cudnnCreateFilterDescriptor, + &cudnnDestroyFilterDescriptor> { + public: + void set(const at::Tensor &t, int64_t pad = 0) { + set(t, at::MemoryFormat::Contiguous, pad); + } + + void set(const at::Tensor &t, const at::MemoryFormat memory_format, int64_t pad = 0); + + void print(); +private: + void set(cudnnDataType_t dataType, int dim, int* size, cudnnTensorFormat_t filter_format) { + AT_CUDNN_CHECK(cudnnSetFilterNdDescriptor(mut_desc(), dataType, filter_format, dim, size)); + } +}; + +std::ostream& operator<<(std::ostream & out, const FilterDescriptor& d); + +struct TORCH_CUDA_CPP_API ConvolutionDescriptor + : public Descriptor< + cudnnConvolutionStruct, + &cudnnCreateConvolutionDescriptor, + &cudnnDestroyConvolutionDescriptor> { + void set(cudnnDataType_t dataType, int dim, int* pad, int* stride, int * upscale /* aka dilation */, int groups, bool allow_tf32) { + cudnnDataType_t mathType = dataType; + if (dataType == CUDNN_DATA_HALF) mathType = CUDNN_DATA_FLOAT; + AT_CUDNN_CHECK(cudnnSetConvolutionNdDescriptor(mut_desc(), dim, pad, stride, upscale, + CUDNN_CROSS_CORRELATION, mathType)); + AT_CUDNN_CHECK(cudnnSetConvolutionGroupCount(mut_desc(), groups)); + // See Note [behavior of cudnnFind and cudnnGet] + AT_CUDNN_CHECK(cudnnSetConvolutionMathType(mut_desc(), CUDNN_DEFAULT_MATH)); + if(dataType == CUDNN_DATA_HALF) { + AT_CUDNN_CHECK(cudnnSetConvolutionMathType(mut_desc(), CUDNN_TENSOR_OP_MATH)); + } else if (dataType == CUDNN_DATA_FLOAT && !allow_tf32) { + AT_CUDNN_CHECK(cudnnSetConvolutionMathType(mut_desc(), CUDNN_FMA_MATH)); + } + } +}; + +struct TORCH_CUDA_CPP_API SpatialTransformerDescriptor + : public Descriptor< + cudnnSpatialTransformerStruct, + &cudnnCreateSpatialTransformerDescriptor, + &cudnnDestroySpatialTransformerDescriptor> { + void set(cudnnDataType_t dataType, int dim, int* size) { + AT_CUDNN_CHECK(cudnnSetSpatialTransformerNdDescriptor(mut_desc(), CUDNN_SAMPLER_BILINEAR, dataType, dim, size)); + } +}; + +// NOLINTNEXTLINE(bugprone-exception-escape) +struct TORCH_CUDA_CPP_API DropoutDescriptor + : public Descriptor< + cudnnDropoutStruct, + &cudnnCreateDropoutDescriptor, + &cudnnDestroyDropoutDescriptor> { + at::Tensor state; + + // Initialize a dropout descriptor's RNG state. + // WARNING: This function is very expensive, avoid calling this function! + void initialize_rng(cudnnHandle_t handle, float dropout, long long int seed, const TensorOptions& options) { + TORCH_INTERNAL_ASSERT(dropout > 0, "dropout must be nonzero; otherwise call set_no_dropout"); + size_t state_size = 0; + AT_CUDNN_CHECK(cudnnDropoutGetStatesSize(handle, &state_size)); + AT_ASSERT(options.device().type() == kCUDA); + AT_ASSERT(options.dtype() == kByte); + state = at::empty({static_cast(state_size)}, options); + AT_CUDNN_CHECK(cudnnSetDropoutDescriptor(mut_desc(), handle, dropout, state.data_ptr(), state_size, seed)); + } + + // Restore a dropout descriptor given a dropout probability and existing RNG state. + void set(cudnnHandle_t handle, float dropout, const at::Tensor& state) { + TORCH_INTERNAL_ASSERT(dropout > 0, "dropout must be nonzero; otherwise call set_no_dropout"); + void *state_ptr = state.data_ptr(); + size_t state_size = state.size(0); + // NB: The seed doesn't actually matter, so we give a dummy value + AT_CUDNN_CHECK(cudnnRestoreDropoutDescriptor(mut_desc(), handle, dropout, state_ptr, state_size, 0 /* seed */)); + } + + // Restore a dropout descriptor corresponding to no dropout + void set_no_dropout(cudnnHandle_t handle) { + // NB: seed doesn't matter when dropout = 0, because no random number + // initialization actually takes place when there is no dropout. + // NB: Empirically, cudnnSetDropoutDescriptor is cheap when + // dropout == 0 + AT_CUDNN_CHECK(cudnnSetDropoutDescriptor(mut_desc(), handle, 0 /* dropout */, nullptr, 0 /* state_size */, 0 /* seed */)); + } +}; + +struct TORCH_CUDA_CPP_API RNNDescriptor : public Descriptor< + cudnnRNNStruct, + &cudnnCreateRNNDescriptor, + &cudnnDestroyRNNDescriptor> { + DropoutDescriptor dropout_desc_; + void set(cudnnHandle_t handle, +#ifdef USE_CUDNN_RNN_V8_API + int input_size, + bool packed, +#endif + int hidden_size, int proj_size, int num_layers, DropoutDescriptor&& dropout_desc, + cudnnRNNInputMode_t input_mode, cudnnDirectionMode_t bidirectional, + cudnnRNNMode_t mode, cudnnDataType_t datatype, cudnnDataType_t input_type, cudnnRNNAlgo_t algo, bool allow_tf32) { + dropout_desc_ = std::move(dropout_desc); +#ifndef USE_CUDNN_RNN_V8_API + AT_CUDNN_CHECK(cudnnSetRNNDescriptor_v6( + handle, + mut_desc(), + hidden_size, + num_layers, + dropout_desc_.desc(), + input_mode, + bidirectional, + mode, + algo, + datatype)); + if (proj_size != 0) { + AT_CUDNN_CHECK(cudnnSetRNNProjectionLayers( + handle, + /*rnnDesc=*/mut_desc(), + /*recProjSize=*/proj_size, + /*outProjSize=*/0)); + } + cudaDeviceProp* prop = at::cuda::getCurrentDeviceProperties(); + if (prop->major >= 7) { + if (input_type == CUDNN_DATA_HALF) { + cudnnSetRNNMatrixMathType(mut_desc(), CUDNN_TENSOR_OP_MATH); + } + else if (input_type == CUDNN_DATA_FLOAT && !allow_tf32) { + cudnnSetRNNMatrixMathType(mut_desc(), CUDNN_FMA_MATH); + } + else { + // Technically, as the default it's not necessary to explicitly + // set this. + cudnnSetRNNMatrixMathType(mut_desc(), CUDNN_DEFAULT_MATH); + } + } +#else + cudaDeviceProp* prop = at::cuda::getCurrentDeviceProperties(); + auto math_type = CUDNN_DEFAULT_MATH; + if (prop->major >= 7) { + if (input_type == CUDNN_DATA_HALF) { + math_type = CUDNN_TENSOR_OP_MATH; + } else if (!allow_tf32) { + math_type = CUDNN_FMA_MATH; + } + } + AT_CUDNN_CHECK(cudnnSetRNNDescriptor_v8( + mut_desc(), + algo, + mode, + CUDNN_RNN_DOUBLE_BIAS, + bidirectional, + input_mode, + input_type, + datatype, + math_type, + input_size, + hidden_size, + proj_size ? proj_size : hidden_size, + num_layers, + dropout_desc_.desc(), + packed ? CUDNN_RNN_PADDED_IO_DISABLED : CUDNN_RNN_PADDED_IO_ENABLED)); +#endif + } +}; + +struct TORCH_CUDA_CPP_API CTCLossDescriptor + : public Descriptor< + cudnnCTCLossStruct, + &cudnnCreateCTCLossDescriptor, + &cudnnDestroyCTCLossDescriptor> { + void set(cudnnDataType_t datatype) { + AT_CUDNN_CHECK(cudnnSetCTCLossDescriptor(mut_desc(), datatype)); + } + void setEx( + cudnnDataType_t datatype, + cudnnLossNormalizationMode_t normMode, + cudnnNanPropagation_t gradMode) { + AT_CUDNN_CHECK( + cudnnSetCTCLossDescriptorEx(mut_desc(), datatype, normMode, gradMode)); + } + void set_v8_v9( + cudnnDataType_t datatype, + cudnnLossNormalizationMode_t normMode, + cudnnNanPropagation_t gradMode, + int maxLabelLength) { +#if defined(CUDNN_VERSION) && CUDNN_VERSION >= 90000 + auto gradModev9 = CUDNN_CTC_ZERO_OOB_GRADIENTS; + if (gradMode == cudnnNanPropagation_t::CUDNN_PROPAGATE_NAN) { + gradModev9 = CUDNN_CTC_SKIP_OOB_GRADIENTS; + } + AT_CUDNN_CHECK( + cudnnSetCTCLossDescriptor_v9(mut_desc(), datatype, normMode, gradModev9, maxLabelLength)); +#else + AT_CUDNN_CHECK( + cudnnSetCTCLossDescriptor_v8(mut_desc(), datatype, normMode, gradMode, maxLabelLength)); +#endif + } + +}; + +struct TORCH_CUDA_CPP_API ActivationDescriptor + : public Descriptor< + cudnnActivationStruct, + &cudnnCreateActivationDescriptor, + &cudnnDestroyActivationDescriptor> { + void set(cudnnActivationMode_t mode) { + AT_ASSERT( + mode == CUDNN_ACTIVATION_RELU, + "TODO: support more cuDNN activation modes"); + AT_CUDNN_CHECK(cudnnSetActivationDescriptor( + mut_desc(), + mode, + cudnnNanPropagation_t::CUDNN_NOT_PROPAGATE_NAN, + std::numeric_limits::max())); + } +}; + +union Constant +{ + float f; + double d; + Constant(cudnnDataType_t dataType, double value) { + if (dataType == CUDNN_DATA_HALF || dataType == CUDNN_DATA_FLOAT) { + f = static_cast(value); + } else { + d = value; + } + } +}; + +} // namespace diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Handle.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Handle.h new file mode 100644 index 0000000000000000000000000000000000000000..a049ee9ad8fa47a658cbb70337ee2c4c8461abda --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Handle.h @@ -0,0 +1,9 @@ +#pragma once + +#include +#include + +namespace at::native { + +TORCH_CUDA_CPP_API cudnnHandle_t getCudnnHandle(); +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Handles.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Handles.h new file mode 100644 index 0000000000000000000000000000000000000000..5b9a081f0c11b57b093891e0dd2adbd969a79f96 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Handles.h @@ -0,0 +1,2 @@ +#pragma once +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Types.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Types.h new file mode 100644 index 0000000000000000000000000000000000000000..202a72e4761aecb485780c9d6b1e2129b9ac31cb --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Types.h @@ -0,0 +1,14 @@ +#pragma once + +#include +#include + +namespace at::native { + +TORCH_CUDA_CPP_API cudnnDataType_t +getCudnnDataTypeFromScalarType(const at::ScalarType dtype); +cudnnDataType_t getCudnnDataType(const at::Tensor& tensor); + +int64_t cudnn_version(); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Utils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Utils.h new file mode 100644 index 0000000000000000000000000000000000000000..a66df02c2001891382319a84ded65a42f85a4cea --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/Utils.h @@ -0,0 +1,22 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::native { + +// cuDNN has a buggy check for tensor being contiguous (that is, it does +// not ignore stride for dimension that is equal to 0). This function +// makes tensors which have zero stride contiguous, by setting the +// strides to 1 as cuDNN likes. +inline Tensor contiguousIfZeroInStrides(const Tensor& t) { + for (auto s : t.strides()) { + if (s == 0) + return t.contiguous(); + } + return t; +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/cudnn-wrapper.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/cudnn-wrapper.h new file mode 100644 index 0000000000000000000000000000000000000000..52ec1cddcb7dc1a0263a65da5ff2f33a36805af0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/cudnn/cudnn-wrapper.h @@ -0,0 +1,16 @@ +#pragma once + +#include + +#define STRINGIFY(x) #x +#define STRING(x) STRINGIFY(x) + +#if CUDNN_MAJOR < 8 || (CUDNN_MAJOR == 8 && CUDNN_MINOR < 5) +#pragma message("CuDNN v" STRING( \ + CUDNN_MAJOR) " found, but need at least CuDNN v8. You can get the latest version of CuDNN from https://developer.nvidia.com/cudnn or disable CuDNN with USE_CUDNN=0") +#pragma message "We strongly encourage you to move to 8.5 and above." +#pragma message "This message is intended to annoy you enough to update." +#endif + +#undef STRINGIFY +#undef STRING diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/AcceleratorHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/AcceleratorHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..5aa38635430d0ceacec92ec4e79b1ff970cf20d8 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/AcceleratorHooksInterface.h @@ -0,0 +1,96 @@ +#pragma once + +#include + +#include +#include +#include + +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Wunused-parameter") + +namespace at { + +// AcceleratorHooksInterface is a shared interface provided by all +// accelerators to allow generic code. +// This inferface is hook-based as it corresponds to all the functions +// that are going to be called in a generic way from the CPU code. + +struct TORCH_API AcceleratorHooksInterface { + // This should never actually be implemented, but it is used to + // squelch -Werror=non-virtual-dtor + virtual ~AcceleratorHooksInterface() = default; + + // Whether this backend was enabled at compilation time. + // This function should NEVER throw. + virtual bool isBuilt() const { + return false; + } + + // Whether this backend can be used at runtime, meaning it was built, + // its runtime dependencies are available (driver) and at least one + // supported device can be used. + // This function should NEVER throw. This function should NOT initialize the context + // on any device (result of hasPrimaryContext below should not change). + // While it is acceptable for this function to poison fork, it is + // recommended to avoid doing so whenever possible. + virtual bool isAvailable() const { + return false; + } + + // Whether the device at device_index is fully initialized or not. + virtual bool hasPrimaryContext(DeviceIndex device_index) const = 0; + + virtual void init() const { + TORCH_CHECK(false, "Backend doesn`t support init()"); + } + + virtual DeviceIndex deviceCount() const { + return 0; + } + + virtual void setCurrentDevice(DeviceIndex device) const { + TORCH_CHECK(false, "Backend doesn't support setCurrentDevice()"); + } + + virtual DeviceIndex getCurrentDevice() const { + TORCH_CHECK(false, "Backend doesn't support getCurrentDevice()"); + return -1; + } + + virtual DeviceIndex exchangeDevice(DeviceIndex device) const { + TORCH_CHECK(false, "Backend doesn't support exchangeDevice()"); + return -1; + } + + virtual DeviceIndex maybeExchangeDevice(DeviceIndex device) const { + TORCH_CHECK(false, "Backend doesn't support maybeExchangeDevice()"); + return -1; + } + + virtual bool isPinnedPtr(const void* data) const { + return false; + } + + virtual Allocator* getPinnedMemoryAllocator() const { + TORCH_CHECK(false, "Backend doesn't support getPinnedMemoryAllocator()"); + return nullptr; + } + + virtual Device getDeviceFromPtr(void* data) const { + TORCH_CHECK(false, "Backend doesn't support getDeviceFromPtr()"); + } + + virtual const Generator& getDefaultGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const { + TORCH_CHECK(false, "Backend doesn`t support getDefaultGenerator()"); + } + + virtual Generator getNewGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const { + TORCH_CHECK(false, "Backend doesn`t support getNewGenerator()"); + } +}; + +} // namespace at + +C10_DIAGNOSTIC_POP() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/CUDAHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/CUDAHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..9b54a84dd68dfe7e7767656c3bce8b3a80d42b5b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/CUDAHooksInterface.h @@ -0,0 +1,220 @@ +#pragma once + +#include +#include +#include + +#include + +// NB: Class must live in `at` due to limitations of Registry.h. +namespace at { + +// Forward-declares at::cuda::NVRTC +namespace cuda { +struct NVRTC; +} // namespace cuda + +#ifdef _MSC_VER +constexpr const char* CUDA_HELP = + "PyTorch splits its backend into two shared libraries: a CPU library " + "and a CUDA library; this error has occurred because you are trying " + "to use some CUDA functionality, but the CUDA library has not been " + "loaded by the dynamic linker for some reason. The CUDA library MUST " + "be loaded, EVEN IF you don't directly use any symbols from the CUDA library! " + "One common culprit is a lack of -INCLUDE:?warp_size@cuda@at@@YAHXZ " + "in your link arguments; many dynamic linkers will delete dynamic library " + "dependencies if you don't depend on any of their symbols. You can check " + "if this has occurred by using link on your binary to see if there is a " + "dependency on *_cuda.dll library."; +#else +constexpr const char* CUDA_HELP = + "PyTorch splits its backend into two shared libraries: a CPU library " + "and a CUDA library; this error has occurred because you are trying " + "to use some CUDA functionality, but the CUDA library has not been " + "loaded by the dynamic linker for some reason. The CUDA library MUST " + "be loaded, EVEN IF you don't directly use any symbols from the CUDA library! " + "One common culprit is a lack of -Wl,--no-as-needed in your link arguments; many " + "dynamic linkers will delete dynamic library dependencies if you don't " + "depend on any of their symbols. You can check if this has occurred by " + "using ldd on your binary to see if there is a dependency on *_cuda.so " + "library."; +#endif + +// The CUDAHooksInterface is an omnibus interface for any CUDA functionality +// which we may want to call into from CPU code (and thus must be dynamically +// dispatched, to allow for separate compilation of CUDA code). How do I +// decide if a function should live in this class? There are two tests: +// +// 1. Does the *implementation* of this function require linking against +// CUDA libraries? +// +// 2. Is this function *called* from non-CUDA ATen code? +// +// (2) should filter out many ostensible use-cases, since many times a CUDA +// function provided by ATen is only really ever used by actual CUDA code. +// +// TODO: Consider putting the stub definitions in another class, so that one +// never forgets to implement each virtual function in the real implementation +// in CUDAHooks. This probably doesn't buy us much though. +struct TORCH_API CUDAHooksInterface : AcceleratorHooksInterface { + // This should never actually be implemented, but it is used to + // squelch -Werror=non-virtual-dtor + ~CUDAHooksInterface() override = default; + + // Initialize THCState and, transitively, the CUDA state + void init() const override { + TORCH_CHECK(false, "Cannot initialize CUDA without ATen_cuda library. ", CUDA_HELP); + } + + const Generator& getDefaultGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const override { + TORCH_CHECK( + false, + "Cannot get default CUDA generator without ATen_cuda library. ", + CUDA_HELP); + } + + Generator getNewGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const override { + TORCH_CHECK( + false, + "Cannot get CUDA generator without ATen_cuda library. ", + CUDA_HELP); + } + + Device getDeviceFromPtr(void* /*data*/) const override { + TORCH_CHECK(false, "Cannot get device of pointer on CUDA without ATen_cuda library. ", CUDA_HELP); + } + + bool isPinnedPtr(const void* data) const override { + return false; + } + + virtual bool hasCUDA() const { + return false; + } + + virtual bool hasCUDART() const { + return false; + } + + virtual bool hasMAGMA() const { + return false; + } + + virtual bool hasCuDNN() const { + return false; + } + + virtual bool hasCuSOLVER() const { + return false; + } + + virtual bool hasCuBLASLt() const { + return false; + } + + virtual bool hasROCM() const { + return false; + } + + virtual const at::cuda::NVRTC& nvrtc() const { + TORCH_CHECK(false, "NVRTC requires CUDA. ", CUDA_HELP); + } + + bool hasPrimaryContext(DeviceIndex device_index) const override { + TORCH_CHECK(false, "Cannot call hasPrimaryContext(", device_index, ") without ATen_cuda library. ", CUDA_HELP); + } + + virtual DeviceIndex current_device() const { + return -1; + } + + Allocator* getPinnedMemoryAllocator() const override { + TORCH_CHECK(false, "Pinned memory requires CUDA. ", CUDA_HELP); + } + + virtual Allocator* getCUDADeviceAllocator() const { + TORCH_CHECK(false, "CUDADeviceAllocator requires CUDA. ", CUDA_HELP); + } + + virtual bool compiledWithCuDNN() const { + return false; + } + + virtual bool compiledWithMIOpen() const { + return false; + } + + virtual bool supportsDilatedConvolutionWithCuDNN() const { + return false; + } + + virtual bool supportsDepthwiseConvolutionWithCuDNN() const { + return false; + } + + virtual bool supportsBFloat16ConvolutionWithCuDNNv8() const { + return false; + } + + virtual long versionCuDNN() const { + TORCH_CHECK(false, "Cannot query cuDNN version without ATen_cuda library. ", CUDA_HELP); + } + + virtual long versionCUDART() const { + TORCH_CHECK(false, "Cannot query CUDART version without ATen_cuda library. ", CUDA_HELP); + } + + virtual std::string showConfig() const { + TORCH_CHECK(false, "Cannot query detailed CUDA version without ATen_cuda library. ", CUDA_HELP); + } + + virtual double batchnormMinEpsilonCuDNN() const { + TORCH_CHECK(false, + "Cannot query batchnormMinEpsilonCuDNN() without ATen_cuda library. ", CUDA_HELP); + } + + virtual int64_t cuFFTGetPlanCacheMaxSize(DeviceIndex /*device_index*/) const { + TORCH_CHECK(false, "Cannot access cuFFT plan cache without ATen_cuda library. ", CUDA_HELP); + } + + virtual void cuFFTSetPlanCacheMaxSize(DeviceIndex /*device_index*/, int64_t /*max_size*/) const { + TORCH_CHECK(false, "Cannot access cuFFT plan cache without ATen_cuda library. ", CUDA_HELP); + } + + virtual int64_t cuFFTGetPlanCacheSize(DeviceIndex /*device_index*/) const { + TORCH_CHECK(false, "Cannot access cuFFT plan cache without ATen_cuda library. ", CUDA_HELP); + } + + virtual void cuFFTClearPlanCache(DeviceIndex /*device_index*/) const { + TORCH_CHECK(false, "Cannot access cuFFT plan cache without ATen_cuda library. ", CUDA_HELP); + } + + virtual int getNumGPUs() const { + return 0; + } + +#ifdef USE_ROCM + virtual bool isGPUArch(DeviceIndex /*device_index*/, const std::vector& /*archs*/) const { + TORCH_CHECK(false, "Cannot check GPU arch without ATen_cuda library. ", CUDA_HELP); + } +#endif + + virtual void deviceSynchronize(DeviceIndex /*device_index*/) const { + TORCH_CHECK(false, "Cannot synchronize CUDA device without ATen_cuda library. ", CUDA_HELP); + } +}; + +// NB: dummy argument to suppress "ISO C++11 requires at least one argument +// for the "..." in a variadic macro" +struct TORCH_API CUDAHooksArgs {}; + +TORCH_DECLARE_REGISTRY(CUDAHooksRegistry, CUDAHooksInterface, CUDAHooksArgs); +#define REGISTER_CUDA_HOOKS(clsname) \ + C10_REGISTER_CLASS(CUDAHooksRegistry, clsname, clsname) + +namespace detail { +TORCH_API const CUDAHooksInterface& getCUDAHooks(); +} // namespace detail +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/FunctionTraits.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/FunctionTraits.h new file mode 100644 index 0000000000000000000000000000000000000000..c9212cb75a4d48e2db725e2d510adf2fdbbb5d98 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/FunctionTraits.h @@ -0,0 +1,103 @@ +#pragma once + +#include +#include + +// Modified from https://stackoverflow.com/questions/7943525/is-it-possible-to-figure-out-the-parameter-type-and-return-type-of-a-lambda + +// Fallback, anything with an operator() +template +struct function_traits : public function_traits { +}; + +// Pointers to class members that are themselves functors. +// For example, in the following code: +// template +// struct S { +// func_t f; +// }; +// template +// S make_s(func_t f) { +// return S { .f = f }; +// } +// +// auto s = make_s([] (int, float) -> double { /* ... */ }); +// +// function_traits traits; +template +struct function_traits : public function_traits { +}; + +// Const class member functions +template +struct function_traits : public function_traits { +}; + +// Reference types +template +struct function_traits : public function_traits {}; +template +struct function_traits : public function_traits {}; + +// Free functions +template +struct function_traits { + // arity is the number of arguments. + enum { arity = sizeof...(Args) }; + + using ArgsTuple = std::tuple; + using result_type = ReturnType; + + template + struct arg + { + using type = typename std::tuple_element>::type; + // the i-th argument is equivalent to the i-th tuple element of a tuple + // composed of those arguments. + }; +}; + +template +struct nullary_function_traits { + using traits = function_traits; + using result_type = typename traits::result_type; +}; + +template +struct unary_function_traits { + using traits = function_traits; + using result_type = typename traits::result_type; + using arg1_t = typename traits::template arg<0>::type; +}; + +template +struct binary_function_traits { + using traits = function_traits; + using result_type = typename traits::result_type; + using arg1_t = typename traits::template arg<0>::type; + using arg2_t = typename traits::template arg<1>::type; +}; + + +// Traits for calling with c10::guts::invoke, where member_functions have a first argument of ClassType +template +struct invoke_traits : public function_traits{ +}; + +template +struct invoke_traits : public invoke_traits{ +}; + +template +struct invoke_traits : public invoke_traits{ +}; + +template +struct invoke_traits : + public function_traits { +}; + +template +struct invoke_traits : + public function_traits { +}; diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/HIPHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/HIPHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..e19a379efbdace351273ec79c90eb75a256a3006 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/HIPHooksInterface.h @@ -0,0 +1,69 @@ +#pragma once + +#include +#include +#include + +#include + +#include + +// NB: Class must live in `at` due to limitations of Registry.h. +namespace at { + +// The HIPHooksInterface is an omnibus interface for any HIP functionality +// which we may want to call into from CPU code (and thus must be dynamically +// dispatched, to allow for separate compilation of HIP code). See +// CUDAHooksInterface for more detailed motivation. +struct TORCH_API HIPHooksInterface : AcceleratorHooksInterface { + // This should never actually be implemented, but it is used to + // squelch -Werror=non-virtual-dtor + ~HIPHooksInterface() override = default; + + void init() const override { + TORCH_CHECK(false, "Cannot initialize HIP without ATen_hip library."); + } + + const Generator& getDefaultGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const override { + TORCH_CHECK(false, "Cannot initialize HIP without ATen_hip library."); + } + + virtual bool hasHIP() const { + return false; + } + + virtual c10::DeviceIndex current_device() const { + return -1; + } + + bool isPinnedPtr(const void* data) const override { + return false; + } + + Allocator* getPinnedMemoryAllocator() const override { + TORCH_CHECK(false, "Pinned memory requires HIP."); + } + + virtual int getNumGPUs() const { + return 0; + } + + bool hasPrimaryContext(DeviceIndex device_index) const override { + TORCH_CHECK(false, "Cannot check primary context without ATen_hip library."); + } +}; + +// NB: dummy argument to suppress "ISO C++11 requires at least one argument +// for the "..." in a variadic macro" +struct TORCH_API HIPHooksArgs {}; + +TORCH_DECLARE_REGISTRY(HIPHooksRegistry, HIPHooksInterface, HIPHooksArgs); +#define REGISTER_HIP_HOOKS(clsname) \ + C10_REGISTER_CLASS(HIPHooksRegistry, clsname, clsname) + +namespace detail { +TORCH_API const HIPHooksInterface& getHIPHooks(); + +} // namespace detail +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/HPUHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/HPUHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..8cf9502a7e1b90c369329985d88d96c36f640582 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/HPUHooksInterface.h @@ -0,0 +1,57 @@ +#pragma once + +#include +#include + +#include +#include +#include + +namespace at { + +struct TORCH_API HPUHooksInterface : AcceleratorHooksInterface { + ~HPUHooksInterface() override = default; + + void init() const override { + TORCH_CHECK(false, "Cannot initialize HPU without HPU backend"); + } + + virtual bool hasHPU() const { + return false; + } + + Device getDeviceFromPtr(void* /*data*/) const override { + TORCH_CHECK( + false, "Cannot get device of pointer on HPU without HPU backend"); + } + + bool isPinnedPtr(const void*) const override { + return false; + } + + Allocator* getPinnedMemoryAllocator() const override { + TORCH_CHECK( + false, + "You should register `HPUHooksInterface` for HPU before call `getPinnedMemoryAllocator`."); + } + + bool hasPrimaryContext( + [[maybe_unused]] DeviceIndex device_index) const override { + TORCH_CHECK( + false, + "You should register `HPUHooksInterface` for HPU before call `hasPrimaryContext`."); + } +}; + +struct TORCH_API HPUHooksArgs {}; + +TORCH_DECLARE_REGISTRY(HPUHooksRegistry, HPUHooksInterface, HPUHooksArgs); +#define REGISTER_HPU_HOOKS(clsname) \ + C10_REGISTER_CLASS(HPUHooksRegistry, clsname, clsname) + +namespace detail { + +TORCH_API const at::HPUHooksInterface& getHPUHooks(); + +} // namespace detail +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/IPUHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/IPUHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..ee29aa352f3defdf32e3c415abfc9a4fd2a96c6a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/IPUHooksInterface.h @@ -0,0 +1,43 @@ +#pragma once + +#include + +#include +#include +#include + +namespace at { + +struct TORCH_API IPUHooksInterface : AcceleratorHooksInterface { + ~IPUHooksInterface() override = default; + + void init() const override { + TORCH_CHECK(false, "Cannot initialize IPU without ATen_ipu library."); + } + + bool hasPrimaryContext(DeviceIndex device_index) const override { + TORCH_CHECK(false, "Cannot initialize IPU without ATen_ipu library."); + return false; + } + + const Generator& getDefaultGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const override { + TORCH_CHECK(false, "Cannot initialize IPU without ATen_ipu library."); + } + + Generator getNewGenerator( + DeviceIndex device_index [[maybe_unused]] = -1) const override { + TORCH_CHECK(false, "Cannot initialize IPU without ATen_ipu library."); + } +}; + +struct TORCH_API IPUHooksArgs {}; + +TORCH_DECLARE_REGISTRY(IPUHooksRegistry, IPUHooksInterface, IPUHooksArgs); +#define REGISTER_IPU_HOOKS(clsname) \ + C10_REGISTER_CLASS(IPUHooksRegistry, clsname, clsname) + +namespace detail { +TORCH_API const IPUHooksInterface& getIPUHooks(); +} // namespace detail +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/MAIAHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/MAIAHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..554cc93043fd3c19d65db06b1d0656b4714b898f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/MAIAHooksInterface.h @@ -0,0 +1,42 @@ +#pragma once + +#include +#include + +#include + +// NB: Class must live in `at` due to limitations of Registry.h. +namespace at { + +struct TORCH_API MAIAHooksInterface : AcceleratorHooksInterface { + // This should never actually be implemented, but it is used to + // squelch -Werror=non-virtual-dtor + ~MAIAHooksInterface() override = default; + + void init() const override { + TORCH_CHECK(false, "Cannot initialize MAIA without ATen_maia library."); + } + + bool hasPrimaryContext(DeviceIndex device_index) const override { + TORCH_CHECK(false, "Cannot initialize MAIA without ATen_maia library."); + return false; + } + + virtual std::string showConfig() const { + TORCH_CHECK(false, "Cannot query detailed MAIA version information."); + } +}; + +// NB: dummy argument to suppress "ISO C++11 requires at least one argument +// for the "..." in a variadic macro" +struct TORCH_API MAIAHooksArgs {}; + +TORCH_DECLARE_REGISTRY(MAIAHooksRegistry, MAIAHooksInterface, MAIAHooksArgs); +#define REGISTER_MAIA_HOOKS(clsname) \ + C10_REGISTER_CLASS(MAIAHooksRegistry, clsname, clsname) + +namespace detail { +TORCH_API const MAIAHooksInterface& getMAIAHooks(); +} // namespace detail + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/MPSHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/MPSHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..01d6281e8afe028a77cde61aa986782acecdc3df --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/MPSHooksInterface.h @@ -0,0 +1,122 @@ +// Copyright © 2022 Apple Inc. + +#pragma once + +#include + +#include +#include +#include + +#include + +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Wunused-parameter") +namespace at { + +struct TORCH_API MPSHooksInterface : AcceleratorHooksInterface { + // this fails the implementation if MPSHooks functions are called, but + // MPS backend is not present. + #define FAIL_MPSHOOKS_FUNC(func) \ + TORCH_CHECK(false, "Cannot execute ", func, "() without MPS backend."); + + ~MPSHooksInterface() override = default; + + // Initialize the MPS library state + void init() const override { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual bool hasMPS() const { + return false; + } + virtual bool isOnMacOSorNewer(unsigned major = 13, unsigned minor = 0) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + const Generator& getDefaultGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const override { + FAIL_MPSHOOKS_FUNC(__func__); + } + Generator getNewGenerator( + [[maybe_unused]] DeviceIndex device_index) const override { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual Allocator* getMPSDeviceAllocator() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void deviceSynchronize() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void commitStream() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void* getCommandBuffer() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void* getDispatchQueue() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void emptyCache() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual size_t getCurrentAllocatedMemory() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual size_t getDriverAllocatedMemory() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual size_t getRecommendedMaxMemory() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void setMemoryFraction(double /*ratio*/) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void profilerStartTrace(const std::string& mode, bool waitUntilCompleted) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void profilerStopTrace() const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual uint32_t acquireEvent(bool enable_timing) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void releaseEvent(uint32_t event_id) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void recordEvent(uint32_t event_id) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void waitForEvent(uint32_t event_id) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual void synchronizeEvent(uint32_t event_id) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual bool queryEvent(uint32_t event_id) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + virtual double elapsedTimeOfEvents(uint32_t start_event_id, uint32_t end_event_id) const { + FAIL_MPSHOOKS_FUNC(__func__); + } + bool hasPrimaryContext(DeviceIndex device_index) const override { + FAIL_MPSHOOKS_FUNC(__func__); + } + bool isPinnedPtr(const void* data) const override { + return false; + } + Allocator* getPinnedMemoryAllocator() const override { + FAIL_MPSHOOKS_FUNC(__func__); + } + #undef FAIL_MPSHOOKS_FUNC +}; + +struct TORCH_API MPSHooksArgs {}; + +TORCH_DECLARE_REGISTRY(MPSHooksRegistry, MPSHooksInterface, MPSHooksArgs); +#define REGISTER_MPS_HOOKS(clsname) \ + C10_REGISTER_CLASS(MPSHooksRegistry, clsname, clsname) + +namespace detail { +TORCH_API const MPSHooksInterface& getMPSHooks(); + +} // namespace detail +} // namespace at +C10_DIAGNOSTIC_POP() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/MTIAHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/MTIAHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..b69e0027ea133cca0d33419bd27297add697ce17 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/MTIAHooksInterface.h @@ -0,0 +1,152 @@ +#pragma once + +#include +#include + +#include +#include + +#include + +#include +#include + +#include +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Wunused-parameter") +namespace at { +class Context; +} + +namespace at { +constexpr const char* MTIA_HELP = + "The MTIA backend requires MTIA extension for PyTorch;" + "this error has occurred because you are trying " + "to use some MTIA's functionality without MTIA extension included."; + +struct TORCH_API MTIAHooksInterface : AcceleratorHooksInterface { +// this fails the implementation if MTIAHooks functions are called, but +// MTIA backend is not present. +#define FAIL_MTIAHOOKS_FUNC(func) \ + TORCH_CHECK(false, "Cannot execute ", func, "() without MTIA backend."); + + ~MTIAHooksInterface() override = default; + + void init() const override { + // Avoid logging here, since MTIA needs init devices first then it will know + // how many devices are available. Make it as no-op if mtia extension is not + // dynamically loaded. + return; + } + + virtual bool hasMTIA() const { + return false; + } + + DeviceIndex deviceCount() const override { + return 0; + } + + virtual void deviceSynchronize(c10::DeviceIndex device_index) const { + FAIL_MTIAHOOKS_FUNC(__func__); + } + + virtual std::string showConfig() const { + FAIL_MTIAHOOKS_FUNC(__func__); + } + + bool hasPrimaryContext(DeviceIndex device_index) const override { + return false; + } + + void setCurrentDevice(DeviceIndex device) const override { + FAIL_MTIAHOOKS_FUNC(__func__); + } + + DeviceIndex getCurrentDevice() const override { + FAIL_MTIAHOOKS_FUNC(__func__); + return -1; + } + + DeviceIndex exchangeDevice(DeviceIndex device) const override { + FAIL_MTIAHOOKS_FUNC(__func__); + return -1; + } + + DeviceIndex maybeExchangeDevice(DeviceIndex device) const override { + FAIL_MTIAHOOKS_FUNC(__func__); + return -1; + } + + virtual c10::Stream getCurrentStream(DeviceIndex device) const { + FAIL_MTIAHOOKS_FUNC(__func__); + return c10::Stream::unpack3(-1, 0, c10::DeviceType::MTIA); + } + + virtual c10::Stream getDefaultStream(DeviceIndex device) const { + FAIL_MTIAHOOKS_FUNC(__func__); + return c10::Stream::unpack3(-1, 0, c10::DeviceType::MTIA); + } + + virtual void setCurrentStream(const c10::Stream& stream) const { + FAIL_MTIAHOOKS_FUNC(__func__); + } + + bool isPinnedPtr(const void* data) const override { + return false; + } + + Allocator* getPinnedMemoryAllocator() const override { + FAIL_MTIAHOOKS_FUNC(__func__); + return nullptr; + } + + virtual PyObject* memoryStats(DeviceIndex device) const { + FAIL_MTIAHOOKS_FUNC(__func__); + return nullptr; + } + + virtual PyObject* getDeviceCapability(DeviceIndex device) const { + FAIL_MTIAHOOKS_FUNC(__func__); + return nullptr; + } + + virtual void emptyCache() const { + FAIL_MTIAHOOKS_FUNC(__func__); + } + + + virtual void recordMemoryHistory( + const std::optional& enabled, + const std::string& stacks, + size_t max_entries) const { + FAIL_MTIAHOOKS_FUNC(__func__); + } + + virtual PyObject* memorySnapshot() const { + FAIL_MTIAHOOKS_FUNC(__func__); + return nullptr; + } + + virtual DeviceIndex getDeviceCount() const { + FAIL_MTIAHOOKS_FUNC(__func__); + return 0; + } + + virtual void resetPeakMemoryStats(DeviceIndex device) const { + FAIL_MTIAHOOKS_FUNC(__func__); + } + +}; + +struct TORCH_API MTIAHooksArgs {}; + +TORCH_DECLARE_REGISTRY(MTIAHooksRegistry, MTIAHooksInterface, MTIAHooksArgs); +#define REGISTER_MTIA_HOOKS(clsname) \ + C10_REGISTER_CLASS(MTIAHooksRegistry, clsname, clsname) + +namespace detail { +TORCH_API const MTIAHooksInterface& getMTIAHooks(); +TORCH_API bool isMTIAHooksBuilt(); +} // namespace detail +} // namespace at +C10_DIAGNOSTIC_POP() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/PrivateUse1HooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/PrivateUse1HooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..69819c76426041fcdb5368235afcf4d82700f4d0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/PrivateUse1HooksInterface.h @@ -0,0 +1,81 @@ +#pragma once + +#include +#include + +#include +#include +#include +#include + +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Wunused-parameter") + +namespace at { + +struct TORCH_API PrivateUse1HooksInterface : AcceleratorHooksInterface { +#define FAIL_PRIVATEUSE1HOOKS_FUNC(func) \ + TORCH_CHECK_NOT_IMPLEMENTED( \ + false, \ + "You should register `PrivateUse1HooksInterface`", \ + "by `RegisterPrivateUse1HooksInterface` and implement `", \ + func, \ + "` at the same time for PrivateUse1."); + + ~PrivateUse1HooksInterface() override = default; + + const at::Generator& getDefaultGenerator( + c10::DeviceIndex device_index) const override { + FAIL_PRIVATEUSE1HOOKS_FUNC(__func__); + } + + Generator getNewGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const override { + // TODO(FFFrog): Perserved for BC and will be removed in the future. + if (at::GetGeneratorPrivate().has_value()) + return at::GetGeneratorForPrivateuse1(device_index); + + FAIL_PRIVATEUSE1HOOKS_FUNC(__func__); + } + + at::Device getDeviceFromPtr(void* data) const override { + FAIL_PRIVATEUSE1HOOKS_FUNC(__func__); + } + + bool isPinnedPtr(const void* data) const override { + return false; + } + + Allocator* getPinnedMemoryAllocator() const override { + FAIL_PRIVATEUSE1HOOKS_FUNC(__func__); + } + + bool hasPrimaryContext(DeviceIndex device_index) const override { + FAIL_PRIVATEUSE1HOOKS_FUNC(__func__); + } + + void init() const override {} + virtual void resizePrivateUse1Bytes( + const c10::Storage& storage, + size_t newsize) const { + FAIL_PRIVATEUSE1HOOKS_FUNC(__func__); + } + +#undef FAIL_PRIVATEUSE1HOOKS_FUNC +}; + +struct TORCH_API PrivateUse1HooksArgs {}; + +TORCH_API void RegisterPrivateUse1HooksInterface( + at::PrivateUse1HooksInterface* hook_); + +TORCH_API bool isPrivateUse1HooksRegistered(); + +namespace detail { + +TORCH_API const at::PrivateUse1HooksInterface& getPrivateUse1Hooks(); + +} // namespace detail + +} // namespace at + +C10_DIAGNOSTIC_POP() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/XPUHooksInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/XPUHooksInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..5d31acbce170a61751901c91e6b1c346b611e83d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/detail/XPUHooksInterface.h @@ -0,0 +1,84 @@ +#pragma once + +#include +#include +#include + +#include + +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Wunused-parameter") + +namespace at { + +struct TORCH_API XPUHooksInterface : AcceleratorHooksInterface{ + ~XPUHooksInterface() override = default; + + void init() const override { + TORCH_CHECK(false, "Cannot initialize XPU without ATen_xpu library."); + } + + virtual bool hasXPU() const { + return false; + } + + virtual std::string showConfig() const { + TORCH_CHECK( + false, + "Cannot query detailed XPU version without ATen_xpu library."); + } + + virtual int32_t getGlobalIdxFromDevice(const Device& device) const { + TORCH_CHECK(false, "Cannot get XPU global device index without ATen_xpu library."); + } + + const Generator& getDefaultGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const override { + TORCH_CHECK( + false, "Cannot get default XPU generator without ATen_xpu library."); + } + + Generator getNewGenerator( + [[maybe_unused]] DeviceIndex device_index = -1) const override { + TORCH_CHECK(false, "Cannot get XPU generator without ATen_xpu library."); + } + + virtual DeviceIndex getNumGPUs() const { + return 0; + } + + virtual DeviceIndex current_device() const { + TORCH_CHECK(false, "Cannot get current device on XPU without ATen_xpu library."); + } + + Device getDeviceFromPtr(void* /*data*/) const override { + TORCH_CHECK(false, "Cannot get device of pointer on XPU without ATen_xpu library."); + } + + virtual void deviceSynchronize(DeviceIndex /*device_index*/) const { + TORCH_CHECK(false, "Cannot synchronize XPU device without ATen_xpu library."); + } + + Allocator* getPinnedMemoryAllocator() const override { + TORCH_CHECK(false, "Cannot get XPU pinned memory allocator without ATen_xpu library."); + } + + bool isPinnedPtr(const void* data) const override { + return false; + } + + bool hasPrimaryContext(DeviceIndex device_index) const override { + TORCH_CHECK(false, "Cannot query primary context without ATen_xpu library."); + } +}; + +struct TORCH_API XPUHooksArgs {}; + +TORCH_DECLARE_REGISTRY(XPUHooksRegistry, XPUHooksInterface, XPUHooksArgs); +#define REGISTER_XPU_HOOKS(clsname) \ + C10_REGISTER_CLASS(XPUHooksRegistry, clsname, clsname) + +namespace detail { +TORCH_API const XPUHooksInterface& getXPUHooks(); +} // namespace detail +} // namespace at +C10_DIAGNOSTIC_POP() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/ADInterpreters.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/ADInterpreters.h new file mode 100644 index 0000000000000000000000000000000000000000..ceca44832179dbd3102402696a972de11ca88016 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/ADInterpreters.h @@ -0,0 +1,38 @@ +#pragma once +#include + +namespace at::functorch { + +// These are the interpreters for our AD transforms +// (grad, vjp and jvp). +// See NOTE: [functorch interpreter stack] for more details. + +struct TORCH_API GradInterpreterPtr { + explicit GradInterpreterPtr(const Interpreter* base): base_(base) { TORCH_INTERNAL_ASSERT(base->key() == TransformType::Grad); } + TransformType key() const { return base_->key(); } + int64_t level() const { return base_->level(); } + void processImpl(const c10::OperatorHandle& op, torch::jit::Stack* stack); + void sendToNextInterpreterImpl(const c10::OperatorHandle& op, torch::jit::Stack* stack, bool grad_special_case); + bool prevGradMode() const { + return std::get(base_->meta()).prevGradMode_; + } + Tensor lift(const Tensor& tensor) const; + private: + const Interpreter* base_; +}; + +struct TORCH_API JvpInterpreterPtr { + explicit JvpInterpreterPtr(const Interpreter* base): base_(base) { TORCH_INTERNAL_ASSERT(base->key() == TransformType::Jvp); } + TransformType key() const { return base_->key(); } + int64_t level() const { return base_->level(); } + void processImpl(const c10::OperatorHandle& op, torch::jit::Stack* stack); + void sendToNextInterpreterImpl(const c10::OperatorHandle& op, torch::jit::Stack* stack, bool grad_special_case); + bool prevFwdGradMode() const { + return std::get(base_->meta()).prevFwdGradMode_; + } + Tensor lift(const Tensor& tensor) const; + private: + const Interpreter* base_; +}; + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchRulesHelper.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchRulesHelper.h new file mode 100644 index 0000000000000000000000000000000000000000..70fbf3135a3ca8e32b03ce6481dc1781d779cb0c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchRulesHelper.h @@ -0,0 +1,481 @@ +// Copyright (c) Facebook, Inc. and its affiliates. +// All rights reserved. +// +// This source code is licensed under the BSD-style license found in the +// LICENSE file in the root directory of this source tree. +#pragma once + +#include + +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include + +#include + +// This file contains helper functions for batching rules. + +namespace at::functorch { + +TORCH_API Tensor reshape_dim_into(int64_t src, int64_t dst, const Tensor& x); +TORCH_API Tensor reshape_dim_outof(int64_t src, int64_t size1, const Tensor& x); + +TORCH_API Tensor reshape_dim_outof_symint(int64_t src, const c10::SymInt& size1, const Tensor& x); + +Tensor moveBatchDimToFront(Tensor tensor, std::optional maybe_batch_dim); +int64_t rankWithoutBatchDim(const Tensor& tensor, std::optional maybe_batch_dim); +int64_t numelWithoutBatchDim(const Tensor& tensor, std::optional maybe_batch_dim); +std::optional valIfNonempty(std::optional maybe_empty, int64_t new_val); +int64_t getPhysicalDim(const Tensor& tensor, bool has_batch_dim, int64_t logical_dim); +VmapDimVector getPhysicalDims(const Tensor& tensor, bool has_batch_dim, IntArrayRef logical_dims); + +void vmapIncompatibleInplaceError(const char* schema_name); + +Tensor maybePadToLogicalRank(const Tensor& tensor, std::optional has_bdim, int64_t logical_rank); + +void check_randomness(RandomnessType randomness); +void check_randomness(RandomnessType randomness, bool any_tensor_bdim); + +inline Tensor ensure_has_bdim(const Tensor& tensor, bool has_bdim, c10::SymInt batch_size) { + if (has_bdim) { + return tensor; + } + const auto sizes = tensor.sym_sizes(); + SymDimVector expanded_shape; + expanded_shape.reserve(sizes.size()); + expanded_shape.emplace_back(std::move(batch_size)); + expanded_shape.insert(expanded_shape.end(), sizes.begin(), sizes.end()); + return tensor.expand_symint(expanded_shape); +} + +#define VMAP_SUPPORT(op, batch_rule) \ + m.impl(#op, op ## _generated_plumbing); + +#define VMAP_SUPPORT2(op, overload, batch_rule) \ + m.impl(#op "." #overload, op ## _ ## overload ## _generated_plumbing); + +#define OP_DECOMPOSE(op) m.impl(#op, static_cast(native::op)); +#define OP_DECOMPOSE2(op, overload) m.impl(#op"."#overload, static_cast(native::op)); + +// DO NOT USE ME DIRECTLY! Use BASIC_UNARY_BATCH_RULE to save yourself some pain +template +struct BasicUnaryBatchRuleHelper; + +template +struct BasicUnaryBatchRuleHelper> { + static std::tuple> apply( + const Tensor& tensor, + std::optional batch_dim, + T... extra_args) { + return std::make_tuple(Func(tensor, std::forward(extra_args)...), batch_dim); + } +}; + +// USAGE: BASIC_UNARY_BATCH_RULE(at::sin) +// INCORRECT USAGE: BASIC_UNARY_BATCH_RULE(&at::sin) +// It is important that this macro is not passed a function pointer!! +#define BASIC_UNARY_BATCH_RULE(fn) SINGLE_ARG(\ + BasicUnaryBatchRuleHelper<\ + decltype(&fn),\ + &fn,\ + c10::guts::function_traits::parameter_types>::apply) + +#define UNARY_POINTWISE(op) \ + VMAP_SUPPORT(op, BASIC_UNARY_BATCH_RULE(ATEN_FN(op))); + +template +struct VariadicBdimsBatchRuleHelper; + +template +struct VariadicBdimsBatchRuleHelper> { + static std::tuple> apply( + const Tensor& tensor, + std::optional batch_dim, + T... extra_args) { + auto tensor_ = moveBatchDimToFront(tensor, batch_dim); + return std::make_tuple(Func(tensor_, std::forward(extra_args)...), 0); + } +}; + +// USAGE: VARIADIC_BDIMS_BATCH_RULE(at::cholesky_inverse) +// INCORRECT USAGE: VARIADIC_BDIMS_BATCH_RULE(&at::cholesky_inverse) +// It is important that this macro is not passed a function pointer!! +#define VARIADIC_BDIMS_BATCH_RULE(fn) SINGLE_ARG(\ + VariadicBdimsBatchRuleHelper<\ + decltype(&fn),\ + &fn,\ + c10::guts::function_traits::parameter_types>::apply) + +#define VARIADIC_BDIMS(op) \ + VMAP_SUPPORT(op, VARIADIC_BDIMS_BATCH_RULE(ATEN_FN(op))); + +#define VARIADIC_BDIMS2(op, overload) \ + VMAP_SUPPORT2(op, overload, VARIADIC_BDIMS_BATCH_RULE(ATEN_FN2(op, overload))); + +template +void boxed_tensor_inputs_batch_rule(const c10::OperatorHandle& op, torch::jit::Stack* stack) { + const auto& schema = op.schema(); + const auto num_returns = schema.returns().size(); + const auto num_arguments = schema.arguments().size(); + + c10::impl::ExcludeDispatchKeyGuard guard(DispatchKey::FuncTorchBatched); + auto maybe_layer = maybeCurrentDynamicLayer(); + vmap_check_escaped(maybe_layer, "boxed_tensor_inputs_batch_rule"); + + int64_t cur_level = maybe_layer->layerId(); + + auto orig_arguments = torch::jit::last(*stack, num_arguments); + if (std::none_of(orig_arguments.begin(), orig_arguments.end(), ivalueParticipatesInCurrentLevel)) { + op.callBoxed(stack); + return; + } + + auto arguments = torch::jit::pop(*stack, num_arguments); + std::vector>> tensor_inputs; + std::vector tensor_pos; + for (const auto idx : c10::irange(0, num_arguments)) { + const auto& ivalue = arguments[idx]; + if (ivalue.isTensor()) { + auto [tensor_value, tensor_bdim] = unwrapTensorAtLevel(ivalue.toTensor(), cur_level); + tensor_inputs.emplace_back(std::move(tensor_value), tensor_bdim); + tensor_pos.push_back(static_cast(idx)); + } + } + Func(tensor_inputs); + + size_t tensor_idx = 0; + TORCH_INTERNAL_ASSERT(!tensor_pos.empty()); + for (const auto arg_idx : c10::irange(0, num_arguments)) { + if (tensor_idx >= tensor_pos.size() || (int64_t)arg_idx != tensor_pos[tensor_idx]) { + torch::jit::push(stack, arguments[arg_idx]); + } else { + TORCH_INTERNAL_ASSERT(tensor_idx < tensor_inputs.size()); + torch::jit::push(stack, tensor_inputs[tensor_idx].first); + tensor_idx++; + } + } + + op.callBoxed(stack); + const auto returns = torch::jit::pop(*stack, num_returns); + for (const auto& ret : returns) { + if (ret.isTensor()) { + torch::jit::push(stack, makeBatched(ret.toTensor(), 0, cur_level)); + } else { + TORCH_INTERNAL_ASSERT(false, "This boxed batching rule does not currently support ops that return non-tensor values"); + } + } +} + +inline void handle_pointwise_ops(std::vector>> &tensor_inputs) { + int64_t out_logical_rank = 0; + for (auto& tensor_input : tensor_inputs) { + int64_t cur_logical_rank = rankWithoutBatchDim(tensor_input.first, tensor_input.second); + out_logical_rank = std::max(out_logical_rank, cur_logical_rank); + } + for (auto& tensor_input: tensor_inputs) { + tensor_input.first = moveBatchDimToFront(tensor_input.first, tensor_input.second); + tensor_input.first = maybePadToLogicalRank(tensor_input.first, tensor_input.second, out_logical_rank); + } +} + +#define POINTWISE_BOXED(op) \ + m.impl(#op, torch::CppFunction::makeFromBoxedFunction>()); + +#define POINTWISE_BOXED2(op, overload) \ + m.impl(#op "." #overload, torch::CppFunction::makeFromBoxedFunction>()); + +inline void handle_variadic_bdims(std::vector>> &tensor_inputs) { + for (auto & tensor_input : tensor_inputs) { + tensor_input.first = moveBatchDimToFront(tensor_input.first, tensor_input.second); + } +} + +#define VARIADIC_BDIMS_BOXED(op) \ + m.impl(#op, torch::CppFunction::makeFromBoxedFunction>()); + +using UnpackedBatchedTensor = std::tuple>; + +inline void find_and_unpack_tensors( + const torch::jit::Stack* stack, + int64_t num_args, + int64_t cur_level, + SmallVector* tensors, + SmallVector* tensors_pos, + int64_t* batch_size) { + + int64_t computed_batch_size = -1; + int64_t args_begin = static_cast(stack->size()) - num_args; + + for (const auto idx : c10::irange(0, num_args)) { + const auto& ivalue = (*stack)[args_begin + idx]; + if (!ivalue.isTensor()) { + continue; + } + auto unpacked = unwrapTensorAtLevel(ivalue.toTensor(), cur_level); + const auto& [tensor_value, tensor_bdim] = unpacked; + if (tensor_bdim.has_value()) { + auto candidate_batch_size = tensor_value.size(*tensor_bdim); + if (computed_batch_size == -1) { + computed_batch_size = candidate_batch_size; + } + TORCH_INTERNAL_ASSERT(candidate_batch_size == computed_batch_size); + } + + tensors->push_back(std::move(unpacked)); + tensors_pos->push_back(idx); + } + TORCH_INTERNAL_ASSERT(computed_batch_size > -1); + *batch_size = computed_batch_size; +} + +inline void boxed_existing_bdim_all_batch_rule( + const c10::OperatorHandle& op, torch::jit::Stack* stack) { + const auto& schema = op.schema(); + const auto num_returns = schema.returns().size(); + const auto num_arguments = static_cast(schema.arguments().size()); + + c10::impl::ExcludeDispatchKeyGuard guard(DispatchKey::FuncTorchBatched); + const auto maybe_layer = maybeCurrentDynamicLayer(); + vmap_check_escaped(maybe_layer, "boxed_existing_bdim_all_batch_rule"); + + const auto arguments = torch::jit::last(stack, num_arguments); + if (std::none_of(arguments.begin(), arguments.end(), ivalueParticipatesInCurrentLevel)) { + op.callBoxed(stack); + return; + } + + int64_t args_begin = static_cast(stack->size()) - num_arguments; + SmallVector tensor_inputs; + SmallVector tensor_pos; + int64_t batch_size = 0; + // NOLINTNEXTLINE(bugprone-unchecked-optional-access) + int64_t cur_level = maybe_layer->layerId(); + + find_and_unpack_tensors( + stack, num_arguments, cur_level, + &tensor_inputs, &tensor_pos, &batch_size); + + // for each tensor, ensure it has a bdim and reshape it. + for (const auto tensor_idx : c10::irange(0, tensor_inputs.size())) { + const auto& [value, bdim] = tensor_inputs[tensor_idx]; + auto value_ = ensure_has_bdim(value, bdim.has_value(), batch_size); + (*stack)[args_begin + tensor_pos[tensor_idx]] = reshape_dim_into(bdim.value_or(0), 0, value_); + } + + op.callBoxed(stack); + + for (const auto idx : c10::irange(args_begin, args_begin + num_returns)) { + const auto& ret = (*stack)[idx]; + TORCH_INTERNAL_ASSERT(ret.isTensor(), + "This boxed batching rule does not currently support ops that return non-tensor values"); + (*stack)[idx] = makeBatched(reshape_dim_outof(0, batch_size, ret.toTensor()), 0, cur_level); + } +} + +// Use when all tensors arguments accept one (normal) batch dim. +// This batching rule expands the batch dim on all Tensors, reshapes it into +// dim 0, calls the op, and then reshapes the batch dim out of dim 0. +// This is not the most efficient thing; if there are alternatives, plese try +// to use them. Use this only as a last resort. +#define EXISTING_BDIM_ALL_BOXED(op) \ + m.impl(#op, torch::CppFunction::makeFromBoxedFunction()); + +template +inline void boxed_all_tensors_have_optional_bdim( + const c10::OperatorHandle& op, torch::jit::Stack* stack) { + const auto& schema = op.schema(); + const auto num_returns = schema.returns().size(); + const auto num_arguments = schema.arguments().size(); + + c10::impl::ExcludeDispatchKeyGuard guard(DispatchKey::FuncTorchBatched); + auto maybe_layer = maybeCurrentDynamicLayer(); + vmap_check_escaped(maybe_layer, "boxed_all_tensors_have_optional_bdim"); + int64_t cur_level = maybe_layer->layerId(); + + const auto arguments = torch::jit::last(stack, num_arguments); + if (std::none_of(arguments.begin(), arguments.end(), ivalueParticipatesInCurrentLevel)) { + op.callBoxed(stack); + return; + } + + int64_t args_begin = static_cast(stack->size() - num_arguments); + SmallVector tensor_inputs; + SmallVector tensor_pos; + int64_t batch_size = 0; + + find_and_unpack_tensors( + stack, static_cast(num_arguments), cur_level, + &tensor_inputs, &tensor_pos, &batch_size); + + std::optional is_no_batch_dim_case; + + for (const auto tensor_idx : c10::irange(0, tensor_inputs.size())) { + const auto& value = std::get<0>(tensor_inputs[tensor_idx]); + auto bdim = std::get<1>(tensor_inputs[tensor_idx]); + const auto logical_rank = rankWithoutBatchDim(value, bdim); + + if (!is_no_batch_dim_case.has_value()) { + is_no_batch_dim_case = (logical_rank == feature_rank); + } + auto value_ = ensure_has_bdim(value, bdim.has_value(), batch_size); + if (!bdim.has_value()) { + bdim = 0; + } + if (*is_no_batch_dim_case) { + TORCH_INTERNAL_ASSERT(logical_rank == feature_rank); + value_ = moveBatchDimToFront(value_, bdim); + if (tensor_idx == contig_tensor_index) { + value_ = value_.contiguous(); + } + (*stack)[args_begin + tensor_pos[tensor_idx]] = std::move(value_); + continue; + } + TORCH_INTERNAL_ASSERT(logical_rank == feature_rank + 1); + value_ = reshape_dim_into(*bdim, 0, value_); + if (tensor_idx == contig_tensor_index) { + value_ = value_.contiguous(); + } + (*stack)[args_begin + tensor_pos[tensor_idx]] = std::move(value_); + } + + op.callBoxed(stack); + + for (const auto idx : c10::irange(args_begin, args_begin + num_returns)) { + const auto& ret = (*stack)[idx]; + TORCH_INTERNAL_ASSERT(ret.isTensor(), + "This boxed batching rule does not currently support ops that return non-tensor values"); + if (*is_no_batch_dim_case) { + (*stack)[idx] = makeBatched(ret.toTensor(), 0, cur_level); + } else { + (*stack)[idx] = makeBatched(reshape_dim_outof(0, batch_size, ret.toTensor()), 0, cur_level); + } + } +} + +// Useful for many NN operators. +// The operator must satisfy the following: +// - All arguments must accept an optional batch dim. +// - All arguments must be the same rank +#define ALL_TENSORS_HAVE_OPTIONAL_BDIM_BOXED(feature_rank, op) \ + m.impl(#op, torch::CppFunction::makeFromBoxedFunction>()); + +#define ALL_TENSORS_HAVE_OPTIONAL_BDIM_BOXED_CONTIG1(feature_rank, op, contig_tensor_index) \ + m.impl(#op, \ + torch::CppFunction::makeFromBoxedFunction<\ + boxed_all_tensors_have_optional_bdim<\ + feature_rank, \ + contig_tensor_index>\ + >()); + +template +struct ExistingBdimBatchRuleHelper; + +template +struct ExistingBdimBatchRuleHelper> { + static std::tuple> apply( + const Tensor& self, + std::optional self_bdim, + T... extra_args) { + auto self_ = reshape_dim_into(*self_bdim, 0, self); + auto out = Func(self_, std::forward(extra_args)...); + return std::make_tuple(reshape_dim_outof_symint(0, self.sym_sizes()[*self_bdim], out), 0); + } +}; + +// USAGE: EXISTING_BDIM_BATCH_RULE(at::cholesky_inverse) +// INCORRECT USAGE: EXISTING_BDIM_BATCH_RULE(&at::cholesky_inverse) +// It is important that this macro is not passed a function pointer!! +#define EXISTING_BDIM_BATCH_RULE(fn) SINGLE_ARG(\ + ExistingBdimBatchRuleHelper<\ + decltype(&fn),\ + &fn,\ + c10::guts::function_traits::parameter_types>::apply) + + +#define EXISTING_BDIM(op) \ + VMAP_SUPPORT(op, EXISTING_BDIM_BATCH_RULE(ATEN_FN(op))); + +#define EXISTING_BDIM2(op, overload) \ + VMAP_SUPPORT2(op, overload, EXISTING_BDIM_BATCH_RULE(ATEN_FN2(op, overload))); + +#define INVOKE(object,ptrToMember) ((object).*(ptrToMember)) + + +template +Tensor& unary_inplace_batch_rule(Tensor& self, std::optional, ExtraArgs... extra_args) { + INVOKE(self, Method)(std::forward(extra_args)...); + return self; +} + +inline int64_t get_bdim_size4( + const Tensor& a_value, std::optional a_bdim, + const Tensor& b_value, std::optional b_bdim, + const Tensor& c_value, std::optional c_bdim, + const Tensor& d_value, std::optional d_bdim) { + if (a_bdim) + return a_value.size(*a_bdim); + if (b_bdim) + return b_value.size(*b_bdim); + if (c_bdim) + return c_value.size(*c_bdim); + if (d_bdim) + return d_value.size(*d_bdim); + TORCH_INTERNAL_ASSERT(false); +} + +inline int64_t get_bdim_size3( + const Tensor& a_value, std::optional a_bdim, + const Tensor& b_value, std::optional b_bdim, + const Tensor& c_value, std::optional c_bdim) { + if (a_bdim) + return a_value.size(*a_bdim); + if (b_bdim) + return b_value.size(*b_bdim); + if (c_bdim) + return c_value.size(*c_bdim); + TORCH_INTERNAL_ASSERT(false); +} + +inline int64_t get_bdim_size2( + const Tensor& a_value, std::optional a_bdim, + const Tensor& b_value, std::optional b_bdim) { + if (a_bdim) + return a_value.size(*a_bdim); + if (b_bdim) + return b_value.size(*b_bdim); + TORCH_INTERNAL_ASSERT(false); +} + +inline c10::SymInt get_bdim_size2_symint( + const Tensor& a_value, std::optional a_bdim, + const Tensor& b_value, std::optional b_bdim) { + if (a_bdim) + return a_value.sym_size(*a_bdim); + if (b_bdim) + return b_value.sym_size(*b_bdim); + TORCH_INTERNAL_ASSERT(false); +} + +// [start, start + 1, ..., stop - 1] +inline VmapDimVector range(int64_t start, int64_t stop) { + TORCH_INTERNAL_ASSERT(stop >= start); + VmapDimVector dims; + dims.reserve(stop - start); + for (int64_t i = start; i < stop; i++) { + dims.emplace_back(i); + } + return dims; +} +std::tuple _binary_pointwise_helper( + const Tensor& tensor, std::optional tensor_batch_dim, const Tensor& other, std::optional other_batch_dim, + bool do_type_promotion=true); + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchedFallback.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchedFallback.h new file mode 100644 index 0000000000000000000000000000000000000000..f76191221a1e2b1a4d055c8a3e68945791c259df --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchedFallback.h @@ -0,0 +1,81 @@ +// Copyright (c) Facebook, Inc. and its affiliates. +// All rights reserved. +// +// This source code is licensed under the BSD-style license found in the +// LICENSE file in the root directory of this source tree. + +#pragma once +#include +#include +#include + +namespace at::functorch { + +// This file contains code for the vmap fallback (also known as the +// BatchedTensor fallback or the Batched fallback). This code runs +// when an operation doesn't have a batching rule implemented. + +// If an operator doesn't have a batching rule implemented then we fallback +// to this implementation. The fallback doesn't work on out= variants or +// view operations; that is, it works for out-of-place operations and +// in-place non-view operations. +// +// For out-of-place operations, the fallback effectively takes all of the +// BatchedTensors in `stack`, slices them, and runs `op` on all of the +// corresponding slices to produce slices of the outputs. The output slices +// then get `torch.stack`ed to create the +// final returns. +// +// The performance of the fallback is not very good because it introduces an +// extra copy from stacking the sliced outputs. Because of this, we prefer to +// write batching rules for operators whenever possible. +void batchedTensorForLoopFallback(const c10::OperatorHandle& op, torch::jit::Stack* stack); +void batchedNestedTensorForLoopFallback(const c10::OperatorHandle& op, torch::jit::Stack* stack); + +void vmapErrorFallback(const c10::OperatorHandle& op, torch::jit::Stack* stack); + +// The vmap fallback emits a warning by default, but it may be disabled if +// the user finds it to be too annoying. +TORCH_API bool isVmapFallbackWarningEnabled(); +TORCH_API void setVmapFallbackWarningEnabled(bool enabled); + +// Used for testing. The vmap fallback is enabled by default. When it is disabled, +// it raises an error. +TORCH_API bool isVmapFallbackEnabled(); +TORCH_API void setVmapFallbackEnabled(bool enabled); + +template A vector_to_result(const std::vector& buffer) { + return buffer[0].to(); +} +template std::tuple vector_to_result(const std::vector& buffer) { + return std::make_tuple(buffer[0].to(), buffer[1].to()); +} +template std::tuple vector_to_result(const std::vector& buffer) { + return std::make_tuple(buffer[0].to(), buffer[1].to(), buffer[2].to()); +} + +// slow_fallback is a way to call the vmap fallback inside some boxed kernel. +// There is probably some better way to metaprogram this. +template +Ret slow_fallback(const c10::OperatorHandle& op, ArrayRef args) { + std::vector stack(args.begin(), args.end()); + batchedTensorForLoopFallback(op, &stack); + return vector_to_result(stack); +} + +template +std::tuple slow_fallback(const c10::OperatorHandle& op, ArrayRef args) { + std::vector stack(args.begin(), args.end()); + batchedTensorForLoopFallback(op, &stack); + return vector_to_result(stack); +} + +template +std::tuple slow_fallback(const c10::OperatorHandle& op, ArrayRef args) { + std::vector stack(args.begin(), args.end()); + batchedTensorForLoopFallback(op, &stack); + return vector_to_result(stack); +} + + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchedTensorImpl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchedTensorImpl.h new file mode 100644 index 0000000000000000000000000000000000000000..e42f8dd87b50116e1866ebb0219ac1dedbe3c186 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchedTensorImpl.h @@ -0,0 +1,169 @@ +// Copyright (c) Facebook, Inc. and its affiliates. +// All rights reserved. +// +// This source code is licensed under the BSD-style license found in the +// LICENSE file in the root directory of this source tree. + +#pragma once + +#include + +#include +#include +#include + +namespace at::functorch { + +using Tensor = at::Tensor; + +// We assume this in a few other places in the codebase, +// but there isn't a centralized definition. +constexpr int64_t kVmapMaxTensorDims = 64; + +// The valid vmap levels range from [0, 64). This effectively means that we +// support a maximum of 64 nested vmaps. +constexpr int64_t kVmapNumLevels = 64; + +// Store this number of elements of BatchDims on the stack. Most people will +// probably use <= 5 nested vmaps, but adjust this number as necessary. +constexpr int64_t kBatchDimsStackSize = 5; + +// A BatchedTensorImpl holds an underlying Tensor and a single batch dim +// NB: We use the term "BatchedTensor" to mean a Tensor that is backed with a +// BatchedTensorImpl. +// +// The batch dimensions are treated as being "private"; they are not user-visible. +// For example, in the following Tensor, +// bt = BatchedTensorImpl(ones(2, 3, 5, 7), lvl=1, dim=0) +// dimension 0 is batch dimension. +// +// bt.sizes() returns (5, 7); bt.sum(0) performs a reduction over the (public) +// dim 0, which is equivalent to dim 3 in the underlying ones(2, 3, 5, 7) tensor. +struct TORCH_API BatchedTensorImpl : public c10::TensorImpl { + explicit BatchedTensorImpl(at::DispatchKeySet key_set, Tensor value, int64_t dim, int64_t level); + + // Returns batch dimension of this tensor + int64_t bdim() const { return bdim_; } + + // Returns batch dimension of this tensor + int64_t level() const { return level_; } + + // BatchedTensorImpl wraps a Tensor + const Tensor& value() const { return value_; } + + // Given a public dimension index, return the dimension index in the underlying + // value() tensor. + // For example, if we have + // bt = BatchedTensorImpl(ones(2, 3, 5, 7), lvl=1, dim=0) + // bt.actualDim(0) -> 1 + // bt.actualDim(1) -> 2 + // bt.actualDim(2) -> 3 + // bt.actualDim(3) -> Error + int64_t actualDim(int64_t dim, bool wrap_dim = true) const; + + IntArrayRef sizes_custom() const override; + SymIntArrayRef sym_sizes_custom() const override; + int64_t size_custom(int64_t d) const override; + c10::SymInt sym_size_custom(int64_t d) const override; + // We have to override this because we opted into CustomStrides + IntArrayRef strides_custom() const override; + SymIntArrayRef sym_strides_custom() const override; + // Override a bunch of methods inherited from TensorImpl to return error messages. + bool is_contiguous_custom(at::MemoryFormat memory_format=at::MemoryFormat::Contiguous) const override; + void set_size(int64_t dim, int64_t new_size) override; + void set_stride(int64_t dim, int64_t new_stride) override; + c10::intrusive_ptr shallow_copy_and_detach( + const c10::VariableVersion& version_counter, + bool allow_tensor_metadata_change) const override; + c10::intrusive_ptr shallow_copy_and_detach( + c10::VariableVersion&& version_counter, + bool allow_tensor_metadata_change) const override; + void shallow_copy_from(const c10::intrusive_ptr& impl) override; +#ifdef DEBUG + bool has_storage() const override; +#endif + + void refreshTensorMetadata(); + + // Used in torchdim. torchdim uses non-lexical BatchedTensor; the way it + // accomplishes this is a hack where it is able to modify the levels of + // BatchedTensor to match the level of the current vmap transform. + void _unsafe_set_level(int64_t level) { + level_ = level; + } + + // Used in batching rule for in-place view operations that can change + // the index of the bdim (think squeeze_, unsqueeze_) + void unsafe_set_bdim(int64_t bdim) { + // NB: you MUST call refreshTensorMetadata after doing this. + bdim_ = bdim; + } + private: + // see NOTE: [BatchedTensorImpl levels invariant] + void checkInvariants() const; + const char* tensorimpl_type_name() const override; + + Tensor value_; + + int64_t level_; + int64_t bdim_; +}; + +// NB: We use the term "BatchedTensor" to mean a Tensor that is backed with a +// BatchedTensorImpl. +inline bool isBatchedTensor(const Tensor& tensor) { + return tensor.unsafeGetTensorImpl()->key_set().has(DispatchKey::FuncTorchBatched) || + tensor.unsafeGetTensorImpl()->key_set().has(DispatchKey::BatchedNestedTensor); +} + +// It is unsafe to call this on a Tensor that is not backed by a +// BatchedTensorImpl. Please use `maybeGetBatchedImpl` whenever possible. +inline BatchedTensorImpl* unsafeGetBatchedImpl(const Tensor& tensor) { + return static_cast(tensor.unsafeGetTensorImpl()); +} + +inline BatchedTensorImpl* maybeGetBatchedImpl(const Tensor& tensor) { + if (!isBatchedTensor(tensor)) { + return nullptr; + } + return unsafeGetBatchedImpl(tensor); +} + +// Returns a bitset. If bit i is set, then that means dim i is a batchdim. +inline std::bitset createBatchDimBitset(int64_t dim) { + std::bitset is_bdim; + is_bdim.set(dim); + return is_bdim; +} + +// Creates a bitset for the given level +inline std::bitset createVmapLevelsBitset(int64_t level) { + std::bitset result; + result.set(level); + return result; +} + +// Use this to construct a BatchedTensor from a regular Tensor +TORCH_API Tensor makeBatched(Tensor tensor, int64_t dim, int64_t level); + +// Adds a batch dim to `tensor`, returning a BatchedTensor +TORCH_API Tensor addBatchDim(Tensor tensor, int64_t dim, int64_t level); + +// Certain dispatch keys must be propagated to the BatchedTensor (or, in general, +// any wrapper Tensor subclasses). This is because there are methods on Tensor +// that skip dispatch and check for the presence of a dispatch key (e.g. is_cpu()). +// TODO: should probably contain more (or all?) backend keys +constexpr DispatchKeySet kKeysToPropagateToWrapper({ + DispatchKey::Negative, + DispatchKey::Conjugate, + DispatchKey::XLA, + DispatchKey::CUDA, + DispatchKey::CPU, +}); + +inline DispatchKeySet getKeysToPropagateToWrapper(const Tensor& tensor, DispatchKeySet to_propagate=kKeysToPropagateToWrapper) { + auto key_set = tensor.unsafeGetTensorImpl()->key_set(); + return key_set & kKeysToPropagateToWrapper; +} + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchingMetaprogramming.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchingMetaprogramming.h new file mode 100644 index 0000000000000000000000000000000000000000..7b9c2aa151e9f11d4771a0ce52774c756497b17f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/BatchingMetaprogramming.h @@ -0,0 +1,126 @@ +// Copyright (c) Facebook, Inc. and its affiliates. +// All rights reserved. +// +// This source code is licensed under the BSD-style license found in the +// LICENSE file in the root directory of this source tree. + +#pragma once +#include +#include + +// This file contains template metaprogramming things that are used for our +// batching rules. +// +// See NOTE: [vmap plumbing] for more details on why this is necessary. +// The plumbing has a bunch of metaprogramming hacks for determining the signature +// of a batching rule from the signature of the operator, many of which use the +// helper functions in this file. + +namespace at::functorch { + +// Metaprogramming things +template using typelist = c10::guts::typelist::typelist; +template using head_t = c10::guts::typelist::head_t; +template using concat_t = c10::guts::typelist::concat_t; +template class debug_t; + +// tail operation +template +struct tail final { + static_assert(c10::guts::false_t::value, + "In typelist::tail, the T argument must be typelist<...>."); +}; +template +struct tail> final { + using type = typelist; +}; +template using tail_t = typename tail::type; + +template +struct IfFirstIsTensorAndSecondisBatchDimThenTailElseNext { + using type = Next; +}; +template +struct IfFirstIsTensorAndSecondisBatchDimThenTailElseNext, Next, Tail> { + using type = Tail; +}; +template +struct IfFirstIsTensorAndSecondisBatchDimThenTailElseNext, Next, Tail> { + using type = Tail; +}; +template +struct IfFirstIsTensorAndSecondisBatchDimThenTailElseNext, Next, Tail> { + using type = Tail; +}; +template +struct IfFirstIsTensorAndSecondisBatchDimThenTailElseNext, std::optional, Next, Tail> { + using type = Tail; +}; +template +struct IfFirstIsTensorAndSecondisBatchDimThenTailElseNext&, std::optional, Next, Tail> { + using type = Tail; +}; +template +struct IfFirstIsTensorAndSecondisBatchDimThenTailElseNext&, std::optional, Next, Tail> { + using type = Tail; +}; +template +struct IfFirstIsTensorAndSecondisBatchDimThenTailElseNext, std::optional, Next, Tail> { + using type = Tail; +}; +template struct RemoveBatchDimAfterTensor { + using first = head_t; + using next = tail_t; + using second = head_t; + using tail = tail_t; + + using type = concat_t< + typelist, + typename RemoveBatchDimAfterTensor< + typename IfFirstIsTensorAndSecondisBatchDimThenTailElseNext::type + >::type + >; +}; +template struct RemoveBatchDimAfterTensor> { + using type = typelist; +}; +template <> struct RemoveBatchDimAfterTensor> { + using type = typelist<>; +}; +template using remove_batch_dim_after_tensor_t = typename RemoveBatchDimAfterTensor::type; + +template struct UnpackSingleItemTuple { + using type = T; +}; +template struct UnpackSingleItemTuple> { + using type = T; +}; +template using unpack_single_item_tuple_t = typename UnpackSingleItemTuple::type; + +template struct BuildFunctionHelper; +template struct BuildFunctionHelper> { + using type = Return(Args...); +}; +template +struct BuildFunction { + using type = typename BuildFunctionHelper>::type; +}; +template using build_function_t = typename BuildFunction::type; + + +template struct ToOperatorType { + using batch_rule_return_type = typename c10::guts::function_traits::return_type; + using batch_rule_parameter_types = typename c10::guts::function_traits::parameter_types; + + using operator_parameter_types = remove_batch_dim_after_tensor_t; + using operator_return_type = + unpack_single_item_tuple_t< + c10::guts::typelist::to_tuple_t< + remove_batch_dim_after_tensor_t< + c10::guts::typelist::from_tuple_t>>>; + + using type = build_function_t; +}; +template using to_operator_t = typename ToOperatorType::type; + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/DynamicLayer.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/DynamicLayer.h new file mode 100644 index 0000000000000000000000000000000000000000..447df65550aa5fcda929354ca1a2ff5610232082 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/DynamicLayer.h @@ -0,0 +1,124 @@ +// Copyright (c) Facebook, Inc. and its affiliates. +// All rights reserved. +// +// This source code is licensed under the BSD-style license found in the +// LICENSE file in the root directory of this source tree. + +#pragma once +#include +#include +#include +#include +#include +#include +#include +#include +#include + +// Forward declared +namespace c10 { struct AutogradMetaInterface; } + +namespace at::functorch { + +// This file contains the implementation of functorch's interpreter stack. +// See NOTE: [functorch interpreter stack] first before reading on. +// +// NB: the functorch interpreter stack is also referred to as: +// - the "dynamic layer stack" -- an older name for "interpreter" was +// "dynamic layer". +// - the "functorch mode stack". You can think of each functorch transform as a +// "mode" (in the same sense as torch_dispatch mode or torch_function mode), +// and functorch being an implementation of a "mode stack" where the modes +// may be arbitrary composed. + +// DynamicLayer is basically the same thing as an Interpreter. +// It represents a functorch transform and it holds an Interpreter, +// which contains metadata related to the transform and instructions on +// how to perform the transform. +// +// TODO: we can excise DynamicLayer in favor of Interpreter, +// But I am going to leave it for now as a compatiblity shim to avoid +// needing to refactor a lot of callsites... +struct TORCH_API DynamicLayer { + explicit DynamicLayer( + TransformType transform_type, + int64_t layerId, + std::optional batchSize = std::nullopt, + std::optional randomness = std::nullopt, + std::optional prev_grad_mode = std::nullopt, + std::optional pre_fwd_grad_mode = std::nullopt, + std::optional functionalize_add_back_views = std::nullopt); + + TransformType key() const; + int64_t layerId() const; + + const Interpreter& interpreter() const { return interpreter_; } + Interpreter& interpreter() { return interpreter_; } + + // Only valid for vmap + c10::SymInt batchSize() const; + RandomnessType randomness() const; + + private: + Interpreter interpreter_; +}; + +TORCH_API int64_t initAndPushDynamicLayer( + TransformType transform_type, + std::optional batch_size = std::nullopt, + std::optional randomness = std::nullopt, + std::optional prev_grad_mode = std::nullopt, + std::optional prev_fwd_grad_mode = std::nullopt, + std::optional functionalize_add_back_views = std::nullopt); +TORCH_API DynamicLayer popDynamicLayerAndDeleteMetadata(); +TORCH_API std::optional maybeCurrentDynamicLayer(); +TORCH_API const std::vector& getDynamicLayerStack(); +TORCH_API void setDynamicLayerStack(const std::vector& stack); +TORCH_API void setDynamicLayerFrontBackKeysIncluded(bool included); + +// NOTE: [Life handles and lexically scoped transforms] +// functorch transforms are lexically scoped. +// Given a level, we store a "life handle" that is a boolean that tells us if the +// transform with that level is active or not. +// +// functorch's TensorWrapper (for grad transforms) stores a life handle. +// If a TensorWrapper escapes from the scope of the transform, then somehow +// it must know it escaped; it can tell by querying the life handle. +TORCH_API const std::shared_ptr& getLifeHandleForLevel(int64_t level); + +// Returns if an operator is in-place. An operator is inplace if: +// 1. The first argument is a Tensor and it is being written to +// 2. The first argument is being returned +// 3. No other arguments are aliased +// Here is an example of an in-place operator: +// add_(Tensor(a!) self, Tensor other, *, Scalar alpha=1) -> Tensor(a!) +TORCH_API bool isInplaceOp(const c10::FunctionSchema& schema); + +// Given the indices of unwrapped inputs and the schema, this returns the indices of any outputs that should remain unwrapped +TORCH_API std::optional findAliasedOutput(const FunctionSchema& schema, const int64_t immutable_input); + +TORCH_API Tensor unwrapIfDead(const Tensor& tensor); +TORCH_API bool isDeadTensorWrapper(const Tensor& tensor); + +// Pretty printers +TORCH_API std::ostream& operator<<(std::ostream& os, const DynamicLayer& layer); +TORCH_API std::ostream& operator<<(std::ostream& os, const std::vector& dynamicLayerStack); + +// While a functorch transform is active, torch.autograd.function._SingleLevelFunction +// is disabled by default. The following two APIs are APIs for enabling +// it. These are not user-facing APIs. We can delete this in the future, but +// it is useful for debugging when something goes wrong with the +// autograd.Function <> functorch interaction, which uses _SingleLevelFunction, +// because it leads to loud errors if something is incorrect. +TORCH_API void setSingleLevelAutogradFunctionAllowed(bool allowed); +TORCH_API bool getSingleLevelAutogradFunctionAllowed(); + +// While a functorch grad transform is active, Tensor.requires_grad_() gets +// disabled. These two functions are the mechanism to controlling that. +TORCH_API void setInplaceRequiresGradAllowed(bool allowed); +TORCH_API bool getInplaceRequiresGradAllowed(); + +TORCH_API DynamicLayer popDynamicLayer(); +TORCH_API int64_t pushDynamicLayer(DynamicLayer&& layer); + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/FunctionalizeInterpreter.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/FunctionalizeInterpreter.h new file mode 100644 index 0000000000000000000000000000000000000000..f07c1f4fdc012938702b3ef3cab43e1e2ea5c05c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/FunctionalizeInterpreter.h @@ -0,0 +1,22 @@ +#pragma once +#include + +namespace at::functorch { + +// This is the interpreter that handles the functionalize() transform. +// See NOTE: [functorch interpreter stack] for more details. + +struct FunctionalizeInterpreterPtr { + explicit FunctionalizeInterpreterPtr(const Interpreter* base): base_(base) { TORCH_INTERNAL_ASSERT(base->key() == TransformType::Functionalize); } + TransformType key() const { return base_->key(); } + int64_t level() const { return base_->level(); } + void processImpl(const c10::OperatorHandle& op, torch::jit::Stack* stack); + void sendToNextInterpreterImpl(const c10::OperatorHandle& op, torch::jit::Stack* stack, bool grad_special_case); + bool functionalizeAddBackViews() const { + return std::get(base_->meta()).functionalizeAddBackViews_; + } + private: + const Interpreter* base_; +}; + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/Interpreter.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/Interpreter.h new file mode 100644 index 0000000000000000000000000000000000000000..bdea11d3b2a0ddfc65c4a059bcdf476d713e52f5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/Interpreter.h @@ -0,0 +1,209 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include + +namespace at::functorch { + +// NOTE: [functorch interpreter stack] +// +// functorch's dispatching system uses a stack of interpreters. +// Historically we've referred to this as the "DynamicLayerStack". +// +// An interpreter is something that reads in the code it is passed +// and then executes it. We have a different interpreter per-transform: +// the "VmapInterpreter" is responsible for reading in operators (like aten::mv) +// and executing the batched version of it (the batching rule for aten::mv). +// +// Concretely, each interpreter is responsible for two things: +// +// 1) process(ophandle, stack) +// Given an operator handle and a stack of arguments, the interpreter is +// responsible for figuring out how to execute the operation under the semantics +// of the interpreter. For e.g. VmapInterpreter, this is figuring out how to call +// the batching rule. +// +// The batching rules are stored as kernels on the FuncTorchBatched key, so the way +// VmapInterpreter calls the batching rule is roughly: (A) exclude all +// dispatch keys aside from the Batched key, (B) redispatch so we get to the +// Batched key. +// +// 2) sendToNextInterpreter(ophandle, stack) +// The VmapInterpreter, when it sees aten::mv, will process it into a call to +// aten::mm. It then needs to send the call to aten::mm to the next interpreter +// in the interpreter stack. +// +// The VmapInterpreter just does this via a call to ophandle.callBoxed(stack) +// and most Interpreters will implement it this way. + +enum class RandomnessType { + Error, // always errors when calling a random function + Same, // randomness appears the same across batches + Different, // randomness appears different across batches + END +}; + +enum class TransformType { + Torch, // Unused + Vmap, + Grad, // reverse-mode AD, aka vjp + Jvp, // forward-mode AD + Functionalize, +}; + +std::ostream& operator<<(std::ostream& os, const TransformType& t); + +// NOTE: [Interpreter "subclassing" design] +// +// How are various Interpreters for different transforms (vmap, grad, ...) +// implemented? +// +// Accessing interpreters is in the hot-path of functorch so we have a constraint +// that this code must be as fast as possible. +// +// As a result, we stay away from virtual methods and this causes our code +// to look a little funny. +// +// `Interpreter` is the struct for Interpreters. It holds ALL of the +// relevant information (what type of interpreter it is and the metadata). +// Metadata for each interpreter is represented as a Union (std::variant) +// of all possible metadata (VmapInterpreterMeta, GradInterpreterMeta, ...). +// +// Given an Interpreter, how do I get a "VmapInterpreter"? You may wish to do this +// if you want to access the metadata fields (like batchSize and randomness). +// +// Each type of interpreter (e.g. Vmap) has a convenience struct +// (e.g. VmapInterpreterPtr) associated with it. +// +// Construct the convenience struct with VmapInterpreterPtr(Interpreter*), +// and then one can access methods on VmapInterpreterPtr like so: +// >>> VmapInterpreterPtr(&interpreter).batchSize() +// +// Finally, Interpreter::process switches on the type of the interpreter +// and calls one of {Transform}Intepreter::processImpl under the hood. +// Same for Interpreter::sendToNextInterpreter :) + +struct VmapInterpreterMeta { + explicit VmapInterpreterMeta(c10::SymInt batchSize, RandomnessType randomness) : + batchSize_(std::move(batchSize)), randomness_(randomness) {} + c10::SymInt batchSize_; + RandomnessType randomness_; +}; + +struct GradInterpreterMeta { + explicit GradInterpreterMeta(bool prevGradMode): prevGradMode_(prevGradMode) {} + bool prevGradMode_; +}; + +struct JvpInterpreterMeta { + explicit JvpInterpreterMeta(bool prevFwdGradMode) : prevFwdGradMode_(prevFwdGradMode) {} + bool prevFwdGradMode_; +}; + +struct FunctionalizeInterpreterMeta { + explicit FunctionalizeInterpreterMeta(bool functionalizeAddBackViews) : + functionalizeAddBackViews_(functionalizeAddBackViews) {} + bool functionalizeAddBackViews_; +}; + +typedef std::variant< + int64_t, + GradInterpreterMeta, + JvpInterpreterMeta, + VmapInterpreterMeta, + FunctionalizeInterpreterMeta +> InterpreterMeta; + + +struct Interpreter { + // factory functions + static Interpreter Vmap(int64_t level, c10::SymInt batchSize, RandomnessType randomness) { + return Interpreter(TransformType::Vmap, level, VmapInterpreterMeta(std::move(batchSize), randomness)); + } + static Interpreter Grad(int64_t level, bool prevGradMode) { + return Interpreter(TransformType::Grad, level, GradInterpreterMeta(prevGradMode)); + } + static Interpreter Jvp(int64_t level, bool prevFwdGradMode) { + return Interpreter(TransformType::Jvp, level, JvpInterpreterMeta(prevFwdGradMode)); + } + static Interpreter Functionalize(int64_t level, bool functionalizeAddBackViews) { + return Interpreter(TransformType::Functionalize, level, FunctionalizeInterpreterMeta(functionalizeAddBackViews)); + } + + // methods + TransformType key() const { return type_; } + int64_t level() const { return level_; } + const InterpreterMeta& meta() const { return meta_; } + + void process(const c10::OperatorHandle& op, torch::jit::Stack* stack); + void sendToNextInterpreter(const c10::OperatorHandle& op, torch::jit::Stack* stack, bool grad_special_case); + + void saveLocalDispatchKeySet(c10::impl::LocalDispatchKeySet keyset) { + TORCH_INTERNAL_ASSERT(!savedLocalDispatchKeySet_.has_value()); + savedLocalDispatchKeySet_ = keyset; + } + void clearSavedLocalDispatchKeySet() { + TORCH_INTERNAL_ASSERT(savedLocalDispatchKeySet_.has_value()); + savedLocalDispatchKeySet_ = std::nullopt; + } + c10::impl::LocalDispatchKeySet getSavedLocalDispatchKeySet() const { + TORCH_INTERNAL_ASSERT(savedLocalDispatchKeySet_.has_value()); + return *savedLocalDispatchKeySet_; + } + + // An Interpreter is alive if we are currently inside the ongoing transform + // for the interpreter. For example, vmap(f)(x); inside of f, the vmap's + // corresponding Interpreter is alive, even when it is not on the DynamicLayerStack. + bool is_alive() const { + return *is_alive_; + } + const std::shared_ptr& is_alive_ptr() const { + return is_alive_; + } + void set_is_alive(bool alive) { + *is_alive_ = alive; + } + + // Please don't use this + explicit Interpreter() = default; + + private: + explicit Interpreter(TransformType type, int64_t level, InterpreterMeta meta): + type_(type), level_(level), is_alive_(std::make_shared(false)), meta_(std::move(meta)) {} + + // fields + TransformType type_{}; + int64_t level_{}; + std::optional savedLocalDispatchKeySet_; + std::shared_ptr is_alive_; + InterpreterMeta meta_; +}; + +// Applies the following for-loop: +// for i in range(begin, end): +// args[i] = func(args[i]) +void foreachTensorInplace(std::vector& args, int64_t begin, int64_t end, + std::function func); + +// Applies the following for-loop: +// for i in range(begin, end): +// if use_flag_relative[i] == 1: <-- treats use_flag_relative as a bitset +// args[i] = func(args[i], i - begin, true) +// args[i] = func(args[i], i - begin) +void foreachTensorInplaceWithFlag(std::vector& args, int64_t begin, int64_t end, + const std::bitset<64> use_flag_relative, const std::function& func); + +std::vector findUnwrappedInputs(std::vector& args, int64_t begin, int64_t end); + +DispatchKeySet keysToExcludeWhenEnteringDynamicLayer(TransformType key); + +void setup_dispatch_key_tls(TransformType key, DispatchKeySet include); + +void sanityCheckStack(const c10::OperatorHandle& op, torch::jit::Stack* stack); + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/LegacyVmapTransforms.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/LegacyVmapTransforms.h new file mode 100644 index 0000000000000000000000000000000000000000..390989d45bf73fa6080d5ab4aa69963b10970759 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/LegacyVmapTransforms.h @@ -0,0 +1,187 @@ +// Copyright (c) Facebook, Inc. and its affiliates. +// All rights reserved. +// +// This source code is licensed under the BSD-style license found in the +// LICENSE file in the root directory of this source tree. + +#pragma once + +#include +#include + +namespace at::functorch { + +// This files contains the legacy (now-deprecated) batching rule API. +// Please try to use the new-style batching rule API (see writing_batch_rules.md) + +// This file contains abstractions used for transforming *logical* vmap arguments +// into *physical* arguments. (Keep reading for definitions of these terms). + +// NOTE: [Logical vs physical args] +// Consider the following vmap. +// vmap(vmap(func, in_dims=(2,)), in_dims=(0,))(torch.ones(2, 3, 4)) +// This would produce a BatchedTensor wrapping a Tensor of size [2, 3, 4], +// with batch dims 0 and 2: +// BatchedTensor(ones(2, 3, 4), bdims=[(lvl=1,dim=0),(lvl=2,dim=2)]) +// +// We say the *logical* view of the tensor has size [3] -- tensors inside +// `func` appear to have size [3]. +// However, the *physical* underlying tensor (the one passed to vmap) has size +// [2, 3, 4]. +// +// This notion of logical vs physical also extends to non-tensor arguments. +// Consider the previous tensor; let's assume the user called +// `torch.sum(tensor, dim=0)` inside of `func`. Then the logical +// dimension they are reducing over is dim 0 but the physical dim is dim 1 +// (the first non-batch dimension) + +// Forward declared; see NOTE: [What is a VmapPhysicalView?] +struct VmapPhysicalView; + +// Most PyTorch operators take 4 or fewer inputs. +constexpr int64_t kVmapTransformStaticInputSize = 4; +using VmapPhysicalViewVec = SmallVector; + +// Pytorch generally advertises good performance for <= 5 dims. +// (see ATen/core/DimVector.h). We add a few extra dims (~3) for vmap +// dimensions to get 8. Adjust this number as necessary +constexpr int64_t kVmapStaticDimVecSize = 8; +using VmapDimVector = SmallVector; +using VmapSymDimVector = SmallVector; + +// NOTE: [What is an VmapTransform?] +// An *VmapTransform* converts logical views of tensors to physical views. +// +// Batching rules use VmapTransforms to convert logical arguments to +// physical arguments, then call one or more at:: operator that handles the +// physical arguments, and then converts the physical result back to a logical +// argument. + +// VmapTransform for operators that take tensors with multiple batch dims. +// Given one or more logical views on Tensors, `logicalToPhysical` +// permutes all of the batch dims to the front of the tensor, aligns +// and expands the batch dims to match each other (according to their `level`), +// and returns a VmapPhysicalView on the tensor(s). +struct TORCH_API MultiBatchVmapTransform { + static VmapPhysicalView logicalToPhysical(const Tensor& logical_tensor); + static VmapPhysicalViewVec logicalToPhysical(ITensorListRef logical_tensors); +}; + +// VmapTransform for operators that broadcast all inputs. +// Given some logical views on Tensors, `logicalToPhysical`: +// - permutes all of the batch dims to the front of the tensors +// - aligns all the batch dims to the collective levels of all of the tensors. +// If a tensor does not have a batch dim for a vmap level, then it receives +// a size-one dimension for said level. +// - aligns the non-batch dims to have the same dimensionality, adding extra +// size-1 dimensions in between the batch dimensions and the non-batch dimensions +// so that the batch dimensions are lined up from the right. +// +// For example: given inputs of size (B, 2) and (B, 3, 2) where B is the batch +// dimension, BroadcastingVmapTransform returns VmapPhysicalViews that wrap tensors +// of size (B, 1, 2) and (B, 3, 2). +// +// Given inputs of size (B, 2) and (2,), BroadcastingVmapTransform returns +// VmapPhysicalViews wrapping tensors of size (B, 2) and (1, 2). We don't +// actually *need* to return a tensor of size (1, 2) for the second tensor +// because the broadcasting operation takes care of that for us, but we do +// it anyways to keep things simple. +struct TORCH_API BroadcastingVmapTransform { + static VmapPhysicalViewVec logicalToPhysical(TensorList logical_tensors); +}; + +// Forward declared, if you're reading this file head to toe, don't worry about +// it yet. +struct VmapPhysicalToLogicalMap; + +// NOTE: [What is a VmapPhysicalView?] +// VmapPhysicalView represents a physical view on a Tensor. +// +// One can use it to further convert logical dimension indices, logical shapes, +// and more to their physical variants, or convert a new (physical) tensor into +// a logical BatchedTensor. (TODO(rzou): some of these are not yet implemented). +// +// VmapPhysicalView stores a physical tensor with all of its batch dimensions at +// the front and some levels that correspond to said batch dimensions. +// +// The levels bitset specifies which vmap levels correspond to the batch +// dimensions at the front of the tensor. In particular, the number of set bits +// corresponds to the number of batch dimensions on `tensor` and the rightmost +// bit of `levels` specifies the maximum number of nested vmaps we are in at +// this point in time. +// For example, given: +// physical_view = VmapPhysicalView(tensor=ones(2, 3, 4, 5, 6), levels={1, 3}) +// +// Rightmost bit of `levels` is 3 indicating the number of nested vmaps less +// than or equal to 3. +// bitset: 010100 +// ^ +// | +// levels: 012345 +struct TORCH_API VmapPhysicalView { + VmapPhysicalView(Tensor&& tensor, std::bitset levels) + : levels_(levels), tensor_(std::move(tensor)) { + // TORCH_INTERNAL_ASSERT(!isBatchedTensor(tensor)); + } + + Tensor& tensor() { return tensor_; } + const Tensor& tensor() const { return tensor_; } + + // Maps logical dim indices to physical dim indices. Also does dim wrapping. + // + // For example, given: + // physical_view = VmapPhysicalView(tensor=ones(2, 3, 4, 5), levels={1, 3}) + // + // Then physical_view.getPhysicalDims({0, 1}) returns {2, 3}. + // This is because the size of levels tell us that the first two dimensions + // of `tensor_` are batch dimensions, so a logical dim of `n` is actually + // a physical dim of `n + 2`. + VmapDimVector getPhysicalDims(IntArrayRef logical_dims) const; + int64_t getPhysicalDim(int64_t logical_dim) const; + + // Returns a VmapPhysicalToLogicalMap object. This can be used for + // mapping a physical tensor to a new logical tensor (BatchedTensor) + VmapPhysicalToLogicalMap getPhysicalToLogicalMap() const; + + // Maps a logical shape to a physical shape by pre-pending the batch + // sizes to the logical shape. + VmapDimVector getPhysicalShape(IntArrayRef logical_shape) const; + SymDimVector getPhysicalShape(c10::SymIntArrayRef logical_shape) const; + + int64_t numBatchDims() const; + + private: + int64_t numLogicalDims() const; + + std::bitset levels_; + Tensor tensor_; +}; + +// Convenience struct used for mapping a physical tensor (a non-BatchedTensor) +// to a logical one (BatchedTensor). It holds some levels that are used to do the +// mapping and assumes that the batch dimensions in the physical tensor all +// occur at the front of the tensor. +struct TORCH_API VmapPhysicalToLogicalMap { + VmapPhysicalToLogicalMap(std::bitset levels): levels_(levels) {} + + // Maps a physical tensor to a new logical tensor (BatchedTensor). + // Assumes that all of the "batch dimensions" are at the front + // of the physical tensor. For example, given: + // - x = rank-4 Tensor with size 2, 3, 5, 7 + // - levels = (2, 4) + // Returns: + // - BatchedTensor(x, bdims=[(dim=0,lvl=2), (dim=1, lvl=4)]) + Tensor apply(const Tensor& physical_tensor) const; + + // Given a vector of physical tensors, + // 1. maps each tensor to a new logical tensor. Assumes that all of the + // "batch dimensions" are at the front of the physical tensors. + // 2. stores the new logical tensors back into the passed-in vector. This is + // to avoid additional dynamic allocations. + void applyInplace(std::vector& physical_tensors) const; + + std::bitset levels_; +}; + + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/Macros.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/Macros.h new file mode 100644 index 0000000000000000000000000000000000000000..eb0a763261bf051a814c2bfc128f4edd07732bdf --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/Macros.h @@ -0,0 +1,3 @@ +#pragma once + +#define SINGLE_ARG(...) __VA_ARGS__ diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/PlumbingHelper.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/PlumbingHelper.h new file mode 100644 index 0000000000000000000000000000000000000000..9caa52e9652c88762fd66ef0f19cd96a6061927f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/PlumbingHelper.h @@ -0,0 +1,63 @@ +// Copyright (c) Facebook, Inc. and its affiliates. +// All rights reserved. +// +// This source code is licensed under the BSD-style license found in the +// LICENSE file in the root directory of this source tree. +#pragma once +#include +#include +#include + +// NOTE: [vmap plumbing] +// +// Here's how "batching rules" work. +// - we register kernels to the Batched key +// - these kernels have the same signatures as the original operators. +// For example, at::sin(Tensor self) accepts a Tensor, and the batched kernel +// must also accept a Tensor +// - However, it is more natural for users to write a batching rule like the +// following: sin_batch_rule(Tensor self, std::optional self_bdim) +// - There is some codegenerated layer (the "plumbing") that wraps the user +// defined batching rule (e.g. sin_batch_rule) in a kernel that can be +// registered to the Batched key. +// +// The plumbing is responsible for wrapping a batching rule into a form that may +// be registered as the kernel for the batched key. + +namespace at::functorch { + +void vmap_check_escaped(const std::optional &layer, const char* what); + +// Create a BatchedTensor given a tensor, bdim, and level +TORCH_API Tensor makeBatched(Tensor tensor, std::optional bdim, int64_t level); + +// Given a Tensor that may or may not be a BatchedTensor, unwrap it. +// If `tensor` is not a BatchedTensor, or is a BatchedTensor but the level +// doesn't match, then this returns (tensor, std::nullopt). +// Otherwise, it returns (unwrap(tensor), bdim). +TORCH_API std::tuple> unwrapTensorAtLevel(const Tensor& tensor, int64_t level); + +// Creates a vector of BatchedTensor +TORCH_API std::vector makeBatchedVector(std::vector tensors, std::optional bdim, int64_t level); + +// Returns True if ANY tensor in tensors is batched at level +TORCH_API bool isBatchedAtLevel(ITensorListRef tensors, int64_t level); +TORCH_API bool isBatchedAtLevel(const c10::List>& maybe_tensors, int64_t level); +TORCH_API bool isBatchedAtLevel(const Tensor& tensor, int64_t level); +TORCH_API bool isBatchedAtLevel(const std::optional& maybe_tensor, int64_t level); + +// Convenience helper. Returns true if any tensor is batched at level +TORCH_API bool areAnyBatchedAtLevel(ArrayRef> maybe_tensors, int64_t level); + +inline bool ivalueParticipatesInCurrentLevel(const IValue& ivalue) { + if (ivalue.isTensor()) { + auto maybe_level = maybeCurrentDynamicLayer(); + TORCH_INTERNAL_ASSERT(maybe_level.has_value()); + auto current_level = maybe_level->layerId(); + return isBatchedAtLevel(ivalue.toTensor(), current_level); + } + // TODO: should really check this + return false; +} + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/TensorWrapper.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/TensorWrapper.h new file mode 100644 index 0000000000000000000000000000000000000000..bf7b14fd4168997af0329b2d458775314212f70a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/TensorWrapper.h @@ -0,0 +1,103 @@ +// Copyright (c) Facebook, Inc. and its affiliates. +// All rights reserved. +// +// This source code is licensed under the BSD-style license found in the +// LICENSE file in the root directory of this source tree. + +#pragma once + +#include +#include +#include + +namespace at::functorch { + +// NOTE: [functorch's TensorWrapper] +// +// Taking better suggestions for a name. TensorWrapper is the wrapper Tensor +// Subclass for functorch's grad-based transforms (grad, vjp, jvp). It is +// analogous to how vmap uses BatchedTensor as the wrapper Tensor subclass. +// +// If you're familiar with the Tensor-Variable merge, TensorWrapper is effectively +// another Variable. +// +// Consider grad(grad(torch.sin))(x). This wraps `x` as TensorWrapper(TensorWrapper(x)). +// The reason why is so that each TensorWrapper can hold its own AutogradMeta and +// participate in a **separate** autograd graph. +// +// There are alternative designs we could have chosen (e.g. each grad transform +// stores a weak map of Tensor -> AutogradMeta); the benefit of the TensorWrapper +// design is that we can re-use existing VariableType kernels (i.e. Autograd kernels) +// without much modification. Since a TensorWrapper looks like a regular Tensor, +// the VariableType kernel can pull out the AutogradMeta struct from where it +// expects and extend the autograd graph + +struct TORCH_API TensorWrapper : public c10::TensorImpl { + explicit TensorWrapper( + c10::DispatchKeySet key_set, + Tensor value, + int64_t level, + std::shared_ptr is_alive, + bool is_immutable = false, // if true, this came from an operation that aliases an immutable tensor + bool use_value_sizes_strides = true); + + void refreshMetadata(); + + const Tensor& value() const { + return value_; + } + std::optional level() const { + if (is_alive()) { + return level_; + } + return {}; + } + bool is_immutable() const { + return is_immutable_; + } + bool is_alive() const; + + // Overrides necessary for autograd + c10::intrusive_ptr shallow_copy_and_detach( + const c10::VariableVersion& version_counter, + bool allow_tensor_metadata_change) const override; + c10::intrusive_ptr shallow_copy_and_detach( + c10::VariableVersion&& version_counter, + bool allow_tensor_metadata_change) const override; + void shallow_copy_from(const c10::intrusive_ptr& impl) override; + + private: + const char* tensorimpl_type_name() const override; + Tensor value_; + int64_t level_; + bool is_immutable_; + + // TensorWrapper receives a boolean flag on whether or not the Grad Interpreter + // that created it is still alive or not. + // If the Grad Interpreter is no longer alive then it attempts to behave like + // a regular Tensor. + // + // When we exit the level, this wrapper may be marked as "not alive". + // Wrappers that are not alive: + // 1) May still have autograd metadata on them + // 2) Forward dispatches to the underlying value() + std::shared_ptr is_alive_; +}; + +// There are two variants of makeTensorWrapper: one that accepts a level +// and one that accepts an Interpreter. +// +// The one that accepts a level tries to automatically get the life handle from the +// interpreter on the DynamicLayerStack. +// It needs to be used with caution: if the interpreter is not on the +// DynamicLayerStack, then we won't be able to find the life handle. +// +// In practice this isn't a problem: when we're constructing TensorWrapper in +// Python, the corresponding interpreter is on the stack. +TORCH_API Tensor makeTensorWrapper(const Tensor& tensor, int64_t level, bool is_immutable=false); +TORCH_API Tensor makeTensorWrapper(const Tensor& tensor, const Interpreter& interpreter, bool is_immutable=false); +TORCH_API TensorWrapper* maybeGetTensorWrapper(const Tensor& tensor); +TORCH_API void dumpTensor(std::ostream & ss, const Tensor& tensor); +TORCH_API void dumpTensorCout(const Tensor& tensor); + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/VmapInterpreter.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/VmapInterpreter.h new file mode 100644 index 0000000000000000000000000000000000000000..917c671e3ddc95836660f5f0be6365dcdde7e0b4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/functorch/VmapInterpreter.h @@ -0,0 +1,25 @@ +#pragma once +#include + +namespace at::functorch { + +// This is the interpreter that handles the functionalize() transform. +// See NOTE: [functorch interpreter stack] for more details. + +struct VmapInterpreterPtr { + explicit VmapInterpreterPtr(const Interpreter* base): base_(base) { TORCH_INTERNAL_ASSERT(base->key() == TransformType::Vmap); } + TransformType key() const { return base_->key(); } + int64_t level() const { return base_->level(); } + void processImpl(const c10::OperatorHandle& op, torch::jit::Stack* stack); + void sendToNextInterpreterImpl(const c10::OperatorHandle& op, torch::jit::Stack* stack, bool grad_special_case); + c10::SymInt batchSize() const { + return std::get(base_->meta()).batchSize_; + } + RandomnessType randomness() const { + return std::get(base_->meta()).randomness_; + } + private: + const Interpreter* base_; +}; + +} // namespace at::functorch diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPAllocatorMasqueradingAsCUDA.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPAllocatorMasqueradingAsCUDA.h new file mode 100644 index 0000000000000000000000000000000000000000..39ab441478e8f54cd0a8f5f61e9575ce6ca0dc24 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPAllocatorMasqueradingAsCUDA.h @@ -0,0 +1,31 @@ +#pragma once + +#include +#include + +// Use of c10::hip namespace here makes hipification easier, because +// I don't have to also fix namespaces. Sorry! +namespace c10::hip { + +// Takes a valid HIPAllocator (of any sort) and turns it into +// an allocator pretending to be a CUDA allocator. See +// Note [Masquerading as CUDA] +class HIPAllocatorMasqueradingAsCUDA final : public Allocator { + Allocator* allocator_; +public: + explicit HIPAllocatorMasqueradingAsCUDA(Allocator* allocator) + : allocator_(allocator) {} + DataPtr allocate(size_t size) override { + DataPtr r = allocator_->allocate(size); + r.unsafe_set_device(Device(c10::DeviceType::CUDA, r.device().index())); + return r; + } + DeleterFnPtr raw_deleter() const override { + return allocator_->raw_deleter(); + } + void copy_data(void* dest, const void* src, std::size_t count) const final { + allocator_->copy_data(dest, src, count); + } +}; + +} // namespace c10::hip diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPCachingAllocatorMasqueradingAsCUDA.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPCachingAllocatorMasqueradingAsCUDA.h new file mode 100644 index 0000000000000000000000000000000000000000..3aaa9d06c5e91f562382ecd56ea1d3c8a25d41af --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPCachingAllocatorMasqueradingAsCUDA.h @@ -0,0 +1,18 @@ +#pragma once + +#include +#include +#include + +namespace c10 { +// forward declaration +class DataPtr; +namespace hip { +namespace HIPCachingAllocatorMasqueradingAsCUDA { + +C10_HIP_API Allocator* get(); +C10_HIP_API void recordStreamMasqueradingAsCUDA(const DataPtr& ptr, HIPStreamMasqueradingAsCUDA stream); + +} // namespace HIPCachingAllocatorMasqueradingAsCUDA +} // namespace hip +} // namespace c10 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPGuardImplMasqueradingAsCUDA.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPGuardImplMasqueradingAsCUDA.h new file mode 100644 index 0000000000000000000000000000000000000000..93b998a8f7fd6efcca58e255fa47f76a0e1e652b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPGuardImplMasqueradingAsCUDA.h @@ -0,0 +1,383 @@ +#pragma once + +#include + +// The includes of HIPGuard.h +#include +#include +#include +#include +#include +#include + +#include + +#include +#include + +// Use of c10::hip namespace here makes hipification easier, because +// I don't have to also fix namespaces. Sorry! +namespace c10 { namespace hip { + +// Note [Masquerading as CUDA] +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// c10_hip is very easy to understand: it is HIPified from c10_cuda, +// and anywhere you said CUDA, the source code now says HIP. HIPified +// PyTorch is much harder to understand: it is HIPified from regular +// PyTorch, yes, but NO source-to-source translation from CUDA to +// HIP occurs; instead, anywhere we see "CUDA", it actually means "HIP". +// For example, when you use HIPified PyTorch, you say x.cuda() to +// move a tensor onto ROCm device. We call this situation "HIP +// masquerading as CUDA". +// +// This leads to a very awkward situation when we want to call c10_hip +// code from PyTorch, since c10_hip is expecting things to be called +// HIP, but PyTorch is calling them CUDA (masquerading as HIP). To +// fix this impedance mismatch, we have MasqueradingAsCUDA variants +// for all c10_hip classes. These translate between the "HIP" and "CUDA +// masquerading as HIP" worlds. For example, +// HIPGuardImplMasqueradingAsCUDA (this file) provides something like a +// HIPGuardImpl, but it reports its DeviceType as CUDA (e.g., type() +// returns CUDA, getDevice() reports the current HIP device as a CUDA +// device.) +// +// We should be able to delete all of these classes entirely once +// we switch PyTorch to calling a HIP a HIP. +// +// When you add a new MasqueradingAsCUDA class/function, you need to +// also update the rewrite rules in torch/utils/hipify/cuda_to_hip_mappings.py +// +// +// +// By the way, note that the cpp file associated with this also +// *overwrites* the entry in the DeviceGuardImpl registry for CUDA with +// this HIP implementation. + +struct HIPGuardImplMasqueradingAsCUDA final : public c10::impl::DeviceGuardImplInterface { + static constexpr c10::DeviceType static_type = c10::DeviceType::CUDA; + HIPGuardImplMasqueradingAsCUDA() {} + HIPGuardImplMasqueradingAsCUDA(c10::DeviceType t) { + TORCH_INTERNAL_ASSERT(t == c10::DeviceType::CUDA); + } + c10::DeviceType type() const override { + return c10::DeviceType::CUDA; + } + Device exchangeDevice(Device d) const override { + TORCH_INTERNAL_ASSERT(d.is_cuda()); + Device old_device = getDevice(); + if (old_device.index() != d.index()) { + C10_HIP_CHECK(hipSetDevice(d.index())); + } + return old_device; + } + Device getDevice() const override { + int device; + C10_HIP_CHECK(hipGetDevice(&device)); + return Device(c10::DeviceType::CUDA, device); + } + void setDevice(Device d) const override { + TORCH_INTERNAL_ASSERT(d.is_cuda()); + C10_HIP_CHECK(hipSetDevice(d.index())); + } + void uncheckedSetDevice(Device d) const noexcept override { + C10_HIP_CHECK_WARN(hipSetDevice(d.index())); + } + Stream getStream(Device d) const override { + return getCurrentHIPStreamMasqueradingAsCUDA(d.index()).unwrap(); + } + Stream getDefaultStream(Device d) const override { + return getDefaultHIPStreamMasqueradingAsCUDA(d.index()); + } + Stream getNewStream(Device d, int priority = 0) const override { + return getStreamFromPoolMasqueradingAsCUDA(priority, d.index()); + } + Stream getStreamFromGlobalPool(Device d, bool isHighPriority = false) const override { + return getStreamFromPoolMasqueradingAsCUDA(isHighPriority, d.index()); + } + Stream exchangeStream(Stream s) const override { + HIPStreamMasqueradingAsCUDA cs(s); + auto old_stream = getCurrentHIPStreamMasqueradingAsCUDA(s.device().index()); + setCurrentHIPStreamMasqueradingAsCUDA(cs); + return old_stream.unwrap(); + } + DeviceIndex deviceCount() const noexcept override { + int deviceCnt; + hipError_t _err; + _err = hipGetDeviceCount(&deviceCnt); + if(_err != hipErrorNoDevice && _err != hipSuccess) + C10_HIP_CHECK(_err); + return deviceCnt; + } + + // Event-related functions + // Note: hipEventCreateWithFlags should be called on the same device as + // the recording stream's device. + void createEvent( + hipEvent_t* hip_event, + const EventFlag flag) const { + // Maps PyTorch's Event::Flag to HIP flag + auto hip_flag = hipEventDefault; + switch (flag) { + case EventFlag::PYTORCH_DEFAULT: + hip_flag = hipEventDisableTiming; + break; + case EventFlag::BACKEND_DEFAULT: + hip_flag = hipEventDefault; + break; + default: + TORCH_CHECK(false, "HIP event received unknown flag"); + } + + C10_HIP_CHECK(hipEventCreateWithFlags(hip_event, hip_flag)); + } + + void destroyEvent( + void* event, + const DeviceIndex device_index) const noexcept override { + if (!event) return; + auto hip_event = static_cast(event); + int orig_device; + C10_HIP_CHECK_WARN(hipGetDevice(&orig_device)); + C10_HIP_CHECK_WARN(hipSetDevice(device_index)); + C10_HIP_CHECK_WARN(hipEventDestroy(hip_event)); + C10_HIP_CHECK_WARN(hipSetDevice(orig_device)); + } + + void record(void** event, + const Stream& stream, + const DeviceIndex device_index, + const EventFlag flag) const override { + TORCH_CHECK(device_index == -1 || device_index == stream.device_index(), + "Event device index ", + device_index, + " does not match recording stream's device index ", + stream.device_index(), + "."); + + hipEvent_t hip_event = static_cast(*event); + HIPStreamMasqueradingAsCUDA hip_stream{stream}; + + // Moves to stream's device to record + const auto orig_device = getDevice(); + setDevice(stream.device()); + + // Creates the event (lazily) + if (!hip_event) createEvent(&hip_event, flag); + C10_HIP_CHECK(hipEventRecord(hip_event, hip_stream)); + // Makes the void* point to the (possibly just allocated) HIP event + *event = hip_event; + + // Resets device + setDevice(orig_device); + } + + void block( + void* event, + const Stream& stream) const override { + if (!event) return; + hipEvent_t hip_event = static_cast(event); + HIPStreamMasqueradingAsCUDA hip_stream{stream}; + const auto orig_device = getDevice(); + setDevice(stream.device()); + C10_HIP_CHECK(hipStreamWaitEvent( + hip_stream, + hip_event, + /*flags (must be zero)=*/ 0)); + setDevice(orig_device); + } + + bool queryEvent(void* event) const override { + if (!event) return true; + hipEvent_t hip_event = static_cast(event); + const hipError_t err = hipEventQuery(hip_event); + if (err != hipErrorNotReady) C10_HIP_CHECK(err); + else { + // ignore and clear the error if not ready + (void)hipGetLastError(); + } + return (err == hipSuccess); + } + + // Stream-related functions + bool queryStream(const Stream& stream) const override { + HIPStreamMasqueradingAsCUDA hip_stream{stream}; + return hip_stream.query(); + } + + void synchronizeStream(const Stream& stream) const override { + HIPStreamMasqueradingAsCUDA hip_stream{stream}; + hip_stream.synchronize(); + } + + void synchronizeEvent(void* event) const override { + if (!event) + return; + hipEvent_t hip_event = static_cast(event); + C10_HIP_CHECK(hipEventSynchronize(hip_event)); + } + + // Note: synchronizeDevice can be safely called from any device + void synchronizeDevice(const c10::DeviceIndex device_index) const override { + int orig_device{-1}; + C10_HIP_CHECK(hipGetDevice(&orig_device)); + C10_HIP_CHECK(hipSetDevice(device_index)); + C10_HIP_CHECK(hipDeviceSynchronize()); + C10_HIP_CHECK(hipSetDevice(orig_device)); + } + + void recordDataPtrOnStream( + const c10::DataPtr& data_ptr, + const Stream& stream) const override { + HIPStreamMasqueradingAsCUDA hip_stream{stream}; + HIPCachingAllocatorMasqueradingAsCUDA::recordStreamMasqueradingAsCUDA(data_ptr, hip_stream); + } + + double elapsedTime(void* event1, void* event2, const DeviceIndex device_index) + const override { + TORCH_CHECK( + event1 && event2, + "Both events must be recorded before calculating elapsed time."); + int orig_device; + C10_HIP_CHECK(hipGetDevice(&orig_device)); + C10_HIP_CHECK(hipSetDevice(device_index)); + hipEvent_t hip_event1 = static_cast(event1); + hipEvent_t hip_event2 = static_cast(event2); + float time_ms = 0; + // raise hipErrorNotReady if either event is recorded but not yet completed + C10_HIP_CHECK(hipEventElapsedTime(&time_ms, hip_event1, hip_event2)); + C10_HIP_CHECK(hipSetDevice(orig_device)); + return static_cast(time_ms); + } +}; + +// All of the guards which have HIPGuardImpl burned in need to also have +// variants using HIPGuardImplMasqueradingAsCUDA. + +/// This code is all a direct copy from c10/cuda/HIPGuardMasqueradingAsCUDA.h, but with +/// the correct InlineDeviceGuard burned in. Sorry about the +/// copy-pasting. + +struct HIPGuardMasqueradingAsCUDA { + explicit HIPGuardMasqueradingAsCUDA() = delete; + explicit HIPGuardMasqueradingAsCUDA(DeviceIndex device_index) : guard_(device_index) {} + explicit HIPGuardMasqueradingAsCUDA(Device device) : guard_(device) {} + + HIPGuardMasqueradingAsCUDA(const HIPGuardMasqueradingAsCUDA&) = delete; + HIPGuardMasqueradingAsCUDA& operator=(const HIPGuardMasqueradingAsCUDA&) = delete; + HIPGuardMasqueradingAsCUDA(HIPGuardMasqueradingAsCUDA&& other) = delete; + HIPGuardMasqueradingAsCUDA& operator=(HIPGuardMasqueradingAsCUDA&& other) = delete; + + void set_device(Device device) { guard_.set_device(device); } + void reset_device(Device device) { guard_.reset_device(device); } + void set_index(DeviceIndex device_index) { guard_.set_index(device_index); } + Device original_device() const { return guard_.original_device(); } + Device current_device() const { return guard_.current_device(); } + + private: + c10::impl::InlineDeviceGuard guard_; +}; + +struct OptionalHIPGuardMasqueradingAsCUDA { + explicit OptionalHIPGuardMasqueradingAsCUDA() : guard_() {} + explicit OptionalHIPGuardMasqueradingAsCUDA(std::optional device_opt) : guard_(device_opt) {} + explicit OptionalHIPGuardMasqueradingAsCUDA(std::optional device_index_opt) : guard_(device_index_opt) {} + + OptionalHIPGuardMasqueradingAsCUDA(const OptionalHIPGuardMasqueradingAsCUDA&) = delete; + OptionalHIPGuardMasqueradingAsCUDA& operator=(const OptionalHIPGuardMasqueradingAsCUDA&) = delete; + OptionalHIPGuardMasqueradingAsCUDA(OptionalHIPGuardMasqueradingAsCUDA&& other) = delete; + OptionalHIPGuardMasqueradingAsCUDA& operator=(OptionalHIPGuardMasqueradingAsCUDA&& other) = delete; + + void set_device(Device device) { guard_.set_device(device); } + void reset_device(Device device) { guard_.reset_device(device); } + void set_index(DeviceIndex device_index) { guard_.set_index(device_index); } + std::optional original_device() const { return guard_.original_device(); } + std::optional current_device() const { return guard_.current_device(); } + void reset() { guard_.reset(); } + +private: + c10::impl::InlineOptionalDeviceGuard guard_; +}; + +struct HIPStreamGuardMasqueradingAsCUDA { + explicit HIPStreamGuardMasqueradingAsCUDA() = delete; + explicit HIPStreamGuardMasqueradingAsCUDA(Stream stream) : guard_(stream) {} + HIPStreamGuardMasqueradingAsCUDA(const HIPStreamGuardMasqueradingAsCUDA&) = delete; + HIPStreamGuardMasqueradingAsCUDA& operator=(const HIPStreamGuardMasqueradingAsCUDA&) = delete; + HIPStreamGuardMasqueradingAsCUDA(HIPStreamGuardMasqueradingAsCUDA&& other) = delete; + HIPStreamGuardMasqueradingAsCUDA& operator=(HIPStreamGuardMasqueradingAsCUDA&& other) = delete; + + void reset_stream(Stream stream) { guard_.reset_stream(stream); } + + HIPStreamMasqueradingAsCUDA original_stream() const { + return HIPStreamMasqueradingAsCUDA(HIPStreamMasqueradingAsCUDA::UNCHECKED, guard_.original_stream()); + } + HIPStreamMasqueradingAsCUDA current_stream() const { + return HIPStreamMasqueradingAsCUDA(HIPStreamMasqueradingAsCUDA::UNCHECKED, guard_.current_stream()); + } + + Device current_device() const { return guard_.current_device(); } + Device original_device() const { return guard_.original_device(); } + +private: + c10::impl::InlineStreamGuard guard_; +}; + +struct OptionalHIPStreamGuardMasqueradingAsCUDA { + explicit OptionalHIPStreamGuardMasqueradingAsCUDA() : guard_() {} + explicit OptionalHIPStreamGuardMasqueradingAsCUDA(Stream stream) : guard_(stream) {} + explicit OptionalHIPStreamGuardMasqueradingAsCUDA(std::optional stream_opt) : guard_(stream_opt) {} + + OptionalHIPStreamGuardMasqueradingAsCUDA(const OptionalHIPStreamGuardMasqueradingAsCUDA&) = delete; + OptionalHIPStreamGuardMasqueradingAsCUDA& operator=(const OptionalHIPStreamGuardMasqueradingAsCUDA&) = delete; + OptionalHIPStreamGuardMasqueradingAsCUDA(OptionalHIPStreamGuardMasqueradingAsCUDA&& other) = delete; + OptionalHIPStreamGuardMasqueradingAsCUDA& operator=(OptionalHIPStreamGuardMasqueradingAsCUDA&& other) = delete; + + void reset_stream(Stream stream) { guard_.reset_stream(stream); } + + std::optional original_stream() const { + auto r = guard_.original_stream(); + if (r.has_value()) { + return HIPStreamMasqueradingAsCUDA(HIPStreamMasqueradingAsCUDA::UNCHECKED, r.value()); + } else { + return std::nullopt; + } + } + + std::optional current_stream() const { + auto r = guard_.current_stream(); + if (r.has_value()) { + return HIPStreamMasqueradingAsCUDA(HIPStreamMasqueradingAsCUDA::UNCHECKED, r.value()); + } else { + return std::nullopt; + } + } + + void reset() { guard_.reset(); } + +private: + c10::impl::InlineOptionalStreamGuard guard_; +}; + +struct HIPMultiStreamGuardMasqueradingAsCUDA { + explicit HIPMultiStreamGuardMasqueradingAsCUDA(ArrayRef streams) + : guard_(unwrapStreams(streams)) {} + + HIPMultiStreamGuardMasqueradingAsCUDA(const HIPMultiStreamGuardMasqueradingAsCUDA&) = delete; + HIPMultiStreamGuardMasqueradingAsCUDA& operator=(const HIPMultiStreamGuardMasqueradingAsCUDA&) = delete; + HIPMultiStreamGuardMasqueradingAsCUDA(HIPMultiStreamGuardMasqueradingAsCUDA&& other) = delete; + HIPMultiStreamGuardMasqueradingAsCUDA& operator=(HIPMultiStreamGuardMasqueradingAsCUDA&& other) = delete; + +private: + c10::impl::InlineMultiStreamGuard guard_; + + static std::vector unwrapStreams(ArrayRef hipStreams) { + std::vector streams; + streams.reserve(hipStreams.size()); + for (const HIPStreamMasqueradingAsCUDA& hipStream : hipStreams) { + streams.push_back(hipStream); + } + return streams; + } +}; + +}} // namespace c10::hip diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPStreamMasqueradingAsCUDA.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPStreamMasqueradingAsCUDA.h new file mode 100644 index 0000000000000000000000000000000000000000..fb13ada5ad88e18a02225add10f54eef31ca83f3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/hip/impl/HIPStreamMasqueradingAsCUDA.h @@ -0,0 +1,135 @@ +#pragma once + +#include + +// Use of c10::hip namespace here makes hipification easier, because +// I don't have to also fix namespaces. Sorry! +namespace c10 { namespace hip { + +// See Note [Masquerading as CUDA] for motivation + +class HIPStreamMasqueradingAsCUDA { +public: + + enum Unchecked { UNCHECKED }; + + explicit HIPStreamMasqueradingAsCUDA(Stream stream) + : HIPStreamMasqueradingAsCUDA(UNCHECKED, stream) { + // We did the coercion unchecked; check that it was right. + TORCH_CHECK(stream.device().is_cuda() /* !!! */); + } + + explicit HIPStreamMasqueradingAsCUDA(Unchecked, Stream stream) + // Unsafely coerce the "CUDA" stream into a HIP stream + : stream_( + HIPStream( + Stream( + Stream::UNSAFE, + Device(c10::DeviceType::HIP, stream.device_index()), + stream.id()) + ) + ) {} + + // New constructor, just for this. Does NOT coerce. + explicit HIPStreamMasqueradingAsCUDA(HIPStream stream) : stream_(stream) {} + + bool operator==(const HIPStreamMasqueradingAsCUDA& other) const noexcept { + return stream_ == other.stream_; + } + + bool operator!=(const HIPStreamMasqueradingAsCUDA& other) const noexcept { + return stream_ != other.stream_; + } + + operator hipStream_t() const { return stream_.stream(); } + + operator Stream() const { + // Unsafely coerce HIP stream into a "CUDA" stream + return Stream(Stream::UNSAFE, device(), id()); + } + + DeviceIndex device_index() const { return stream_.device_index(); } + + // Unsafely coerce HIP device into CUDA device + c10::DeviceType device_type() const { return c10::DeviceType::CUDA; } + + Device device() const { + // Unsafely coerce HIP device into CUDA device + return Device(c10::DeviceType::CUDA, stream_.device_index()); + } + + StreamId id() const { return stream_.id(); } + bool query() const { return stream_.query(); } + void synchronize() const { stream_.synchronize(); } + int priority() const { return stream_.priority(); } + hipStream_t stream() const { return stream_.stream(); } + + Stream unwrap() const { + // Unsafely coerce HIP stream into "CUDA" stream + return Stream(Stream::UNSAFE, device(), id()); + } + + c10::StreamData3 pack3() const noexcept { + // Unsafely coerce HIP stream into "CUDA" stream before packing + return unwrap().pack3(); + } + + static HIPStreamMasqueradingAsCUDA unpack3(StreamId stream_id, + DeviceIndex device_index, + c10::DeviceType device_type) { + // NB: constructor manages CUDA->HIP translation for us + return HIPStreamMasqueradingAsCUDA(Stream::unpack3( + stream_id, device_index, device_type)); + } + + static std::tuple priority_range() { return HIPStream::priority_range(); } + + // New method, gets the underlying HIPStream + HIPStream hip_stream() const { return stream_; } + +private: + HIPStream stream_; +}; + +HIPStreamMasqueradingAsCUDA +inline getStreamFromPoolMasqueradingAsCUDA(const bool isHighPriority = false, DeviceIndex device = -1) { + return HIPStreamMasqueradingAsCUDA(getStreamFromPool(isHighPriority, device)); +} + +HIPStreamMasqueradingAsCUDA +inline getStreamFromPoolMasqueradingAsCUDA(const int priority, DeviceIndex device = -1) { + return HIPStreamMasqueradingAsCUDA(getStreamFromPool(priority, device)); +} + +HIPStreamMasqueradingAsCUDA +inline getStreamFromExternalMasqueradingAsCUDA(hipStream_t ext_stream, DeviceIndex device) { + return HIPStreamMasqueradingAsCUDA(getStreamFromExternal(ext_stream, device)); +} + +inline HIPStreamMasqueradingAsCUDA getDefaultHIPStreamMasqueradingAsCUDA(DeviceIndex device_index = -1) { + return HIPStreamMasqueradingAsCUDA(getDefaultHIPStream(device_index)); +} + +inline HIPStreamMasqueradingAsCUDA getCurrentHIPStreamMasqueradingAsCUDA(DeviceIndex device_index = -1) { + return HIPStreamMasqueradingAsCUDA(getCurrentHIPStream(device_index)); +} + +inline void setCurrentHIPStreamMasqueradingAsCUDA(HIPStreamMasqueradingAsCUDA stream) { + setCurrentHIPStream(stream.hip_stream()); +} + +inline std::ostream& operator<<(std::ostream& stream, const HIPStreamMasqueradingAsCUDA& s) { + stream << s.hip_stream() << " (masquerading as CUDA)"; + return stream; +} + +}} // namespace c10::hip + +namespace std { + template <> + struct hash { + size_t operator()(c10::hip::HIPStreamMasqueradingAsCUDA s) const noexcept { + return std::hash{}(s.unwrap()); + } + }; +} // namespace std diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Activation.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Activation.h new file mode 100644 index 0000000000000000000000000000000000000000..71be2bcb67cf786a150a5d471cdbe1c752fac676 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Activation.h @@ -0,0 +1,73 @@ +#pragma once + +#include +#include +#include + +namespace c10 { +class Scalar; +} + +namespace at { +struct TensorIterator; +struct TensorIteratorBase; +class TensorBase; +} + +namespace at::native { + +using structured_activation_fn = void (*)(TensorIteratorBase&); +using structured_activation_backward_fn = void (*)(TensorIteratorBase&); + +using activation_fn = void (*)(TensorIterator&); +using activation_backward_fn = void (*)(TensorIterator&); +using softplus_fn = void (*)(TensorIteratorBase&, const c10::Scalar&, const c10::Scalar&); +using softplus_backward_fn = void (*)(TensorIteratorBase&, const c10::Scalar&, const c10::Scalar&); +using threshold_fn = void (*)(TensorIteratorBase&, const c10::Scalar&, const c10::Scalar&); +using hardtanh_backward_fn = void (*)(TensorIterator&, const c10::Scalar&, const c10::Scalar&); +using hardsigmoid_fn = void(*)(TensorIteratorBase&); +using hardsigmoid_backward_fn = void(*)(TensorIteratorBase&); +using hardswish_fn = void(*)(TensorIterator&); +using hardswish_backward_fn = void(*)(TensorIterator&); +using shrink_fn = void (*)(TensorIteratorBase&, const c10::Scalar&); +using softshrink_fn = void (*)(TensorIteratorBase&, const c10::Scalar&); +using shrink_backward_fn = void (*)(TensorIteratorBase&, const c10::Scalar&); +using elu_fn = void (*)(TensorIteratorBase&, const c10::Scalar&, const c10::Scalar&, const c10::Scalar&); +using elu_backward_fn = void (*)(TensorIteratorBase&, const c10::Scalar&, const c10::Scalar&, const c10::Scalar&, bool); +using leaky_relu_fn = void (*)(TensorIteratorBase&, const c10::Scalar&); +using leaky_relu_backward_fn = void (*)(TensorIteratorBase&, const c10::Scalar&); +using log_sigmoid_cpu_fn = void (*)(TensorBase&, TensorBase&, const TensorBase&); +using gelu_fn = void (*)(TensorIteratorBase&, GeluType); +using gelu_backward_fn = void (*)(TensorIteratorBase&, GeluType); +using glu_jvp_fn = void (*)(TensorIteratorBase&); + +DECLARE_DISPATCH(elu_fn, elu_stub) +DECLARE_DISPATCH(elu_backward_fn, elu_backward_stub) +DECLARE_DISPATCH(softplus_fn, softplus_stub) +DECLARE_DISPATCH(softplus_backward_fn, softplus_backward_stub) +DECLARE_DISPATCH(log_sigmoid_cpu_fn, log_sigmoid_cpu_stub) +DECLARE_DISPATCH(activation_backward_fn, log_sigmoid_backward_stub) +DECLARE_DISPATCH(threshold_fn, threshold_stub) +DECLARE_DISPATCH(gelu_fn, GeluKernel) +DECLARE_DISPATCH(gelu_backward_fn, GeluBackwardKernel) +DECLARE_DISPATCH(hardtanh_backward_fn, hardtanh_backward_stub) +DECLARE_DISPATCH(hardsigmoid_fn, hardsigmoid_stub) +DECLARE_DISPATCH(hardsigmoid_backward_fn, hardsigmoid_backward_stub) +DECLARE_DISPATCH(hardswish_fn, hardswish_stub) +DECLARE_DISPATCH(hardswish_backward_fn, hardswish_backward_stub) +DECLARE_DISPATCH(shrink_fn, hardshrink_stub) +DECLARE_DISPATCH(softshrink_fn, softshrink_stub) +DECLARE_DISPATCH(shrink_backward_fn, shrink_backward_stub) +DECLARE_DISPATCH(leaky_relu_fn, leaky_relu_stub) +DECLARE_DISPATCH(leaky_relu_backward_fn, leaky_relu_backward_stub) +DECLARE_DISPATCH(structured_activation_fn, glu_stub) +DECLARE_DISPATCH(activation_backward_fn, glu_backward_stub) +DECLARE_DISPATCH(glu_jvp_fn, glu_jvp_stub) +DECLARE_DISPATCH(structured_activation_fn, silu_stub) +DECLARE_DISPATCH(structured_activation_backward_fn, silu_backward_stub) +DECLARE_DISPATCH(structured_activation_fn, mish_stub) +DECLARE_DISPATCH(activation_backward_fn, mish_backward_stub) +DECLARE_DISPATCH(activation_fn, prelu_stub) +DECLARE_DISPATCH(activation_backward_fn, prelu_backward_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/AdaptivePooling.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/AdaptivePooling.h new file mode 100644 index 0000000000000000000000000000000000000000..3ed45725cada148e4f7fff2a43c1919c5d6da2aa --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/AdaptivePooling.h @@ -0,0 +1,49 @@ +#pragma once + +#include +#include +#include +#include +#include + +namespace at::native { + +using adaptive_avg_pooling2d_fn = void(*)(Tensor& output, const Tensor& input, IntArrayRef output_size); +using adaptive_avg_pooling2d_backward_fn = void(*)(Tensor& grad_input, const Tensor& grad_output); +DECLARE_DISPATCH(adaptive_avg_pooling2d_fn, adaptive_avg_pool2d_kernel) +DECLARE_DISPATCH(adaptive_avg_pooling2d_backward_fn, adaptive_avg_pool2d_backward_kernel) + +using adaptive_max_pooling2d_fn = void(*)(const Tensor& output, const Tensor& indices, const Tensor& input, IntArrayRef output_size); +using adaptive_max_pooling2d_backward_fn = void(*)(const Tensor& grad_input, const Tensor& grad_output, const Tensor& indices); +DECLARE_DISPATCH(adaptive_max_pooling2d_fn, adaptive_max_pool2d_kernel) +DECLARE_DISPATCH(adaptive_max_pooling2d_backward_fn, adaptive_max_pool2d_backward_kernel) + +using adaptive_avg_pooling3d_fn = void(*)(Tensor& output, const Tensor& input, IntArrayRef output_size); +using adaptive_avg_pooling3d_backward_fn = void(*)(Tensor& grad_input, const Tensor& grad_output); +DECLARE_DISPATCH(adaptive_avg_pooling3d_fn, adaptive_avg_pool3d_kernel) +DECLARE_DISPATCH(adaptive_avg_pooling3d_backward_fn, adaptive_avg_pool3d_backward_kernel) + +using adaptive_max_pooling3d_fn = void(*)(const Tensor& output, const Tensor& indices, const Tensor& input, IntArrayRef output_size); +using adaptive_max_pooling3d_backward_fn = void(*)(const Tensor& grad_input, const Tensor& grad_output, const Tensor& indices); +DECLARE_DISPATCH(adaptive_max_pooling3d_fn, adaptive_max_pool3d_kernel) +DECLARE_DISPATCH(adaptive_max_pooling3d_backward_fn, adaptive_max_pool3d_backward_kernel) + +inline int64_t start_index(int64_t a, int64_t b, int64_t c) { + return (a / b) * c + ((a % b) * c) / b; +} + +inline int64_t end_index(int64_t a, int64_t b, int64_t c) { + return 1 + ((a + 1) * c - 1) / b; +} + +inline void adaptive_pool_empty_output_check(const Tensor& gradOutput_, const char* arg_name) { + int64_t ndim = gradOutput_.ndimension(); + for (const auto i : c10::irange(1, ndim)) { + TORCH_CHECK(gradOutput_.size(i) > 0, + arg_name, "(): Expected grad_output to have non-zero size for non-batch dimensions, " + "but grad_output has sizes ", gradOutput_.sizes(), " with dimension ", i, + " being empty"); + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/AmpKernels.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/AmpKernels.h new file mode 100644 index 0000000000000000000000000000000000000000..0504ca1b4f2237a722cea955c41ce3447c7d71e8 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/AmpKernels.h @@ -0,0 +1,28 @@ +#pragma once + +#include +#include + +namespace at { +class Tensor; + +namespace native { + +using _amp_foreach_non_finite_check_and_unscale_cpu__fn = void (*)( + TensorList, + Tensor&, + const Tensor&); + +using _amp_update_scale_cpu__fn = Tensor& (*)( + Tensor&, + Tensor&, + const Tensor&, + double, + double, + int64_t); + +DECLARE_DISPATCH(_amp_foreach_non_finite_check_and_unscale_cpu__fn, _amp_foreach_non_finite_check_and_unscale_cpu_stub) +DECLARE_DISPATCH(_amp_update_scale_cpu__fn, _amp_update_scale_cpu_stub) + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/BatchLinearAlgebra.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/BatchLinearAlgebra.h new file mode 100644 index 0000000000000000000000000000000000000000..1b8ce2bdf5417af55f3bd3557c33847c0bd85a23 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/BatchLinearAlgebra.h @@ -0,0 +1,321 @@ +#pragma once + +#include +#include +#include +#include + +// Forward declare TI +namespace at { +class Tensor; +struct TensorIterator; + +namespace native { +enum class TransposeType; +} + +} + +namespace at::native { + +enum class LapackLstsqDriverType : int64_t { Gels, Gelsd, Gelsy, Gelss}; + +#if AT_BUILD_WITH_LAPACK() +// Define per-batch functions to be used in the implementation of batched +// linear algebra operations + +template +void lapackCholesky(char uplo, int n, scalar_t *a, int lda, int *info); + +template +void lapackCholeskyInverse(char uplo, int n, scalar_t *a, int lda, int *info); + +template +void lapackEig(char jobvl, char jobvr, int n, scalar_t *a, int lda, scalar_t *w, scalar_t* vl, int ldvl, scalar_t *vr, int ldvr, scalar_t *work, int lwork, value_t *rwork, int *info); + +template +void lapackGeqrf(int m, int n, scalar_t *a, int lda, scalar_t *tau, scalar_t *work, int lwork, int *info); + +template +void lapackOrgqr(int m, int n, int k, scalar_t *a, int lda, scalar_t *tau, scalar_t *work, int lwork, int *info); + +template +void lapackOrmqr(char side, char trans, int m, int n, int k, scalar_t *a, int lda, scalar_t *tau, scalar_t *c, int ldc, scalar_t *work, int lwork, int *info); + +template +void lapackSyevd(char jobz, char uplo, int n, scalar_t* a, int lda, value_t* w, scalar_t* work, int lwork, value_t* rwork, int lrwork, int* iwork, int liwork, int* info); + +template +void lapackGels(char trans, int m, int n, int nrhs, + scalar_t *a, int lda, scalar_t *b, int ldb, + scalar_t *work, int lwork, int *info); + +template +void lapackGelsd(int m, int n, int nrhs, + scalar_t *a, int lda, scalar_t *b, int ldb, + value_t *s, value_t rcond, int *rank, + scalar_t* work, int lwork, + value_t *rwork, int* iwork, int *info); + +template +void lapackGelsy(int m, int n, int nrhs, + scalar_t *a, int lda, scalar_t *b, int ldb, + int *jpvt, value_t rcond, int *rank, + scalar_t *work, int lwork, value_t* rwork, int *info); + +template +void lapackGelss(int m, int n, int nrhs, + scalar_t *a, int lda, scalar_t *b, int ldb, + value_t *s, value_t rcond, int *rank, + scalar_t *work, int lwork, + value_t *rwork, int *info); + +template +struct lapackLstsq_impl; + +template +struct lapackLstsq_impl { + static void call( + char trans, int m, int n, int nrhs, + scalar_t *a, int lda, scalar_t *b, int ldb, + scalar_t *work, int lwork, int *info, // Gels flavor + int *jpvt, value_t rcond, int *rank, value_t* rwork, // Gelsy flavor + value_t *s, // Gelss flavor + int *iwork // Gelsd flavor + ) { + lapackGels( + trans, m, n, nrhs, + a, lda, b, ldb, + work, lwork, info); + } +}; + +template +struct lapackLstsq_impl { + static void call( + char trans, int m, int n, int nrhs, + scalar_t *a, int lda, scalar_t *b, int ldb, + scalar_t *work, int lwork, int *info, // Gels flavor + int *jpvt, value_t rcond, int *rank, value_t* rwork, // Gelsy flavor + value_t *s, // Gelss flavor + int *iwork // Gelsd flavor + ) { + lapackGelsy( + m, n, nrhs, + a, lda, b, ldb, + jpvt, rcond, rank, + work, lwork, rwork, info); + } +}; + +template +struct lapackLstsq_impl { + static void call( + char trans, int m, int n, int nrhs, + scalar_t *a, int lda, scalar_t *b, int ldb, + scalar_t *work, int lwork, int *info, // Gels flavor + int *jpvt, value_t rcond, int *rank, value_t* rwork, // Gelsy flavor + value_t *s, // Gelss flavor + int *iwork // Gelsd flavor + ) { + lapackGelsd( + m, n, nrhs, + a, lda, b, ldb, + s, rcond, rank, + work, lwork, + rwork, iwork, info); + } +}; + +template +struct lapackLstsq_impl { + static void call( + char trans, int m, int n, int nrhs, + scalar_t *a, int lda, scalar_t *b, int ldb, + scalar_t *work, int lwork, int *info, // Gels flavor + int *jpvt, value_t rcond, int *rank, value_t* rwork, // Gelsy flavor + value_t *s, // Gelss flavor + int *iwork // Gelsd flavor + ) { + lapackGelss( + m, n, nrhs, + a, lda, b, ldb, + s, rcond, rank, + work, lwork, + rwork, info); + } +}; + +template +void lapackLstsq( + char trans, int m, int n, int nrhs, + scalar_t *a, int lda, scalar_t *b, int ldb, + scalar_t *work, int lwork, int *info, // Gels flavor + int *jpvt, value_t rcond, int *rank, value_t* rwork, // Gelsy flavor + value_t *s, // Gelss flavor + int *iwork // Gelsd flavor + ) { + lapackLstsq_impl::call( + trans, m, n, nrhs, + a, lda, b, ldb, + work, lwork, info, + jpvt, rcond, rank, rwork, + s, + iwork); +} + +template +void lapackLuSolve(char trans, int n, int nrhs, scalar_t *a, int lda, int *ipiv, scalar_t *b, int ldb, int *info); + +template +void lapackLu(int m, int n, scalar_t *a, int lda, int *ipiv, int *info); + +template +void lapackLdlHermitian( + char uplo, + int n, + scalar_t* a, + int lda, + int* ipiv, + scalar_t* work, + int lwork, + int* info); + +template +void lapackLdlSymmetric( + char uplo, + int n, + scalar_t* a, + int lda, + int* ipiv, + scalar_t* work, + int lwork, + int* info); + +template +void lapackLdlSolveHermitian( + char uplo, + int n, + int nrhs, + scalar_t* a, + int lda, + int* ipiv, + scalar_t* b, + int ldb, + int* info); + +template +void lapackLdlSolveSymmetric( + char uplo, + int n, + int nrhs, + scalar_t* a, + int lda, + int* ipiv, + scalar_t* b, + int ldb, + int* info); + +template +void lapackSvd(char jobz, int m, int n, scalar_t *a, int lda, value_t *s, scalar_t *u, int ldu, scalar_t *vt, int ldvt, scalar_t *work, int lwork, value_t *rwork, int *iwork, int *info); +#endif + +#if AT_BUILD_WITH_BLAS() +template +void blasTriangularSolve(char side, char uplo, char trans, char diag, int n, int nrhs, scalar_t* a, int lda, scalar_t* b, int ldb); +#endif + +using cholesky_fn = void (*)(const Tensor& /*input*/, const Tensor& /*info*/, bool /*upper*/); +DECLARE_DISPATCH(cholesky_fn, cholesky_stub) + +using cholesky_inverse_fn = Tensor& (*)(Tensor& /*result*/, Tensor& /*infos*/, bool /*upper*/); + +DECLARE_DISPATCH(cholesky_inverse_fn, cholesky_inverse_stub) + +using linalg_eig_fn = void (*)(Tensor& /*eigenvalues*/, Tensor& /*eigenvectors*/, Tensor& /*infos*/, const Tensor& /*input*/, bool /*compute_eigenvectors*/); + +DECLARE_DISPATCH(linalg_eig_fn, linalg_eig_stub) + +using geqrf_fn = void (*)(const Tensor& /*input*/, const Tensor& /*tau*/); +DECLARE_DISPATCH(geqrf_fn, geqrf_stub) + +using orgqr_fn = Tensor& (*)(Tensor& /*result*/, const Tensor& /*tau*/); +DECLARE_DISPATCH(orgqr_fn, orgqr_stub) + +using ormqr_fn = void (*)(const Tensor& /*input*/, const Tensor& /*tau*/, const Tensor& /*other*/, bool /*left*/, bool /*transpose*/); +DECLARE_DISPATCH(ormqr_fn, ormqr_stub) + +using linalg_eigh_fn = void (*)( + const Tensor& /*eigenvalues*/, + const Tensor& /*eigenvectors*/, + const Tensor& /*infos*/, + bool /*upper*/, + bool /*compute_eigenvectors*/); +DECLARE_DISPATCH(linalg_eigh_fn, linalg_eigh_stub) + +using lstsq_fn = void (*)( + const Tensor& /*a*/, + Tensor& /*b*/, + Tensor& /*rank*/, + Tensor& /*singular_values*/, + Tensor& /*infos*/, + double /*rcond*/, + std::string /*driver_name*/); +DECLARE_DISPATCH(lstsq_fn, lstsq_stub) + +using triangular_solve_fn = void (*)( + const Tensor& /*A*/, + const Tensor& /*B*/, + bool /*left*/, + bool /*upper*/, + TransposeType /*transpose*/, + bool /*unitriangular*/); +DECLARE_DISPATCH(triangular_solve_fn, triangular_solve_stub) + +using lu_factor_fn = void (*)( + const Tensor& /*input*/, + const Tensor& /*pivots*/, + const Tensor& /*infos*/, + bool /*compute_pivots*/); +DECLARE_DISPATCH(lu_factor_fn, lu_factor_stub) + +using unpack_pivots_fn = void(*)( + TensorIterator& iter, + const int64_t dim_size, + const int64_t max_pivot); +DECLARE_DISPATCH(unpack_pivots_fn, unpack_pivots_stub) + +using lu_solve_fn = void (*)( + const Tensor& /*LU*/, + const Tensor& /*pivots*/, + const Tensor& /*B*/, + TransposeType /*trans*/); +DECLARE_DISPATCH(lu_solve_fn, lu_solve_stub) + +using ldl_factor_fn = void (*)( + const Tensor& /*LD*/, + const Tensor& /*pivots*/, + const Tensor& /*info*/, + bool /*upper*/, + bool /*hermitian*/); +DECLARE_DISPATCH(ldl_factor_fn, ldl_factor_stub) + +using svd_fn = void (*)( + const Tensor& /*A*/, + const bool /*full_matrices*/, + const bool /*compute_uv*/, + const std::optional& /*driver*/, + const Tensor& /*U*/, + const Tensor& /*S*/, + const Tensor& /*Vh*/, + const Tensor& /*info*/); +DECLARE_DISPATCH(svd_fn, svd_stub) + +using ldl_solve_fn = void (*)( + const Tensor& /*LD*/, + const Tensor& /*pivots*/, + const Tensor& /*result*/, + bool /*upper*/, + bool /*hermitian*/); +DECLARE_DISPATCH(ldl_solve_fn, ldl_solve_stub) +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/BinaryOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/BinaryOps.h new file mode 100644 index 0000000000000000000000000000000000000000..3eaf75f185277d1440fcf2b9141eec87fbe3d4ed --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/BinaryOps.h @@ -0,0 +1,119 @@ +#pragma once + +#include +#include +#include +#include + + +namespace at { +struct TensorIterator; +struct TensorIteratorBase; +} + +namespace at::native { + +inline void alpha_check(const ScalarType dtype, const Scalar& alpha) { + TORCH_CHECK(! alpha.isBoolean() || dtype == ScalarType::Bool, + "Boolean alpha only supported for Boolean results."); + TORCH_CHECK(isFloatingType(dtype) || isComplexType(dtype) + || alpha.isIntegral(true), + "For integral input tensors, argument alpha must not be a floating point number."); + TORCH_CHECK(isComplexType(dtype) || !alpha.isComplex(), + "For non-complex input tensors, argument alpha must not be a complex number.") +} + +// Basic checking for all sub functions. +inline void sub_check(const TensorBase& self, const TensorBase& other) { + TORCH_CHECK(self.scalar_type() != kBool || other.scalar_type() != kBool, + "Subtraction, the `-` operator, with two bool tensors is not supported. " + "Use the `^` or `logical_xor()` operator instead.") + TORCH_CHECK(self.scalar_type() != kBool && other.scalar_type() != kBool, + "Subtraction, the `-` operator, with a bool tensor is not supported. " + "If you are trying to invert a mask, use the `~` or `logical_not()` operator instead."); +} + +inline void sub_check(const TensorBase& self, const Scalar& scalar) { + TORCH_CHECK(self.scalar_type() != kBool || !scalar.isBoolean(), + "Subtraction, the `-` operator, with two bool tensors is not supported. " + "Use the `^` or `logical_xor()` operator instead.") + TORCH_CHECK(self.scalar_type() != kBool && !scalar.isBoolean(), + "Subtraction, the `-` operator, with a bool tensor is not supported. " + "If you are trying to invert a mask, use the `~` or `logical_not()` operator instead."); +} + +using structured_binary_fn_alpha = void(*)(TensorIteratorBase&, const Scalar& alpha); +using structured_binary_fn_double = void(*)(TensorIteratorBase&, double); +using structured_binary_fn = void(*)(TensorIteratorBase&); + +using binary_fn_alpha = void(*)(TensorIteratorBase&, const Scalar& alpha); +using binary_fn_double = void(*)(TensorIterator&, double); +using binary_fn = void(*)(TensorIterator&); +using binary_clamp_fn_alpha = + void(*)(TensorIterator&, const Scalar& alpha, const Scalar& min_val, const Scalar& max_val); + +// NB: codegenned +DECLARE_DISPATCH(structured_binary_fn_alpha, add_stub) + +DECLARE_DISPATCH(binary_clamp_fn_alpha, add_clamp_stub) +DECLARE_DISPATCH(structured_binary_fn_alpha, sub_stub) +DECLARE_DISPATCH(structured_binary_fn, mul_stub) +DECLARE_DISPATCH(structured_binary_fn, div_true_stub) +DECLARE_DISPATCH(structured_binary_fn, div_floor_stub) +DECLARE_DISPATCH(structured_binary_fn, div_trunc_stub) +DECLARE_DISPATCH(structured_binary_fn, atan2_stub) +DECLARE_DISPATCH(structured_binary_fn, remainder_stub) +DECLARE_DISPATCH(structured_binary_fn, bitwise_and_stub) +DECLARE_DISPATCH(structured_binary_fn, bitwise_or_stub) +DECLARE_DISPATCH(structured_binary_fn, bitwise_xor_stub) +DECLARE_DISPATCH(structured_binary_fn, lshift_stub) +DECLARE_DISPATCH(structured_binary_fn, rshift_stub) +DECLARE_DISPATCH(binary_fn, logical_xor_stub) +DECLARE_DISPATCH(binary_fn, logical_and_stub) +DECLARE_DISPATCH(binary_fn, logical_or_stub) +DECLARE_DISPATCH(structured_binary_fn, lt_stub) +DECLARE_DISPATCH(structured_binary_fn, le_stub) +DECLARE_DISPATCH(structured_binary_fn, gt_stub) +DECLARE_DISPATCH(structured_binary_fn, ge_stub) +DECLARE_DISPATCH(structured_binary_fn, eq_stub) +DECLARE_DISPATCH(structured_binary_fn, ne_stub) +DECLARE_DISPATCH(binary_fn, max_elementwise_stub) +DECLARE_DISPATCH(binary_fn, min_elementwise_stub) +DECLARE_DISPATCH(structured_binary_fn, maximum_stub) +DECLARE_DISPATCH(structured_binary_fn, minimum_stub) +DECLARE_DISPATCH(structured_binary_fn, fmax_stub) +DECLARE_DISPATCH(structured_binary_fn, fmin_stub) +DECLARE_DISPATCH(structured_binary_fn_double, smooth_l1_stub) +DECLARE_DISPATCH(binary_fn_double, huber_stub) +DECLARE_DISPATCH(structured_binary_fn, sigmoid_backward_stub) +DECLARE_DISPATCH(binary_fn_alpha, logit_backward_stub) +DECLARE_DISPATCH(structured_binary_fn, tanh_backward_stub) +DECLARE_DISPATCH(structured_binary_fn, mse_stub) +DECLARE_DISPATCH(structured_binary_fn, fmod_stub) +DECLARE_DISPATCH(structured_binary_fn, logaddexp_stub) +DECLARE_DISPATCH(structured_binary_fn, logaddexp2_stub) +DECLARE_DISPATCH(structured_binary_fn, gcd_stub) +DECLARE_DISPATCH(structured_binary_fn, lcm_stub) +DECLARE_DISPATCH(structured_binary_fn, hypot_stub) +DECLARE_DISPATCH(structured_binary_fn, igamma_stub) +DECLARE_DISPATCH(structured_binary_fn, igammac_stub) +DECLARE_DISPATCH(structured_binary_fn, nextafter_stub) +DECLARE_DISPATCH(structured_binary_fn, heaviside_stub) +DECLARE_DISPATCH(structured_binary_fn, copysign_stub) +DECLARE_DISPATCH(structured_binary_fn, xlogy_stub) +DECLARE_DISPATCH(structured_binary_fn, xlog1py_stub) +DECLARE_DISPATCH(structured_binary_fn, zeta_stub) +DECLARE_DISPATCH(structured_binary_fn, chebyshev_polynomial_t_stub) +DECLARE_DISPATCH(structured_binary_fn, chebyshev_polynomial_u_stub) +DECLARE_DISPATCH(structured_binary_fn, chebyshev_polynomial_v_stub) +DECLARE_DISPATCH(structured_binary_fn, chebyshev_polynomial_w_stub) +DECLARE_DISPATCH(structured_binary_fn, hermite_polynomial_h_stub) +DECLARE_DISPATCH(structured_binary_fn, hermite_polynomial_he_stub) +DECLARE_DISPATCH(structured_binary_fn, laguerre_polynomial_l_stub) +DECLARE_DISPATCH(structured_binary_fn, legendre_polynomial_p_stub) +DECLARE_DISPATCH(structured_binary_fn, shifted_chebyshev_polynomial_t_stub) +DECLARE_DISPATCH(structured_binary_fn, shifted_chebyshev_polynomial_u_stub) +DECLARE_DISPATCH(structured_binary_fn, shifted_chebyshev_polynomial_v_stub) +DECLARE_DISPATCH(structured_binary_fn, shifted_chebyshev_polynomial_w_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/BucketizationUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/BucketizationUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..70878ecd704d7ee65f31b4aef41c97ac6b2a6e59 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/BucketizationUtils.h @@ -0,0 +1,173 @@ +#pragma once + +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + +namespace at::native { + +// original values given by raw_*. If an original value is not contiguous, will make a contiguous copy to +// the corresponding trimmed_* value. Additionally, if the dtypes of the boundary and input tensor do not +// match, will change them to be a common super type so comparisons are done between the same types. +// For any trimmed_* tensor, if its outgoing value matches what it was incoming (typically null), then the +// corresponding raw_* version should be used since it was already contiguous of the right type. +inline void searchsorted_maybe_trim_input_tensors( + Tensor& trimmed_input, + Tensor& trimmed_boundaries, + Tensor& trimmed_sorter, + const Tensor& raw_input, + const Tensor& raw_boundaries, + const Tensor& raw_sorter) { + bool in_is_contiguous = raw_input.is_contiguous(); + bool bd_is_contiguous = raw_boundaries.is_contiguous(); + bool sort_is_contiguous = raw_sorter.is_contiguous(); + + if (!in_is_contiguous) { + TORCH_WARN_ONCE("torch.searchsorted(): input value tensor is non-contiguous, this will lower the performance due " + "to extra data copy when converting non-contiguous tensor to contiguous, please use contiguous input value " + "tensor if possible. This message will only appear once per program."); + trimmed_input = raw_input.contiguous(); + } + if (!bd_is_contiguous) { + TORCH_WARN_ONCE("torch.searchsorted(): boundary tensor is non-contiguous, this will lower the performance due " + "to extra data copy when converting non-contiguous tensor to contiguous, please use contiguous boundary " + "tensor if possible. This message will only appear once per program."); + trimmed_boundaries = raw_boundaries.contiguous(); + } + if (!sort_is_contiguous) { + TORCH_WARN_ONCE("torch.searchsorted(): sorter tensor is non-contiguous, this will lower the performance due " + "to extra data copy when converting non-contiguous tensor to contiguous, please use contiguous sorter " + "tensor if possible. This message will only appear once per program."); + trimmed_sorter = raw_sorter.contiguous(); + } + if (raw_input.dtype() != raw_boundaries.dtype()) { + at::native::ResultTypeState state = {}; + state = at::native::update_result_type_state(raw_boundaries, state); + state = at::native::update_result_type_state(raw_input, state); + ScalarType common_stype = at::native::result_type(state); + + TORCH_INTERNAL_ASSERT(common_stype != ScalarType::Undefined); + if (common_stype != raw_input.scalar_type()) { + trimmed_input = in_is_contiguous ? raw_input.to(common_stype) : trimmed_input.to(common_stype); + } + if (common_stype != raw_boundaries.scalar_type()) { + trimmed_boundaries = bd_is_contiguous ? raw_boundaries.to(common_stype) : trimmed_boundaries.to(common_stype); + } + } +} + +/* unused but needed for internal jagged tensor class */ +inline void searchsorted_maybe_trim_input_tensors( + Tensor& trimmed_input, + Tensor& trimmed_boundaries, + const Tensor& raw_input, + const Tensor& raw_boundaries) { + Tensor trimmed_sorter; + Tensor raw_sorter; + return searchsorted_maybe_trim_input_tensors( + trimmed_input, + trimmed_boundaries, + trimmed_sorter, + raw_input, + raw_boundaries, + raw_sorter); +} + +inline bool searchsorted_dims_matched_before_last_dim(const Tensor& boundaries, const Tensor& input) { + if (boundaries.dim() != input.dim()) { + return false; + } + const auto& dims_bd = boundaries.sizes(); + const auto& dims_in = input.sizes(); + for (int64_t dim = 0; dim + 1 < boundaries.dim(); ++dim) { + if (dims_bd[dim] != dims_in[dim]) { + return false; + } + } + return true; +} + +inline Tensor searchsorted_scalar_tensor(const Scalar& scalar, const c10::Device& device) { + auto tensor = c10::scalar_to_tensor(scalar, device); + // This is to adopt the scalar promotion rules defined in native/TypeProperties.h + // So we have the same type promotion rules as binary operations. + tensor.unsafeGetTensorImpl()->set_wrapped_number(true); + return tensor; +} + +inline void searchsorted_pre_check( + const Tensor& boundaries, + const Tensor& input, + const Tensor& output, + const bool out_int32, + const bool right, + const std::optional side_opt, + const Tensor& sorter) { + if (side_opt) { + const std::string_view side = *side_opt; + TORCH_CHECK(side == "left" || side == "right", "torch.searchsorted(): side can only be 'left' or 'right' but ", + "got ", side); + + // assume the user has not explicitly set (right=False, side="right") + TORCH_CHECK(!right || side == "right", "torch.searchsorted(): side and right can't be set to opposites, got side " + "of ", side, " while right was True"); + } + + TORCH_CHECK(boundaries.device() == input.device(), "torch.searchsorted(): boundaries and input value tensors ", + "should have same device type, but got boundaries tensor device type ", boundaries.device(), " and input value ", + "tensor device type ", input.device()); + + if (sorter.defined()) { + TORCH_CHECK(sorter.device() == boundaries.device(), "torch.searchsorted(): sorter and boundary tensors should ", + "have same device type, but got sorter tensor device type ", sorter.device(), " and input value tensor ", + "device type ", boundaries.device()); + + TORCH_CHECK(sorter.sizes() == boundaries.sizes(), "torch.searchsorted(): boundary and sorter must have the same " + "size, but got boundary tensor ", boundaries.sizes(), "and got sorter tensor ", sorter.sizes()); + + TORCH_CHECK(sorter.scalar_type() == ScalarType::Long, "torch.searchsorted(): sorter must be a tensor of long ", + "dtype but got dtype ", sorter.scalar_type()); + + if (sorter.numel() > 0) { + auto minmax = sorter.aminmax(); + int64_t vmin = std::get<0>(minmax).item().toLong(); + int64_t vmax = std::get<1>(minmax).item().toLong(); + TORCH_CHECK(vmin >= 0 && vmax < sorter.sizes().back(), "torch.searchsorted(): sorter index out of range"); + } + } + + TORCH_CHECK(input.dim() > 0 || (input.dim() == 0 && input.numel() == 1 && boundaries.dim() == 1), + "torch.searchsorted(): input value can be a scalar only when boundaries tensor dimension is 1, but we got ", + "boundaries tensor dim(", boundaries.dim(), ") and input value's dim(", input.dim(), ") numel(", + input.numel(), ")"); + + TORCH_CHECK(boundaries.dim() != 0, "torch.searchsorted(): boundaries tensor should have positive dimension, but ", + "got 0 dimension"); + + TORCH_CHECK(boundaries.dim() == 1 || searchsorted_dims_matched_before_last_dim(boundaries, input), + "torch.searchsorted(): boundaries tensor should be 1 dimension or the first N-1 dimensions of boundaries tensor ", + "and input value tensor must match, but we got boundaries tensor ", boundaries.sizes(), " and input value tensor ", + input.sizes()); + + ScalarType output_dtype = output.scalar_type(); + TORCH_CHECK( + (output_dtype == ScalarType::Long && !out_int32) || + (output_dtype == ScalarType::Int && out_int32), + "torch.searchsorted(): output tensor's dtype is wrong, it can only be Int(int32) or Long(int64) depending on ", + "whether out_int32 flag is True, but we got output tensor's dtype ", output_dtype, + " and out_int32 flag is ", (out_int32 ? "True" : "False")); + + if (out_int32) { + TORCH_CHECK(boundaries.sizes().back() < INT_MAX, + "torch.searchsorted(): the size of boundaries' last dimension should be less than ", INT_MAX, ", but we got ", + boundaries.sizes().back()); + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CPUBlas.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CPUBlas.h new file mode 100644 index 0000000000000000000000000000000000000000..c1045f78c430bb0ee8a03221eb005a62ac76969c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CPUBlas.h @@ -0,0 +1,279 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + + +namespace at::native::cpublas { + +namespace internal { +void normalize_last_dims( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + int64_t *lda, int64_t *ldb, int64_t *ldc); +} // namespace internal + +using gemm_fn = void(*)( + at::ScalarType type, + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + const Scalar& alpha, + const void *a, int64_t lda, + const void *b, int64_t ldb, + const Scalar& beta, + void *c, int64_t ldc); + +DECLARE_DISPATCH(gemm_fn, gemm_stub) + +template +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + at::opmath_type alpha, + const scalar_t *a, int64_t lda, + const scalar_t *b, int64_t ldb, + at::opmath_type beta, + scalar_t *c, int64_t ldc) { + internal::normalize_last_dims(transa, transb, m, n, k, &lda, &ldb, &ldc); + gemm_stub( + kCPU, c10::CppTypeToScalarType::value, + transa, transb, m, n, k, alpha, a, lda, b, ldb, beta, c, ldc); +} + +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + double alpha, + const double *a, int64_t lda, + const double *b, int64_t ldb, + double beta, + double *c, int64_t ldc); + +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + float alpha, + const float *a, int64_t lda, + const float *b, int64_t ldb, + float beta, + float *c, int64_t ldc); + +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + float alpha, + const at::BFloat16 *a, int64_t lda, + const at::BFloat16 *b, int64_t ldb, + float beta, + at::BFloat16 *c, int64_t ldc); + +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + const float alpha, + const at::BFloat16 *a, int64_t lda, + const at::BFloat16 *b, int64_t ldb, + const float beta, + float *c, int64_t ldc); + +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + float alpha, + const at::Half *a, int64_t lda, + const at::Half *b, int64_t ldb, + float beta, + at::Half *c, int64_t ldc); + +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + const float alpha, + const at::Half *a, int64_t lda, + const at::Half *b, int64_t ldb, + const float beta, + float *c, int64_t ldc); + +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + c10::complex alpha, + const c10::complex *a, int64_t lda, + const c10::complex *b, int64_t ldb, + c10::complex beta, + c10::complex *c, int64_t ldc); + +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + c10::complex alpha, + const c10::complex *a, int64_t lda, + const c10::complex *b, int64_t ldb, + c10::complex beta, + c10::complex *c, int64_t ldc); + +void gemm( + TransposeType transa, TransposeType transb, + int64_t m, int64_t n, int64_t k, + int64_t alpha, + const int64_t *a, int64_t lda, + const int64_t *b, int64_t ldb, + int64_t beta, + int64_t *c, int64_t ldc); + +template +void gemm_batched( + TransposeType transa, TransposeType transb, + int64_t batch_size, int64_t m, int64_t n, int64_t k, + scalar_t alpha, + const scalar_t * const *a, int64_t lda, + const scalar_t * const *b, int64_t ldb, + const scalar_t beta, + scalar_t * const *c, int64_t ldc); + +template +void gemm_batched_with_stride( + TransposeType transa, TransposeType transb, + int64_t batch_size, int64_t m, int64_t n, int64_t k, + scalar_t alpha, + const scalar_t *a, int64_t lda, int64_t batch_stride_a, + const scalar_t *b, int64_t ldb, int64_t batch_stride_b, + scalar_t beta, + scalar_t *c, int64_t ldc, int64_t batch_stride_c); + +using axpy_fn = void(*)(at::ScalarType type, int64_t n, const Scalar& a, const void *x, int64_t incx, void *y, int64_t incy); + +DECLARE_DISPATCH(axpy_fn, axpy_stub) + +template +void axpy(int64_t n, scalar_t a, const scalar_t *x, int64_t incx, scalar_t *y, int64_t incy){ + if(n == 1) + { + incx = 1; + incy = 1; + } + axpy_stub( + kCPU, c10::CppTypeToScalarType::value, + n, a, x, incx, y, incy); +} + +void axpy(int64_t n, double a, const double *x, int64_t incx, double *y, int64_t incy); +void axpy(int64_t n, float a, const float *x, int64_t incx, float *y, int64_t incy); +void axpy(int64_t n, c10::complex a, const c10::complex *x, int64_t incx, c10::complex *y, int64_t incy); +void axpy(int64_t n, c10::complex a, const c10::complex *x, int64_t incx, c10::complex *y, int64_t incy); + +using copy_fn = void(*)(at::ScalarType type, int64_t n, const void *x, int64_t incx, void *y, int64_t incy); + +DECLARE_DISPATCH(copy_fn, copy_stub) + +template +void copy(int64_t n, const scalar_t *x, int64_t incx, scalar_t *y, int64_t incy) { + if(n == 1) + { + incx = 1; + incy = 1; + } + copy_stub( + kCPU, c10::CppTypeToScalarType::value, + n, x, incx, y, incy); +} + +void copy(int64_t n, const double *x, int64_t incx, double *y, int64_t incy); +void copy(int64_t n, const float *x, int64_t incx, float *y, int64_t incy); +void copy(int64_t n, const c10::complex *x, int64_t incx, c10::complex *y, int64_t incy); +void copy(int64_t n, const c10::complex *x, int64_t incx, c10::complex *y, int64_t incy); + +// Batch-reduce GEMM +// Operates by the following formula: +// C = SUM(A[i] x B[i]) + C if add_C is true, i = 0 to batch size +// A Base pointer to a tensor A. +// B Base pointer to a tensor B. +// C Pointer to a tensor C (accumulation buffer). +// Note only batch size 1 is used currently +TORCH_API void brgemm( + int64_t M, + int64_t N, + int64_t K, + int64_t ld_a, + int64_t ld_b, + int64_t ld_c, + const bool add_C, + const at::Half* A, + const at::Half* B, + float* C, + bool is_vnni = true); + +TORCH_API void brgemm( + int64_t M, + int64_t N, + int64_t K, + int64_t ld_a, + int64_t ld_b, + int64_t ld_c, + const bool add_C, + const at::BFloat16* A, + const at::BFloat16* B, + float* C, + bool is_vnni = true); + +TORCH_API void brgemm( + int64_t M, + int64_t N, + int64_t K, + int64_t ld_a, + int64_t ld_b, + int64_t ld_c, + const bool add_C, + const float* A, + const float* B, + float* C, + bool is_vnni = false); + +TORCH_API void brgemm( + int64_t M, + int64_t N, + int64_t K, + int64_t ld_a, + int64_t ld_b, + int64_t ld_c, + const bool add_C, + const unsigned char* A, + const unsigned char* B, + int32_t* C, + bool is_vnni = true); + +TORCH_API void brgemm( + int64_t M, + int64_t N, + int64_t K, + int64_t ld_a, + int64_t ld_b, + int64_t ld_c, + const bool add_C, + const unsigned char* A, + const signed char* B, + int32_t* C, + bool is_vnni = true); + +// Release brgemm hardware context +TORCH_API void brgemm_release(bool is_vnni = true); + +// Pack B matrix to get better performance if needed +TORCH_API void pack( + int64_t K, + int64_t N, + int64_t ld_in, + int64_t ld_out, + ScalarType dt_in, + ScalarType dt_out, + const void* in, + void* out); + +// Whether pack is supported in the platform. +TORCH_API bool could_pack(ScalarType dt_in); + +} // namespace at::native::cpublas diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CPUFallback.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CPUFallback.h new file mode 100644 index 0000000000000000000000000000000000000000..44cb534b8db2c9b063bef6b6e2c24f16db0ce454 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CPUFallback.h @@ -0,0 +1,46 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + +namespace at::native { + +// This function implements a boxed fallback to CPU. +// External backends can add their own custom logging on top if it to customize their own CPU fallbacks. +TORCH_API void cpu_fallback(const c10::OperatorHandle& op, torch::jit::Stack* stack, bool error_on_views = false, + c10::DispatchKey cpu_dispatch_key = c10::DispatchKey::CPU); + +// This is a helper function that backends can use to directly call their boxed CPU fallback +// TODO: update and add a usage example after https://github.com/pytorch/pytorch/pull/58092 lands. +template +struct _call_fallback_fn final {}; + +template +struct _call_fallback_fn final { + static ReturnType call(typename c10::maybe_keep_symint::type... args) { + auto op = c10::Dispatcher::singleton() + // TODO: figure out how to make compiler happy without dynamic casts + .findSchemaOrThrow((const char*) Op::name, (const char*) Op::overload_name) + //.findSchemaOrThrow("a", "b") + .typed::type...)>(); + return c10::impl::BoxedKernelWrapper::type...)>::call( + c10::BoxedKernel::makeFromFunction(), + op, + c10::DispatchKeySet(), // we know that the cpu_fallback doesn't use the dispatch keyset. + // TODO: get std::forward<> to work + args... + ); + } +}; + +template +using call_fallback_fn_symint = _call_fallback_fn; + +template +using call_fallback_fn = _call_fallback_fn; + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CanUse32BitIndexMath.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CanUse32BitIndexMath.h new file mode 100644 index 0000000000000000000000000000000000000000..db9742e04021e6fa6942c540c28f4ca6ff90d5df --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CanUse32BitIndexMath.h @@ -0,0 +1,13 @@ +#pragma once +#include +#include + +namespace at { +class TensorBase; +} + +namespace at::native { + +TORCH_API bool canUse32BitIndexMath(const at::TensorBase &t, int64_t max_elem=std::numeric_limits::max()); + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ComplexHelper.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ComplexHelper.h new file mode 100644 index 0000000000000000000000000000000000000000..1b09350aef6ebbef4bd339cdf911b2a68991a17c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ComplexHelper.h @@ -0,0 +1,97 @@ +#pragma once + +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#include + +#include +#endif + +// WARNING: this header contains non-inline functions and should be only +// included from ONE cpp file + +namespace at::native { + +// View tensor with new dtype, storage offset, sizes and strides +inline Tensor view_tensor( + const Tensor &tensor, ScalarType dtype, + c10::SymInt offset, SymIntArrayRef sizes, SymIntArrayRef strides) { + Storage storage = tensor.storage(); + auto key_set = tensor.key_set().remove(DispatchKey::Conjugate); + auto new_tensor = detail::make_tensor( + c10::TensorImpl::VIEW, std::move(storage), key_set, scalarTypeToTypeMeta(dtype)); + auto * impl = new_tensor.unsafeGetTensorImpl(); + impl->set_sizes_and_strides(sizes, strides, offset); + return new_tensor; +} + +inline SymDimVector computeStrideForViewAsReal(SymIntArrayRef oldstride) { + SymDimVector res(oldstride.size() + 1); + for (const auto i : c10::irange(oldstride.size())) { + res[i] = oldstride[i] * 2; + } + res.back() = 1; + return res; +} + +inline Tensor _view_as_real_physical(const Tensor& self) { + TORCH_CHECK(self.is_complex(), "view_as_real is only supported for complex tensors"); + auto old_sizes = self.sym_sizes(); + SymDimVector new_sizes(old_sizes.size() + 1); + std::copy(old_sizes.begin(), old_sizes.end(), new_sizes.begin()); + // last dimension will always have two elements containing the real and imag vals + new_sizes.back() = 2; + auto new_strides = computeStrideForViewAsReal(self.sym_strides()); + auto new_storage_offset = self.sym_storage_offset() * 2; + const auto float_type = c10::toRealValueType(self.scalar_type()); + auto real_tensor = view_tensor(self, float_type, std::move(new_storage_offset), new_sizes, new_strides); + return real_tensor; +} + +// expects as input a complex tensor and returns back a tensor +// with corresponding real dtype containing the complex values +// in the last two dimensions +Tensor view_as_real(const Tensor& self) { + TORCH_CHECK(!self.is_conj(), "view_as_real doesn't work on unresolved conjugated tensors. To resolve the conjugate tensor so you can view it as real, use self.resolve_conj(); however, be warned that the resulting tensor will NOT alias the original."); + return _view_as_real_physical(self); +} + +inline SymDimVector computeStrideForViewAsComplex(SymIntArrayRef oldstride) { + const auto dim = oldstride.size(); + TORCH_CHECK(dim > 0 && oldstride[dim - 1] == 1, "Tensor must have a last dimension with stride 1"); + + SymDimVector res(dim - 1); + for (const auto i : c10::irange(res.size())) { + TORCH_CHECK(oldstride[i] % 2 == 0, "Tensor must have a stride divisible by 2 for all but last dimension"); + res[i] = oldstride[i] / 2; + } + return res; +} + +// expects as input a float or double tensor with last dimension of size 2 +// and returns back a tensor with corresponding complex dtype +Tensor view_as_complex(const Tensor& self) { + TORCH_CHECK( + self.scalar_type() == kFloat || self.scalar_type() == kDouble || self.scalar_type() == kHalf, + "view_as_complex is only supported for half, float and double tensors, but got a tensor of scalar type: ", self.scalar_type()); + + auto old_sizes = self.sym_sizes(); + TORCH_CHECK(!old_sizes.empty(), "Input tensor must have one or more dimensions"); + TORCH_CHECK(old_sizes[old_sizes.size()-1] == 2, "Tensor must have a last dimension of size 2"); + SymDimVector new_sizes(old_sizes.begin(), old_sizes.end() - 1); + + const auto new_strides = computeStrideForViewAsComplex(self.sym_strides()); + const auto complex_type = c10::toComplexType(self.scalar_type()); + + TORCH_CHECK(self.sym_storage_offset() % 2 == 0, "Tensor must have a storage_offset divisible by 2"); + const auto new_storage_offset = self.sym_storage_offset() / 2; + + return view_tensor(self, complex_type, new_storage_offset, new_sizes, new_strides); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CompositeRandomAccessor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CompositeRandomAccessor.h new file mode 100644 index 0000000000000000000000000000000000000000..970b7da5cb70931ccb450a6ec24d511f975248c6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CompositeRandomAccessor.h @@ -0,0 +1,34 @@ +#pragma once + +#include + +namespace at::native { + +struct TupleInfoCPU { + template + using tuple = std::tuple; + + template + static constexpr auto tie(Types&... args) noexcept { + return std::tie(args...); + } +}; + +template +using CompositeRandomAccessorCPU = + CompositeRandomAccessor; + +template +void swap( + references_holder rh1, + references_holder rh2 +) { + return std::swap(rh1.data(), rh2.data()); +} + +template +auto get(references_holder rh) -> decltype(std::get(rh.data())) { + return std::get(rh.data()); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CompositeRandomAccessorCommon.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CompositeRandomAccessorCommon.h new file mode 100644 index 0000000000000000000000000000000000000000..9111c3515afcefec2d81a261737ec28bcae00cdc --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/CompositeRandomAccessorCommon.h @@ -0,0 +1,263 @@ +#include + +#pragma once + +namespace at::native { + +namespace { + +// operator_brackets_proxy is used in +// CompositeRandomAccessor in place of operator[]. +// For some iterators, references returned by operator[] +// could become invalid, operator_brackets_proxy tries to +// resolve that by making accessor[n] to be equivalent to +// *(accessor + n). +template +class operator_brackets_proxy { + using reference = typename std::iterator_traits::reference; + using value_type = typename std::iterator_traits::value_type; + +public: + C10_HOST_DEVICE + operator_brackets_proxy(Accessor const& accessor) + : accessor(accessor) + {} + + C10_HOST_DEVICE + operator reference() { + return *accessor; + } + + C10_HOST_DEVICE + reference operator*() { + return *accessor; + } + + C10_HOST_DEVICE + operator_brackets_proxy& operator=(value_type const& val) { + *accessor = val; + return *this; + } + +private: + Accessor accessor; +}; + +} + +// references_holder is used as a surrogate for the +// references type from std::iterator_traits in CompositeRandomAccessor. +// It is assumed in CompositeRandomAccessor that +// References = tuple, +// Values = tuple by default, +// but they could be anything as long as References could be +// cast to Values. +// If you plan to use it with STL, for example, you will need to +// define 'swap` and `get`(aka std::get) methods. +template +class references_holder { +public: + using values = Values; + using references = References; + + C10_HOST_DEVICE + references_holder(references refs) + : refs{std::move(refs)} + {} + + C10_HOST_DEVICE + operator references() { + return refs; + } + + C10_HOST_DEVICE + operator values() { + return refs; + } + + C10_HOST_DEVICE + references_holder& operator=(values vals) { + refs = vals; + return *this; + } + + C10_HOST_DEVICE + references& data() { + return refs; + } + +protected: + references refs; +}; + +// CompositeRandomAccessor is essentially a simplified version of +// a random access iterator over two random access iterators. +// TupleInfo should contain a variadic type `tuple`, and a method `tie`, +// which constructs a tuple of references from a variadic list of arguments. +template +class CompositeRandomAccessor { + using self_type = CompositeRandomAccessor; + + using key_accessor_value_type = + typename std::iterator_traits::value_type; + using value_accessor_value_type = + typename std::iterator_traits::value_type; + using key_accessor_reference_type = + typename std::iterator_traits::reference; + using value_accessor_reference_type = + typename std::iterator_traits::reference; + + using composite_value_type = typename TupleInfo::template tuple< + key_accessor_value_type, + value_accessor_value_type>; + using composite_reference = typename TupleInfo::template tuple< + key_accessor_reference_type, + value_accessor_reference_type>; + +public: + using value_type = composite_value_type; + using reference = references_holder; + // Note that CompositeRandomAccessor does not hold key and values + // in a specific datastructure, which means that a pointer to a (key, value) + // is not defined. Hence we just use a pointer type of the KeyAccessor. + using pointer = typename std::iterator_traits::pointer; + using difference_type = typename std::iterator_traits::difference_type; + using iterator_category = std::random_access_iterator_tag; + + C10_HOST_DEVICE + CompositeRandomAccessor() = default; + + C10_HOST_DEVICE + CompositeRandomAccessor(KeyAccessor keys, ValueAccessor values) + : keys(keys), values(values) + {} + + // Pointer-like operations { + C10_HOST_DEVICE + reference operator*() const { + return TupleInfo::tie(*keys, *values); + } + + // operator->() is supposed to return a pointer type. + // Since CompositeRandomAccessor does not hold pointers to pairs, + // we just return a pointer to a key. + C10_HOST_DEVICE + auto* operator->() const { + return keys.operator->(); + } + + C10_HOST_DEVICE + reference operator[](difference_type idx) { + return operator_brackets_proxy( + CompositeRandomAccessor(keys + idx, values + idx) + ); + } + // } + + // Prefix/postfix increment/decrement { + C10_HOST_DEVICE + CompositeRandomAccessor& operator++() { + ++keys; + ++values; + return *this; + } + + C10_HOST_DEVICE + CompositeRandomAccessor operator++(int) { + CompositeRandomAccessor copy(*this); + ++*this; + return copy; + } + + C10_HOST_DEVICE + CompositeRandomAccessor& operator--() { + --keys; + --values; + return *this; + } + + C10_HOST_DEVICE + CompositeRandomAccessor operator--(int) { + CompositeRandomAccessor copy(*this); + --*this; + return copy; + } + // } + + // Arithmetic operations { + C10_HOST_DEVICE + CompositeRandomAccessor& operator+=(difference_type offset) { + keys += offset; + values += offset; + return *this; + } + + C10_HOST_DEVICE + CompositeRandomAccessor operator+(difference_type offset) const { + return CompositeRandomAccessor(keys + offset, values + offset); + } + + C10_HOST_DEVICE + friend CompositeRandomAccessor operator+( + difference_type offset, + const CompositeRandomAccessor& accessor + ) { + return accessor + offset; + } + + C10_HOST_DEVICE + CompositeRandomAccessor& operator-=(difference_type offset) { + keys -= offset; + values -= offset; + return *this; + } + + C10_HOST_DEVICE + CompositeRandomAccessor operator-(difference_type offset) const { + return CompositeRandomAccessor(keys - offset, values - offset); + } + + C10_HOST_DEVICE + difference_type operator-(const CompositeRandomAccessor& other) const { + return keys - other.keys; + } + // } + + // Comparison operators { + C10_HOST_DEVICE + bool operator==(const CompositeRandomAccessor& other) const { + return keys == other.keys; + } + + C10_HOST_DEVICE + bool operator!=(const CompositeRandomAccessor& other) const { + return keys != other.keys; + } + + C10_HOST_DEVICE + bool operator<(const CompositeRandomAccessor& other) const { + return keys < other.keys; + } + + C10_HOST_DEVICE + bool operator<=(const CompositeRandomAccessor& other) const { + return keys <= other.keys; + } + + C10_HOST_DEVICE + bool operator>(const CompositeRandomAccessor& other) const { + return keys > other.keys; + } + + C10_HOST_DEVICE + bool operator>=(const CompositeRandomAccessor& other) const { + return keys >= other.keys; + } + // } + +protected: + KeyAccessor keys; + ValueAccessor values; +}; + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ConvUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ConvUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..74230fc0ea2dee3af0d5b3d8f2e219dd94af25a8 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ConvUtils.h @@ -0,0 +1,440 @@ +#pragma once +#include +#include +#include +#include +#include +#include + +#include + +namespace at::native { + +using conv_depthwise2d_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, at::IntArrayRef, std::array); +DECLARE_DISPATCH(conv_depthwise2d_backward_fn, conv_depthwise2d_backward_stub) +using conv_depthwise3d_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, at::IntArrayRef, std::array); +DECLARE_DISPATCH(conv_depthwise3d_backward_fn, conv_depthwise3d_backward_stub) +using cudnn_convolution_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, int64_t, bool, bool, bool, std::array); +DECLARE_DISPATCH(cudnn_convolution_backward_fn, cudnn_convolution_backward_stub) +using mps_convolution_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, int64_t, std::array); +DECLARE_DISPATCH(mps_convolution_backward_fn, mps_convolution_backward_stub) +using cudnn_convolution_transpose_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, at::IntArrayRef, int64_t, bool, bool, bool, std::array); +DECLARE_DISPATCH(cudnn_convolution_transpose_backward_fn, cudnn_convolution_transpose_backward_stub) +using miopen_convolution_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, int64_t, bool, bool, std::array); +DECLARE_DISPATCH(miopen_convolution_backward_fn, miopen_convolution_backward_stub) +using miopen_convolution_transpose_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, at::IntArrayRef, int64_t, bool, bool, std::array); +DECLARE_DISPATCH(miopen_convolution_transpose_backward_fn, miopen_convolution_transpose_backward_stub) +using miopen_depthwise_convolution_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, int64_t, bool, bool, std::array); +DECLARE_DISPATCH(miopen_depthwise_convolution_backward_fn, miopen_depthwise_convolution_backward_stub) +using mkldnn_convolution_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, int64_t, std::array); +DECLARE_DISPATCH(mkldnn_convolution_backward_fn, mkldnn_convolution_backward_stub) +using mkldnn_convolution_transpose_fn = Tensor(*)(const Tensor&, const Tensor&, const std::optional&, + IntArrayRef, IntArrayRef, IntArrayRef, IntArrayRef, int64_t); +DECLARE_DISPATCH(mkldnn_convolution_transpose_fn, mkldnn_convolution_transpose_stub) +using mkldnn_convolution_transpose_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, at::IntArrayRef, int64_t, std::array); +DECLARE_DISPATCH(mkldnn_convolution_transpose_backward_fn, mkldnn_convolution_transpose_backward_stub) +using slow_conv_dilated2d_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, at::IntArrayRef, std::array); +DECLARE_DISPATCH(slow_conv_dilated2d_backward_fn, slow_conv_dilated2d_backward_stub) +using slow_conv_dilated3d_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, at::IntArrayRef, std::array); +DECLARE_DISPATCH(slow_conv_dilated3d_backward_fn, slow_conv_dilated3d_backward_stub) +using slow_conv_transpose2d_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, at::IntArrayRef, at::IntArrayRef, std::array); +DECLARE_DISPATCH(slow_conv_transpose2d_backward_fn, slow_conv_transpose2d_backward_stub) +using slow_conv_transpose3d_backward_fn = std::tuple(*)( + const at::Tensor&, const at::Tensor&, const at::Tensor&, at::IntArrayRef, at::IntArrayRef, + at::IntArrayRef, at::IntArrayRef, at::IntArrayRef, std::array); +DECLARE_DISPATCH(slow_conv_transpose3d_backward_fn, slow_conv_transpose3d_backward_stub) + +namespace { + bool is_cudnnv8_heuristic_mode_b() { + static const bool is_cudnnv8_heuristic_mode_b = c10::utils::check_env("TORCH_CUDNN_USE_HEURISTIC_MODE_B") == true; + return is_cudnnv8_heuristic_mode_b; + } +} + +inline bool cudnnv8_enabled_check_debug() { + static bool cudnnv8_flag = c10::utils::check_env("TORCH_CUDNN_V8_API_DISABLED") != true; + static bool cudnnv8_debug = c10::utils::check_env("TORCH_CUDNN_V8_API_DEBUG") == true; + static uint8_t cudnnv8_debugcount = 0; + if (cudnnv8_debug == 1 && cudnnv8_debugcount < 10) { + TORCH_WARN("TORCH_CUDNN_V8_DEBUG ON, V8 ON: ", cudnnv8_flag, " TORCH_CUDNN_USE_HEURISTIC_MODE B: ", is_cudnnv8_heuristic_mode_b()); + cudnnv8_debugcount++; + } + return cudnnv8_flag == 1; +} + +inline bool cudnnv8_use_heur_mode_b() { + return is_cudnnv8_heuristic_mode_b(); +} + +// Keep in sync with py::enum_ in Module.cpp +enum class ConvBackend { + CudaDepthwise2d, + CudaDepthwise3d, + Cudnn, + CudnnTranspose, + Empty, + Miopen, + MiopenDepthwise, + MiopenTranspose, + Mkldnn, + MkldnnTranspose, + MkldnnEmpty, + NnpackSpatial, + Overrideable, + Slow2d, + Slow3d, + SlowDilated2d, + SlowDilated3d, + SlowTranspose2d, + SlowTranspose3d, + Winograd3x3Depthwise, + Xnnpack2d, + Mps, + MpsTranspose, +}; + +// Overload for selecting the convolution backend from the full set of convolution inputs. +// This overload is exposed to python for testing, etc. +TORCH_API ConvBackend select_conv_backend( + const Tensor& input, const Tensor& weight, const std::optional& bias_opt, + SymIntArrayRef stride, SymIntArrayRef padding, SymIntArrayRef dilation, + bool transposed, SymIntArrayRef output_padding, c10::SymInt groups, const at::OptionalSymIntArrayRef bias_sizes_opt); + +TORCH_API at::MemoryFormat _determine_backend_memory_format(const Tensor& input, + const Tensor& weight, + const ConvBackend backend); + +// --------------------------------------------------------------------- +// +// Math +// +// --------------------------------------------------------------------- + +constexpr int input_batch_size_dim = 0; // also grad_input +constexpr int input_channels_dim = 1; +constexpr int output_batch_size_dim = 0; // also grad_output +constexpr int output_channels_dim = 1; +constexpr int weight_output_channels_dim = 0; +constexpr int weight_input_channels_dim = 1; + +// Often written as 2 + max_dim (extra dims for batch size and channels) +constexpr int max_dim = 3; + +// --------------------------------------------------------------------- +// +// Checking +// +// --------------------------------------------------------------------- + +// Used on pad, stride and dilation +static void check_args(CheckedFrom c, IntArrayRef args, size_t expected_size, const char* arg_name) +{ + TORCH_CHECK(args.size() <= expected_size, + "Too many ", arg_name, " values (", args.size(), ") supplied, expecting ", + expected_size, " (while checking arguments for ", c, ")"); + TORCH_CHECK(args.size() >= expected_size, + "Not enough ", arg_name, " values (", args.size(), ") supplied, expecting ", + expected_size, " (while checking arguments for ", c, ")"); + + auto num_negative_values = std::count_if(args.begin(), args.end(), [](int x){return x < 0;}); + if (num_negative_values > 0){ + std::stringstream ss; + ss << arg_name << " should be greater than zero but got ("; + std::copy(args.begin(), args.end() - 1, std::ostream_iterator(ss,", ")); + ss << args.back() << ")" << " (while checking arguments for " << c << ")"; + TORCH_CHECK(false, ss.str()); + } +} + + +// NOTE [ Convolution checks ] +// +// NB: For many call sites, it is not strictly necessary to check all of +// these relationships (for example, for forward convolution, we compute +// the size of output ourselves, so we don't actually need to check +// output. However, writing a single function that does everything +// means we get to reuse it for both forwards and all backwards +// variants, even when the set of "real" inputs varies. The magic of +// relational computing! +// +// (There is one downside, which is that it is slightly harder to write +// error messages which are able to distinguish between real inputs +// (which the user can change) and computed inputs (which the user can +// only indirectly affect). It would be an interesting exercise to +// come up with a general framework to handle such situations.) +inline void convolution_shape_check( + CheckedFrom c, + const TensorGeometryArg& input, const TensorGeometryArg& weight, const TensorGeometryArg& output, + IntArrayRef padding, IntArrayRef stride, IntArrayRef dilation, int64_t groups) +{ + check_args(c, padding, input->dim() - 2, "padding"); + check_args(c, stride, padding.size(), "stride"); + check_args(c, dilation, padding.size(), "dilation"); + + // Input + checkDimRange(c, input, 3, 6 /* exclusive */); + checkSize_symint(c, input, input_channels_dim, weight->size(1) * groups); + + // Weight + checkSameDim(c, input, weight); + + // TODO: check that output->size() matches output_sizes + // TODO: check that weight matches output->sizes() + checkSameDim(c, input, output); +} + +// NB: conv_output_size and conv_input_size are not bijections, +// as conv_output_size loses information; this is why conv_input_size +// takes an extra output_padding argument to resolve the ambiguity. + +template +inline std::vector _conv_output_size( + ArrayRef input_size, ArrayRef weight_size, + ArrayRef padding, ArrayRef stride, ArrayRef dilation = ArrayRef() +) { + // ASSERT(input_size.size() > 2) + // ASSERT(input_size.size() == weight_size.size()) + bool has_dilation = !dilation.empty(); + auto dim = input_size.size(); + std::vector output_size(dim); + output_size[0] = input_size[input_batch_size_dim]; + output_size[1] = weight_size[weight_output_channels_dim]; + for (const auto d : c10::irange(2, dim)) { + auto dilation_ = has_dilation ? dilation[d - 2] : 1; + auto kernel = dilation_ * (weight_size[d] - 1) + 1; + output_size[d] = (input_size[d] + (2 * padding[d - 2]) - kernel) / stride[d - 2] + 1; + } + return output_size; +} + +inline std::vector conv_output_size( + IntArrayRef input_size, IntArrayRef weight_size, + IntArrayRef padding, IntArrayRef stride, IntArrayRef dilation = IntArrayRef() +) { + return _conv_output_size(input_size, weight_size, padding, stride, dilation); +} + +inline std::vector conv_output_size( + SymIntArrayRef input_size, SymIntArrayRef weight_size, + SymIntArrayRef padding, SymIntArrayRef stride, SymIntArrayRef dilation = SymIntArrayRef() +) { + return _conv_output_size(input_size, weight_size, padding, stride, dilation); +} + +template +std::vector _conv_input_size( + ArrayRef output_size, ArrayRef weight_size, + ArrayRef padding, ArrayRef output_padding, ArrayRef stride, ArrayRef dilation, T groups +) { + // ASSERT(output_size.size() > 2) + // ASSERT(output_size.size() == weight_size.size()) + auto dim = output_size.size(); + std::vector input_size(dim); + input_size[0] = output_size[output_batch_size_dim]; + input_size[1] = weight_size[weight_input_channels_dim] * groups; + for (const auto d : c10::irange(2, dim)) { + auto kernel = (weight_size[d] - 1) * dilation[d - 2] + 1; + input_size[d] = (output_size[d] - 1) * stride[d - 2] - (padding[d - 2] * 2) + + kernel + output_padding[d - 2]; + } + return input_size; +} + +inline std::vector conv_input_size( + SymIntArrayRef output_size, SymIntArrayRef weight_size, + SymIntArrayRef padding, SymIntArrayRef output_padding, SymIntArrayRef stride, SymIntArrayRef dilation, c10::SymInt groups +) { + return _conv_input_size(output_size, weight_size, padding, output_padding, stride, dilation, std::move(groups)); +} + +inline std::vector conv_input_size( + IntArrayRef output_size, IntArrayRef weight_size, + IntArrayRef padding, IntArrayRef output_padding, IntArrayRef stride, IntArrayRef dilation, int64_t groups +) { + return _conv_input_size(output_size, weight_size, padding, output_padding, stride, dilation, groups); +} + +template +std::vector _conv_weight_size( + ArrayRef input_size, ArrayRef output_size, + ArrayRef padding, ArrayRef output_padding, IntArrayRef stride, IntArrayRef dilation, int64_t groups +) { + auto dim = input_size.size(); + std::vector weight_size(dim); + weight_size[0] = output_size[1]; + weight_size[1] = input_size[1] / groups; + for (const auto d : c10::irange(2, dim)) { + auto kernel = input_size[d] - (output_size[d] - 1) * stride[d - 2] + + padding[d - 2] * 2 - output_padding[d - 2]; + weight_size[d] = (kernel - 1) / dilation[d - 2] + 1; + } + return weight_size; +} + +inline std::vector conv_weight_size( + SymIntArrayRef input_size, SymIntArrayRef output_size, + SymIntArrayRef padding, SymIntArrayRef output_padding, IntArrayRef stride, IntArrayRef dilation, int64_t groups +) { + return _conv_weight_size(input_size, output_size, padding, output_padding, stride, dilation, groups); +} + +inline std::vector conv_weight_size( + IntArrayRef input_size, IntArrayRef output_size, + IntArrayRef padding, IntArrayRef output_padding, IntArrayRef stride, IntArrayRef dilation, int64_t groups +) { + return _conv_weight_size(input_size, output_size, padding, output_padding, stride, dilation, groups); +} + +inline Tensor reshape_bias(int64_t dim, const Tensor& bias) { + std::vector shape(dim, 1); + shape[1] = -1; + return bias.reshape(shape); +} + +inline at::MemoryFormat cudnn_conv_suggest_memory_format(const at::Tensor& input, const at::Tensor& weight) { + // disable NHWC for float64 input. + if (!at::detail::getCUDAHooks().compiledWithCuDNN() || + input.scalar_type() == at::kDouble || + weight.scalar_type() == at::kDouble) { + return at::MemoryFormat::Contiguous; + } + long cudnn_version = at::detail::getCUDAHooks().versionCuDNN(); + auto input_memory_format = input.suggest_memory_format(); + auto weight_memory_format = weight.suggest_memory_format(); + auto weight_ndim = weight.ndimension(); + + bool can_use_cudnn_channels_last_2d = (cudnn_version >= 7603) && (weight_ndim == 4) && ( + (input_memory_format == at::MemoryFormat::ChannelsLast) || + (weight_memory_format == at::MemoryFormat::ChannelsLast) + ); + if (can_use_cudnn_channels_last_2d) { + return at::MemoryFormat::ChannelsLast; + } + + bool can_use_cudnn_channels_last_3d = (cudnn_version >= 8005) && (weight_ndim == 5) && ( + (input_memory_format == at::MemoryFormat::ChannelsLast3d) || + (weight_memory_format == at::MemoryFormat::ChannelsLast3d) + ); + if (can_use_cudnn_channels_last_3d) { + return at::MemoryFormat::ChannelsLast3d; + } + + return at::MemoryFormat::Contiguous; +} + +// controls whether emptyCache will be called following cudnn conv benchmarking +TORCH_API void _cudnn_set_conv_benchmark_empty_cache(bool enable); +TORCH_API bool _cudnn_get_conv_benchmark_empty_cache(); + + +inline bool miopen_conv_use_channels_last(const at::Tensor& input, const at::Tensor& weight) { + + // disable NHWC for float64 input. + if (!at::detail::getCUDAHooks().compiledWithMIOpen() || + input.scalar_type() == at::kDouble || + weight.scalar_type() == at::kDouble) { + return false; + } + + bool can_use_miopen_channels_last_2d = false; + // TODO: Remove PYTORCH_MIOPEN_SUGGEST_NHWC once ROCm officially supports NHWC in MIOpen + // See #64427 + static std::optional PYTORCH_MIOPEN_SUGGEST_NHWC = c10::utils::check_env("PYTORCH_MIOPEN_SUGGEST_NHWC"); + + auto input_memory_format = input.suggest_memory_format(); + auto weight_memory_format = weight.suggest_memory_format(); + + can_use_miopen_channels_last_2d = PYTORCH_MIOPEN_SUGGEST_NHWC && *PYTORCH_MIOPEN_SUGGEST_NHWC && ( + ( (input_memory_format == at::MemoryFormat::ChannelsLast) || + (weight_memory_format == at::MemoryFormat::ChannelsLast) ) + ); + + bool can_use_miopen_channels_last_3d = false; + + return can_use_miopen_channels_last_2d || can_use_miopen_channels_last_3d; +} + +inline bool mkldnn_conv_use_channels_last(const at::Tensor& input, const at::Tensor& weight) { + + // disable NHWC for float64 input. + if (input.scalar_type() == at::kDouble || + weight.scalar_type() == at::kDouble) { + return false; + } + + // disable NHWC for MkldnnCPU tensor. + if (input.is_mkldnn() || weight.is_mkldnn()) { + return false; + } + + auto input_memory_format = input.suggest_memory_format(); + auto weight_memory_format = weight.suggest_memory_format(); + + bool can_use_mkldnn_channels_last_2d = + (input_memory_format == at::MemoryFormat::ChannelsLast) || + (weight_memory_format == at::MemoryFormat::ChannelsLast); + + bool can_use_mkldnn_channels_last_3d = + (input_memory_format == at::MemoryFormat::ChannelsLast3d) || + (weight_memory_format == at::MemoryFormat::ChannelsLast3d); + + return can_use_mkldnn_channels_last_2d || can_use_mkldnn_channels_last_3d; +} + +inline bool thnn_conv_use_channels_last(const at::Tensor& input, const at::Tensor& weight) { + + auto input_memory_format = input.suggest_memory_format(); + auto weight_memory_format = weight.suggest_memory_format(); + + bool can_use_thnn_channels_last_2d = input.device().is_cpu() && ( + (input_memory_format == at::MemoryFormat::ChannelsLast) || ( + weight_memory_format == at::MemoryFormat::ChannelsLast)); + + return can_use_thnn_channels_last_2d; +} + +inline bool xpu_conv_use_channels_last(const at::Tensor& input, const at::Tensor& weight) { + + // check layout only for xpu tensor. + if (!input.is_xpu() || !weight.is_xpu()) { + return false; + } + if (!input.defined() || input.is_sparse()) { + // suggest channels_first + return false; + } + + auto is_channel_last = [](const at::Tensor& t) { + auto fmt = t.suggest_memory_format(); + return fmt == at::MemoryFormat::ChannelsLast || fmt == at::MemoryFormat::ChannelsLast3d; + }; + return is_channel_last(input) || is_channel_last(weight); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ConvolutionMM3d.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ConvolutionMM3d.h new file mode 100644 index 0000000000000000000000000000000000000000..3de6763015c6616599a604ee169dacc55985a385 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ConvolutionMM3d.h @@ -0,0 +1,14 @@ +#include + +namespace at::native { + +std::tuple slow_conv3d_backward_cpu( + const Tensor& grad_output, + const Tensor& self, + const Tensor& weight, + IntArrayRef kernel_size, + IntArrayRef stride, + IntArrayRef padding, + std::array output_mask); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Copy.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Copy.h new file mode 100644 index 0000000000000000000000000000000000000000..e28b189e0a5366f311dd07e30afb0e5fe6fc63c5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Copy.h @@ -0,0 +1,20 @@ +#pragma once + +#include + +namespace at { + +class Tensor; +struct TensorIterator; +class TensorBase; + +namespace native { + +using copy_fn = void (*)(TensorIterator&, bool non_blocking); + +DECLARE_DISPATCH(copy_fn, copy_stub) + +TORCH_API void copy_ignoring_overlaps(const TensorBase &dst, const TensorBase &src); + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Cross.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Cross.h new file mode 100644 index 0000000000000000000000000000000000000000..b676b253ba1cccf76ae6f23968f3d5db8b32b3a5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Cross.h @@ -0,0 +1,14 @@ +#pragma once + +#include + +namespace at { +class Tensor; + +namespace native { + +using cross_fn = void(*)(const Tensor&, const Tensor&, const Tensor&, const int64_t d); + +DECLARE_DISPATCH(cross_fn, cross_stub) + +}} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/DilatedConvolutionUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/DilatedConvolutionUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..cd580020374a66aa058938e1186fbfd577a76980 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/DilatedConvolutionUtils.h @@ -0,0 +1,229 @@ +#pragma once + +#include +#include + +#include +#include +#include + +#define TORCH_CHECK_DIM_SIZE(T, DIM, DIM_SIZE, SIZE) \ + TORCH_CHECK( \ + T.dim() == DIM && T.size(DIM_SIZE) == SIZE, \ + "Need " #T " of dimension ", \ + DIM, \ + " and " #T ".size[", \ + DIM_SIZE, \ + "] == ", \ + SIZE, \ + " but got input to be of shape ", \ + T.sizes()) + +namespace at::native::internal { +namespace { +inline bool all_positive(IntArrayRef& arr) { + return std::all_of( + arr.begin(), arr.end(), [](int64_t item) { return item > 0; }); +} + +inline bool all_nonnegative(std::vector& arr) { + return std::all_of( + arr.begin(), arr.end(), [](int64_t item) { return item >= 0; }); +} + +} // namespace + +// calculate the rear part of output tensor sizes +template +std::vector get_output_size( + const Tensor& input, + IntArrayRef kernel_size, + IntArrayRef stride_size, + IntArrayRef pad_size, + IntArrayRef dilation_size) { + std::vector sizes; + for (const auto index : c10::irange(dim)) { + sizes.push_back( + div_rtn( + input.size(index + input.dim() - dim) + 2 * pad_size[index] - + (dilation_size[index] * (kernel_size[index] - 1) + 1), + stride_size[index]) + + 1); + } + return sizes; +} + +// calculate the sizes of output tensor +template +std::vector get_output_size( + const Tensor& input, + const Tensor& weight, + IntArrayRef kernel_size, + IntArrayRef stride_size, + IntArrayRef pad_size, + IntArrayRef dilation_size) { + auto output_size = get_output_size( + input, kernel_size, stride_size, pad_size, dilation_size); + output_size.insert(output_size.begin(), weight.size(0)); + if (input.dim() == dim + 2) { + output_size.insert(output_size.begin(), input.size(0)); + } + return output_size; +} +/* + slow_conv_dilated_shape_check - check user-input to dilated convolution + forward and backward functions. +*/ +template +void slow_conv_dilated_shape_check( + const Tensor& input, + const Tensor& weight, + const Tensor& bias, + const Tensor& grad_output, + IntArrayRef kernel_size, + IntArrayRef stride_size, + IntArrayRef pad_size, + IntArrayRef dilation_size) { + /* + When the following tensors are defined: + + bias, grad_weight, grad_output + + then these are assumed to be contiguous without checking + because of these tensors are made contiguous by calling + .contiguous() method or by resizing of zero-sized tensors in + forward/backward functions. + + When grad_weight is defined then it is assumed without + checking to have the same shape as weight, see backward + functions. + */ + // Check size arguments + TORCH_CHECK( + kernel_size.size() == dim, + "kernel sizes length should be ", + dim, + ", but got ", + kernel_size.size()); + TORCH_CHECK( + stride_size.size() == dim, + "strides length should be ", + dim, + ", but got ", + stride_size.size()); + TORCH_CHECK( + dilation_size.size() == dim, + "dilations length should be ", + dim, + ", but got ", + dilation_size.size()); + TORCH_CHECK( + pad_size.size() == dim, + "pads length should be ", + dim, + ", but got ", + pad_size.size()); + + TORCH_CHECK( + all_positive(kernel_size), + "kernel size should be greater than zero, but got ", + kernel_size); + TORCH_CHECK( + all_positive(stride_size), + "stride should be greater than zero, but got ", + stride_size); + TORCH_CHECK( + all_positive(dilation_size), + "dilation should be greater than zero, but got ", + dilation_size); + + // check input + TORCH_CHECK(input.defined(), "input must be defined"); + bool is_batch = input.dim() == dim + 2; + int64_t n = (is_batch ? 2 : 1); + int64_t ndim = n + dim; + if (!is_batch) { + // input dim has to be dim + 1 if not batched + TORCH_CHECK( + input.dim() == dim + 1, + "input must be 4D or 5D tensor but got ", + input.dim(), + "D tensor"); + } + + // check output sizes + auto output_size = get_output_size( + input, kernel_size, stride_size, pad_size, dilation_size); + + TORCH_CHECK( + all_nonnegative(output_size), + "calculated output size ", + output_size, + " is too small (all sizes must be non-negative)"); + + // check weight + TORCH_CHECK(weight.defined(), "weight must be defined"); + TORCH_CHECK( + weight.dim() == dim + 2, + "weight must be ", + dim + 2, + "D tensor but got ", + weight.dim(), + "D tensor dim=", + dim); + TORCH_CHECK( + weight.sizes().slice(2) == kernel_size, + "weight[2:] shape ", + weight.sizes().slice(2), + " must be equal to kernel_size ", + kernel_size); + + TORCH_CHECK_DIM_SIZE(input, input.dim(), (is_batch ? 1 : 0), weight.size(1)); + + // check bias when present + if (bias.defined()) { + TORCH_CHECK( + bias.dim() == 1, + "bias must be 1D tensor but got ", + bias.dim(), + "D tensor"); + TORCH_CHECK_DIM_SIZE(bias, 1, 0, weight.size(0)); + } + + // check grad_output when present + if (grad_output.defined()) { + TORCH_CHECK( + grad_output.dim() == ndim, + "grad_output must be ", + ndim, + "D tensor but got ", + grad_output.dim(), + "D tensor"); + if (is_batch) { + TORCH_CHECK( + grad_output.size(0) == input.size(0), + "grad_output.size(0)=", + grad_output.size(0), + " must be input.size(0)=", + input.size(0)); + } + TORCH_CHECK( + grad_output.size(n - 1) == weight.size(0), + "grad_output.size(", + n - 1, + ")=", + grad_output.size(n - 1), + " must be weight.size(0)=", + weight.size(0)); + TORCH_CHECK( + grad_output.sizes().slice(n) == output_size, + "grad_output[", + n, + ":] shape", + grad_output.sizes().slice(n), + " must be equal to output size ", + output_size); + } +} + +} // namespace at::native::internal diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/DispatchStub.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/DispatchStub.h new file mode 100644 index 0000000000000000000000000000000000000000..725d0d08bae1cc511c40ac215e22fec65f177308 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/DispatchStub.h @@ -0,0 +1,478 @@ +#pragma once + +#include +#include + +#include +#include +#include + +// Implements instruction set specific function dispatch. +// +// Kernels that may make use of specialized instruction sets (e.g. AVX2) are +// compiled multiple times with different compiler flags (e.g. -mavx2). A +// DispatchStub contains a table of function pointers for a kernel. At runtime, +// the fastest available kernel is chosen based on the features reported by +// cpuinfo. +// +// Example: +// +// In native/MyKernel.h: +// using fn_type = void(*)(const Tensor& x); +// DECLARE_DISPATCH(fn_type, stub) +// +// In native/MyKernel.cpp +// DEFINE_DISPATCH(stub); +// +// In native/cpu/MyKernel.cpp: +// namespace { +// // use anonymous namespace so that different cpu versions won't conflict +// void kernel(const Tensor& x) { ... } +// } +// REGISTER_DISPATCH(stub, &kernel); +// +// To call: +// stub(kCPU, tensor); +// +// TODO: CPU instruction set selection should be folded into whatever +// the main dispatch mechanism is. +// +// Supported device types for registration: +// - CPU: Central Processing Unit +// - CUDA: NVIDIA GPUs +// - HIP: AMD GPUs +// - MPS: Apple Silicon GPUs (Metal Performance Shaders) +// - MTIA: Meta Training and Inference Devices +// - XPU: Intel GPUs +// - PrivateUse1: Reserved for private/custom device types +// +// If you want to update the list of supported devices, add a new dispatch_ptr +// member in DispatchStubImpl.h and update the get_call_ptr switch. +// As well you will need to update the inlined list in 'is_device_supported` +// +// +// ignore warnings about DispatchStub::DEFAULT, AVX, AVX2 defined elsewhere +C10_CLANG_DIAGNOSTIC_PUSH() +C10_CLANG_DIAGNOSTIC_IGNORE("-Wundefined-var-template") + +namespace at::native { + +enum class CPUCapability { + DEFAULT = 0, +#if defined(HAVE_VSX_CPU_DEFINITION) + VSX = 1, +#elif defined(HAVE_ZVECTOR_CPU_DEFINITION) + ZVECTOR = 1, +#elif defined(HAVE_SVE_CPU_DEFINITION) + SVE256 = 1, +#else + AVX2 = 1, + AVX512 = 2, +#endif + NUM_OPTIONS +}; + +// Enum for error types +enum class ErrorType { + MissingDeviceKernel, + DeviceNotSupported +}; + +// Alias for the return type using std::variant +using DispatchResult = std::variant; + +CPUCapability get_cpu_capability(); + +template +struct DispatchStub; + +/** + * The sole purpose of this class is to outline methods that don't need to be + * specialized or otherwise inlined and duplicated (by the compiler due to + * template expansion), since it causes size bloat if there are a significant + * number of specialization of the DispatchStub<> class. + */ +struct TORCH_API DispatchStubImpl { + + // The DispatchStubImpl::try_get_call_ptr() method is used to get the call + // pointer for a given device type. If the call pointer is not found, + // DispatchStubImpl::try_get_call_ptr() returns an ErrorType. + // The main difference between try_get_call_ptr() and get_call_ptr() is that + // try_get_call_ptr() will return the ErrorType and not raise an exception. + DispatchResult try_get_call_ptr( + c10::DeviceType device_type + , void *DEFAULT +#ifdef HAVE_AVX512_CPU_DEFINITION + , void *AVX512 +#endif +#ifdef HAVE_AVX2_CPU_DEFINITION + , void *AVX2 +#endif +#ifdef HAVE_VSX_CPU_DEFINITION + , void *VSX +#endif +#ifdef HAVE_ZVECTOR_CPU_DEFINITION + , void *ZVECTOR +#endif +#ifdef HAVE_SVE256_CPU_DEFINITION + , void *SVE256 +#endif + ); + + // Analogous to try_get_call_ptr(), but it will return the ErrorType and not + // raise an exception. + DispatchResult try_choose_cpu_impl( + void *DEFAULT +#ifdef HAVE_AVX512_CPU_DEFINITION + , void *AVX512 +#endif +#ifdef HAVE_AVX2_CPU_DEFINITION + , void *AVX2 +#endif +#ifdef HAVE_VSX_CPU_DEFINITION + , void *VSX +#endif +#ifdef HAVE_ZVECTOR_CPU_DEFINITION + , void *ZVECTOR +#endif +#ifdef HAVE_SVE256_CPU_DEFINITION + , void *SVE256 +#endif + ); + + + void* get_call_ptr( + c10::DeviceType device_type + , void *DEFAULT +#ifdef HAVE_AVX512_CPU_DEFINITION + , void *AVX512 +#endif +#ifdef HAVE_AVX2_CPU_DEFINITION + , void *AVX2 +#endif +#ifdef HAVE_VSX_CPU_DEFINITION + , void *VSX +#endif +#ifdef HAVE_ZVECTOR_CPU_DEFINITION + , void *ZVECTOR +#endif +#ifdef HAVE_SVE256_CPU_DEFINITION + , void *SVE256 +#endif + ); + + /** + * The CPU Dispatch actual method is chosen in decreasing order of preference by + * DispatchStubImpl::choose_cpu_impl() in case none is found by + * DispatchStubImpl::get_call_ptr() in cpu_dispatch_ptr. + */ + void* choose_cpu_impl( + void *DEFAULT +#ifdef HAVE_AVX512_CPU_DEFINITION + , void *AVX512 +#endif +#ifdef HAVE_AVX2_CPU_DEFINITION + , void *AVX2 +#endif +#ifdef HAVE_VSX_CPU_DEFINITION + , void *VSX +#endif +#ifdef HAVE_ZVECTOR_CPU_DEFINITION + , void *ZVECTOR +#endif +#ifdef HAVE_SVE256_CPU_DEFINITION + , void *SVE256 +#endif + ); + + // Fixing dispatch error in Windows debug builds. + // See https://github.com/pytorch/pytorch/issues/22681 for more details. + #if defined(_MSC_VER) && defined(_DEBUG) + std::atomic cpu_dispatch_ptr; + void* cuda_dispatch_ptr; + void* hip_dispatch_ptr; + void* mps_dispatch_ptr; + void* mtia_dispatch_ptr; + #if defined(USE_XPU) + void* xpu_dispatch_ptr; + #endif + void* privateuse1_dispatch_ptr; + #else + std::atomic cpu_dispatch_ptr{nullptr}; + void* cuda_dispatch_ptr = nullptr; + void* hip_dispatch_ptr = nullptr; + void* mps_dispatch_ptr = nullptr; + void* mtia_dispatch_ptr = nullptr; + #if defined(USE_XPU) + void* xpu_dispatch_ptr = nullptr; + #endif + void* privateuse1_dispatch_ptr = nullptr; + #endif +}; + +template +struct DispatchStub { + using FnPtr = rT (*) (Args...); + + DispatchStub() = default; + DispatchStub(const DispatchStub&) = delete; + DispatchStub& operator=(const DispatchStub&) = delete; + +private: + FnPtr get_call_ptr(const c10::DeviceType device_type) { + return reinterpret_cast( + impl.get_call_ptr(device_type + , reinterpret_cast(DEFAULT) +#ifdef HAVE_AVX512_CPU_DEFINITION + , reinterpret_cast(AVX512) +#endif +#ifdef HAVE_AVX2_CPU_DEFINITION + , reinterpret_cast(AVX2) +#endif +#ifdef HAVE_VSX_CPU_DEFINITION + , reinterpret_cast(VSX) +#endif +#ifdef HAVE_ZVECTOR_CPU_DEFINITION + , reinterpret_cast(ZVECTOR) +#endif +#ifdef HAVE_SVE256_CPU_DEFINITION + , reinterpret_cast(SVE256) +#endif + ) + ); + } + +public: + template + rT operator()(c10::DeviceType device_type, ArgTypes&&... args) { + FnPtr call_ptr = get_call_ptr(device_type); + return (*call_ptr)(std::forward(args)...); + } + + void set_cuda_dispatch_ptr(FnPtr fn_ptr) { + impl.cuda_dispatch_ptr = reinterpret_cast(fn_ptr); + } + + #if defined(USE_XPU) + void set_xpu_dispatch_ptr(FnPtr fn_ptr){ + impl.xpu_dispatch_ptr = reinterpret_cast(fn_ptr); + } + #endif + + void set_hip_dispatch_ptr(FnPtr fn_ptr) { + impl.hip_dispatch_ptr = reinterpret_cast(fn_ptr); + } + + void set_mps_dispatch_ptr(FnPtr fn_ptr) { + impl.mps_dispatch_ptr = reinterpret_cast(fn_ptr); + } + + void set_mtia_dispatch_ptr(FnPtr fn_ptr) { + impl.mtia_dispatch_ptr = reinterpret_cast(fn_ptr); + } + + void set_privateuse1_dispatch_ptr(FnPtr fn_ptr) { + impl.privateuse1_dispatch_ptr = reinterpret_cast(fn_ptr); + } + + // Returns true if the dispatcher has a kernel registered for this device + // type. + bool is_device_supported(const c10::DeviceType device_type) { + auto result = impl.try_get_call_ptr(device_type + , reinterpret_cast(DEFAULT) +#ifdef HAVE_AVX512_CPU_DEFINITION + , reinterpret_cast(AVX512) +#endif +#ifdef HAVE_AVX2_CPU_DEFINITION + , reinterpret_cast(AVX2) +#endif +#ifdef HAVE_VSX_CPU_DEFINITION + , reinterpret_cast(VSX) +#endif +#ifdef HAVE_ZVECTOR_CPU_DEFINITION + , reinterpret_cast(ZVECTOR) +#endif +#ifdef HAVE_SVE256_CPU_DEFINITION + , reinterpret_cast(SVE256) +#endif + ); + if (std::holds_alternative(result)){ + return false; + } + return true; + } + + static TORCH_API FnPtr DEFAULT; +#ifdef HAVE_AVX512_CPU_DEFINITION + static TORCH_API FnPtr AVX512; +#endif +#ifdef HAVE_AVX2_CPU_DEFINITION + static TORCH_API FnPtr AVX2; +#endif +#ifdef HAVE_VSX_CPU_DEFINITION + static TORCH_API FnPtr VSX; +#endif +#ifdef HAVE_ZVECTOR_CPU_DEFINITION + static TORCH_API FnPtr ZVECTOR; +#endif +#ifdef HAVE_SVE256_CPU_DEFINITION + static TORCH_API FnPtr SVE256; +#endif +private: + DispatchStubImpl impl; +}; + +namespace { +template +struct RegisterCUDADispatch { + RegisterCUDADispatch(DispatchStub &stub, typename DispatchStub::FnPtr value) { + stub.set_cuda_dispatch_ptr(value); + } +}; + +template +struct RegisterXPUDispatch { + RegisterXPUDispatch(DispatchStub &stub, typename DispatchStub::FnPtr value){ + stub.set_xpu_dispatch_ptr(value); + } +}; + +template +struct RegisterMPSDispatch { + RegisterMPSDispatch(DispatchStub &stub, typename DispatchStub::FnPtr value) { + stub.set_mps_dispatch_ptr(value); + } +}; + +template +struct RegisterHIPDispatch { + RegisterHIPDispatch(DispatchStub &stub, typename DispatchStub::FnPtr value) { + // TODO: make this point at hip_dispatch_ptr + stub.set_cuda_dispatch_ptr(value); + } +}; + +template +struct RegisterMTIADispatch { + RegisterMTIADispatch(DispatchStub &stub, typename DispatchStub::FnPtr value) { + stub.set_mtia_dispatch_ptr(value); + } +}; + +template +struct RegisterPRIVATEUSE1Dispatch { + RegisterPRIVATEUSE1Dispatch(DispatchStub &stub, typename DispatchStub::FnPtr value) { + stub.set_privateuse1_dispatch_ptr(value); + } +}; + +} // anonymous namespace +// Compiler will complain if you put things like std::tuple in +// the `fn` argument of DECLARE_DISPATCH. Some possible workarounds, e.g., +// adding parentheses and using helper struct to get rid of the parentheses, do +// not work with MSVC. So do a `using`-declaration if you need to pass in such +// `fn`, e.g., grid_sampler_2d_backward_cpu_kernel in GridSampleKernel.h. +#define DECLARE_DISPATCH(fn, name) \ + struct name##_DECLARE_DISPATCH_type : DispatchStub { \ + name##_DECLARE_DISPATCH_type() = default; \ + name##_DECLARE_DISPATCH_type(const name##_DECLARE_DISPATCH_type&) = delete; \ + name##_DECLARE_DISPATCH_type& operator=(const name##_DECLARE_DISPATCH_type&) = delete; \ + name##_DECLARE_DISPATCH_type(name##_DECLARE_DISPATCH_type&&) = delete; \ + name##_DECLARE_DISPATCH_type& operator=(name##_DECLARE_DISPATCH_type&&) = delete; \ + ~name##_DECLARE_DISPATCH_type() = default; \ + }; \ + extern TORCH_API struct name##_DECLARE_DISPATCH_type name; + +#define DEFINE_DISPATCH(name) struct name##_DECLARE_DISPATCH_type name + +#define REGISTER_ARCH_DISPATCH(name, arch, fn) \ + template <> name##_DECLARE_DISPATCH_type::FnPtr TORCH_API DispatchStub::arch = fn; + +#ifdef HAVE_AVX512_CPU_DEFINITION +#define REGISTER_AVX512_DISPATCH(name, fn) REGISTER_ARCH_DISPATCH(name, AVX512, fn) +#else +#define REGISTER_AVX512_DISPATCH(name, fn) +#endif + +#ifdef HAVE_AVX2_CPU_DEFINITION +#define REGISTER_AVX2_DISPATCH(name, fn) REGISTER_ARCH_DISPATCH(name, AVX2, fn) +#else +#define REGISTER_AVX2_DISPATCH(name, fn) +#endif + +#ifdef HAVE_VSX_CPU_DEFINITION +#define REGISTER_VSX_DISPATCH(name, fn) REGISTER_ARCH_DISPATCH(name, VSX, fn) +#else +#define REGISTER_VSX_DISPATCH(name, fn) +#endif + +#ifdef HAVE_ZVECTOR_CPU_DEFINITION +#define REGISTER_ZVECTOR_DISPATCH(name, fn) REGISTER_ARCH_DISPATCH(name, ZVECTOR, fn) +#else +#define REGISTER_ZVECTOR_DISPATCH(name, fn) +#endif + +#ifdef HAVE_SVE256_CPU_DEFINITION +#define REGISTER_SVE256_DISPATCH(name, fn) REGISTER_ARCH_DISPATCH(name, SVE256, fn) +#else +#define REGISTER_SVE256_DISPATCH(name, fn) +#endif + +// Macro to register the same kernel for all CPU arch types. This is useful +// if a kernel does not benefit from being recompiled across different arch types. +#define REGISTER_ALL_CPU_DISPATCH(name, fn) \ + REGISTER_ARCH_DISPATCH(name, DEFAULT, fn) \ + REGISTER_AVX512_DISPATCH(name, fn) \ + REGISTER_AVX2_DISPATCH(name, fn) \ + REGISTER_VSX_DISPATCH(name, fn) \ + REGISTER_ZVECTOR_DISPATCH(name, fn) \ + REGISTER_SVE256_DISPATCH(name, fn) + +#define REGISTER_NO_CPU_DISPATCH(name) \ + REGISTER_ALL_CPU_DISPATCH(name, nullptr) + +#define REGISTER_CUDA_DISPATCH(name, fn) \ + static RegisterCUDADispatch name ## __register(name, fn); + +#define REGISTER_XPU_DISPATCH(name, fn) \ + static RegisterXPUDispatch name ## __register(name, fn); + +#define REGISTER_HIP_DISPATCH(name, fn) \ + static RegisterHIPDispatch name ## __register(name, fn); + +#define REGISTER_MPS_DISPATCH(name, fn) \ + static RegisterMPSDispatch name ## __register(name, fn); + +#define REGISTER_MTIA_DISPATCH(name, fn) \ + static RegisterMTIADispatch name ## __register(name, fn); + +#define REGISTER_PRIVATEUSE1_DISPATCH(name, fn) \ + static RegisterPRIVATEUSE1Dispatch name ## __register(name, fn); + +// NB: This macro must be used in an actual 'cu' file; if you try using +// it from a 'cpp' file it will not work! +#if defined(__CUDACC__) +#define REGISTER_DISPATCH(name, fn) REGISTER_CUDA_DISPATCH(name, fn) +#elif defined(__HIPCC__) +// TODO: cut this over to HIP dispatch once we stop pretending that CUDA +// is HIP in the PyTorch HIPify build. +#define REGISTER_DISPATCH(name, fn) REGISTER_CUDA_DISPATCH(name, fn) +// #define REGISTER_DISPATCH(name, fn) REGISTER_HIP_DISPATCH(name, fn) +#elif defined(__OBJC__) && defined(USE_MPS) +// NB: this macro must be used from a 'mm' file in order to dispatch a MPS kernel +#define REGISTER_DISPATCH(name, fn) REGISTER_MPS_DISPATCH(name, fn) +#elif defined(CPU_CAPABILITY) +// REGISTER_DISPATCH now dispatches an AVX512 kernel to nullptr but registers other dispatches. +// ALSO_REGISTER_AVX512_DISPATCH should be used for ensuring AVX512 dispatch, among others. +// ALSO_REGISTER_SVE256_DISPATCH should be used for ensuring SVE256 dispatch, among others. +#ifdef CPU_CAPABILITY_AVX512 +#define REGISTER_DISPATCH(name, fn) REGISTER_ARCH_DISPATCH(name, CPU_CAPABILITY, ((void*)(fn) ? nullptr : nullptr)) +#else +#define REGISTER_DISPATCH(name, fn) REGISTER_ARCH_DISPATCH(name, CPU_CAPABILITY, fn) +#endif +#define ALSO_REGISTER_AVX512_DISPATCH(name, fn) REGISTER_ARCH_DISPATCH(name, CPU_CAPABILITY, fn) +#define ALSO_REGISTER_SVE256_DISPATCH(name, fn) REGISTER_ARCH_DISPATCH(name, CPU_CAPABILITY, fn) +#endif +} // namespace at::native + +C10_CLANG_DIAGNOSTIC_POP() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Distance.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Distance.h new file mode 100644 index 0000000000000000000000000000000000000000..99abd7a389f4992a10dd84a762353b93d6898816 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Distance.h @@ -0,0 +1,20 @@ +#pragma once + +#include + +namespace at { +class Tensor; + +namespace native { + +using pdist_forward_fn = void(*)(Tensor&, const Tensor&, const double p); +using pdist_backward_fn = void(*)(Tensor&, const Tensor&, const Tensor&, const double p, const Tensor&); +using cdist_fn = void(*)(Tensor&, const Tensor&, const Tensor&, const double p); +using cdist_backward_fn = void(*)(Tensor&, const Tensor&, const Tensor&, const Tensor&, const double p, const Tensor&); + +DECLARE_DISPATCH(pdist_forward_fn, pdist_forward_stub) +DECLARE_DISPATCH(pdist_backward_fn, pdist_backward_stub) +DECLARE_DISPATCH(cdist_fn, cdist_stub) +DECLARE_DISPATCH(cdist_backward_fn, cdist_backward_stub) + +}} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/DistributionTemplates.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/DistributionTemplates.h new file mode 100644 index 0000000000000000000000000000000000000000..c6013b6fbae5fd1e87fdeb881921ba18fab489aa --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/DistributionTemplates.h @@ -0,0 +1,394 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#include +#include +#include +#endif + +namespace at::native::templates { + +// ==================================================== Random ======================================================== + +// The purpose of `update_from` and `update_to` is to find the closest valid int64_t number that can be used as actual `from`. +// The current implementation of `random_` uses uint64_t arithmetics and casts the result to the target dtype(scalar_t). +// This casting can result in generating numbers that happen to be greater or equal to `to` value. For instance: +// +// auto actual = torch::empty({3, 3}, torch::half); +// actual.random_(0, 65504); +// +// If random's uint64_t arithmetics produces 65503 as a random value after casting to torch::half it becomes 65504 +// and violates the requirement that random value must be less than `to`. To resolve this issue `update_from` and `update_to` +// moves `from` to the right and `to` to the left to the next closest value that won't go outside [from, to) after casting to +// the target dtype. For `to` = 65504 it moves left for (1 << (log2(to) - 11 + 1)) = 32 and becomes 65472, which is previous +// available number for torch::half dtype. +template +int64_t update_from(int64_t from) { + static_assert( + std::is_floating_point_v || + std::is_same_v || + std::is_same_v, "scalar_t must be floating-point type"); + const auto from_plus_1 = static_cast(static_cast(from + 1)); + if (from_plus_1 < from) { + int64_t from_ = std::abs(from + 1); + int n = 0; + while (from_ >>= 1) ++n; + // NOLINTNEXTLINE(clang-analyzer-core.UndefinedBinaryOperatorResult) + from = from_plus_1 + (1LL << (n - std::numeric_limits::digits + 1)); + } + return from; +} + +template +int64_t update_to(int64_t to) { + static_assert( + std::is_floating_point_v || + std::is_same_v || + std::is_same_v, "scalar_t must be floating-point type"); + const auto to_minus_1 = static_cast(static_cast(to - 1)); + if (to_minus_1 >= to) { + int64_t to_ = std::abs(to - 1); + int n = 0; + while (to_ >>= 1) ++n; + // NOLINTNEXTLINE(clang-analyzer-core.UndefinedBinaryOperatorResult) + to = to_minus_1 - (1LL << (n - std::numeric_limits::digits + 1)); + } + return to; +} + +// Return earlier for not invoking kernel. +// See https://github.com/pytorch/pytorch/issues/103418 for more details +#define CHECK_EMPTY_AND_RETURN(tensor) \ + if (tensor.numel() == 0) { \ + return tensor; \ + } + +template class random_kernel, typename RNG> +at::Tensor& random_impl(at::Tensor& self, std::optional generator) { + CHECK_EMPTY_AND_RETURN(self); + auto iter = at::TensorIterator::borrowing_nullary_op(self); + random_kernel()(iter, generator); + return self; +} + +#define CHECK_OUT_OF_BOUNDS(var, name, min, max, dtype) \ + TORCH_CHECK(var >= min && var <= max, name , " is out of bounds for ", dtype); \ + +#define WARN_OUT_OF_BOUNDS(var, name, digits, dtype) \ + if (var < -(1LL << digits) || var > (1LL << digits)) { \ + TORCH_WARN(name , " is out of bounds [-(2^", digits, "), 2^", digits, "]. ", \ + "Due to precision limitations ", dtype, " can support discrete uniform distribution only within this range. ", \ + "This warning will become an error in version 1.7 release, please fix the code in advance"); \ + } + +inline void check_from_to_in_range(int64_t from, int64_t to_inc, caffe2::TypeMeta dtype) { + const auto scalar_type = typeMetaToScalarType(dtype); + if (isFloatingType(scalar_type)) { + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, scalar_type, "check_random_fp_bounds", [&] { + const auto min = static_cast(std::numeric_limits::lowest()); + const auto max = static_cast(std::numeric_limits::max()); + CHECK_OUT_OF_BOUNDS(from, "from", min, max, dtype); + CHECK_OUT_OF_BOUNDS(to_inc, "to - 1", min, max, dtype); + + constexpr auto digits = std::numeric_limits::digits; + WARN_OUT_OF_BOUNDS(from, "from", digits, dtype); + WARN_OUT_OF_BOUNDS(to_inc, "to - 1", digits, dtype); + }); + } else if (scalar_type == kUInt64) { + // When you do a comparison between int64_t and uint64_t, the usual + // arithmetic conversions say that the int64_t value is promoted to + // unsigned. But this conversion wraps around: if I had -1 as my int64_t, + // then it will promote to 0xFFFFFFFFFFFFFFFF in uint64_t. This is never + // the right thing to do. + CHECK_OUT_OF_BOUNDS(from, "from", 0, INT64_MAX, dtype); + CHECK_OUT_OF_BOUNDS(to_inc, "to - 1", 0, INT64_MAX, dtype); + } else if (isIntegralType(scalar_type, /*includeBool=*/true)) { + AT_DISPATCH_V2(scalar_type, "check_random_integral_bounds", AT_WRAP([&]() { + const auto min = static_cast(std::numeric_limits::lowest()); + const auto max = static_cast(std::numeric_limits::max()); + CHECK_OUT_OF_BOUNDS(from, "from", min, max, dtype); + CHECK_OUT_OF_BOUNDS(to_inc, "to - 1", min, max, dtype); + }), AT_EXPAND(AT_INTEGRAL_TYPES), kUInt16, kUInt32, kBool); + } else { + TORCH_CHECK(false, "check_random_bounds handles only integral, floating-point and boolean types"); + } +} + +template class random_from_to_kernel, typename RNG> +at::Tensor& random_from_to_impl(at::Tensor& self, int64_t from, std::optional to_opt, std::optional generator) { + uint64_t range = 0; + auto iter = at::TensorIterator::borrowing_nullary_op(self); + if (to_opt.has_value()) { + // [from, to) + int64_t to = *to_opt; + TORCH_CHECK(from < to, "random_ expects 'from' to be less than 'to', but got from=", from, " >= to=", to); + if (isFloatingType(iter.dtype())) { + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, self.scalar_type(), "random_update_from_to", [&] { + from = update_from(from); + to = update_to(to); + TORCH_CHECK(from < to, "random_ expects 'from' casted to dtype to be less than 'to' casted to dtype, but got from=", from, " >= to=", to); + }); + } + check_from_to_in_range(from, to - 1, self.dtype()); + CHECK_EMPTY_AND_RETURN(self); + range = static_cast(to) - static_cast(from); + random_from_to_kernel()(iter, range, from, generator); + } else if (from != std::numeric_limits::lowest()) { + // [from, std::numeric_limits::max()] + int64_t to_inc = 0; + if (isFloatingType(iter.dtype())) { + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, self.scalar_type(), "random_from_to_range_calc", [&] { + constexpr int64_t scalar_t_max = static_cast(1) << std::numeric_limits::digits; + to_inc = scalar_t_max > std::numeric_limits::max() ? std::numeric_limits::max() : static_cast(scalar_t_max); + from = update_from(from); + TORCH_CHECK(from < to_inc, "random_ expects 'from' casted to dtype to be less than or equal to 'to_inc' casted to dtype, but got from=", from, " > to_inc=", to_inc); + }); + } else if (isIntegralType(iter.dtype(), /*includeBool=*/true)) { + AT_DISPATCH_V2(self.scalar_type(), "random_from_to_range_calc", AT_WRAP([&] { + if constexpr (std::is_same_v) { + to_inc = static_cast(true); + } else { + to_inc = static_cast(std::numeric_limits::max()); + } + }), AT_EXPAND(AT_INTEGRAL_TYPES_V2), kBool); + } else { + TORCH_CHECK(false, "random_from_to_impl handles only integral, floating-point and boolean types"); + } + check_from_to_in_range(from, to_inc, self.dtype()); + CHECK_EMPTY_AND_RETURN(self); + range = static_cast(to_inc) - static_cast(from) + 1; + random_from_to_kernel()(iter, range, from, generator); + } else { + // [std::numeric_limits::lowest(), std::numeric_limits::max()] + // range = 2^64 + CHECK_EMPTY_AND_RETURN(self); + random_from_to_kernel()(iter, generator); + } + return self; +} + +// ==================================================== Normal ======================================================== + +#define CHECK_NORMAL_TENSOR_STD(std) \ + do { \ + TORCH_CHECK( \ + !std.is_complex(), \ + "normal expects standard deviation to be non-complex"); \ + TORCH_CHECK( \ + std.numel() == 0 || std.is_meta() || std.min().ge(0).item(), \ + "normal expects all elements of std >= 0.0"); \ + } while (0) + +#define CHECK_NORMAL_STD(std) \ + TORCH_CHECK(std >= 0.0, "normal expects std >= 0.0, but found std ", std); + +template class normal_kernel, typename RNG> +Tensor& normal_impl_(Tensor& self, double mean, double std, std::optional gen) { + CHECK_NORMAL_STD(std); + CHECK_EMPTY_AND_RETURN(self); + + if (self.is_complex()) { + auto float_tensor = at::view_as_real(self); + // variance for normal distribution of the real and imaginary values + // is half of the input variance + normal_kernel()(float_tensor, mean, std/(std::sqrt(2)), gen); + } else { + normal_kernel()(self, mean, std, gen); + } + return self; +} + +template class normal_kernel, typename RNG> +Tensor& normal_out_impl(Tensor& output, const Tensor& mean, double std, std::optional gen) { + CHECK_NORMAL_STD(std); + auto std_tensor = at::empty_like(output, MemoryFormat::Contiguous); + auto shape = at::infer_size(mean.sizes(), std_tensor.sizes()); + at::native::resize_output(output, shape); + normal_impl_(output, 0, std, gen); + output.add_(mean); + return output; +} + +template class normal_kernel, typename RNG> +Tensor& normal_out_impl(Tensor& output, double mean, const Tensor& std, std::optional gen) { + CHECK_NORMAL_TENSOR_STD(std); + auto mean_tensor = at::full({}, mean, output.options()); + auto shape = at::infer_size(mean_tensor.sizes(), std.sizes()); + at::native::resize_output(output, shape); + normal_impl_(output, 0, 1, gen); + // CUDA NB: addcmul_out copies the tensor to be added into the output. + // The previous function here was addcmul_out(output, mean_tensor, output, std, 1); + // The third argument is not a constant reference and hence the samples in output are overwritten. + // Consequently, the computation performed is mean_tensor + mean_tensor * std instead of mean_tensor + output * std + output.mul_(std).add_(mean_tensor); + return output; +} + +template class normal_kernel, typename RNG> +Tensor& normal_out_impl(Tensor& output, const Tensor& mean, const Tensor& std, std::optional gen) { + CHECK_NORMAL_TENSOR_STD(std); + auto shape = at::infer_size(mean.sizes(), std.sizes()); + at::native::resize_output(output, shape); + normal_impl_(output, 0, 1, gen); + // CUDA NB: addcmul_out copies the tensor to be added into the output. + // The previous function here was addcmul_out(output, mean, output, std, 1); + // The third argument is not a constant reference and hence the samples in output are overwritten. + // Consequently, the computation performed is mean + mean * std instead of mean + output * std + output.mul_(std).add_(mean); + return output; +} + +template class normal_kernel, typename RNG> +Tensor normal_impl(const Tensor& mean, double std, std::optional gen) { + CHECK_NORMAL_STD(std); + Tensor ret = at::empty_like(mean, MemoryFormat::Contiguous); + normal_out_impl(ret, mean, std, gen); + return ret; +} + +template class normal_kernel, typename RNG> +Tensor normal_impl(double mean, const Tensor& std, std::optional gen) { + CHECK_NORMAL_TENSOR_STD(std); + Tensor ret = at::empty_like(std, MemoryFormat::Contiguous); + normal_out_impl(ret, mean, std, gen); + return ret; +} + +template class normal_kernel, typename RNG> +Tensor normal_impl(const Tensor& mean, const Tensor& std, std::optional gen) { + CHECK_NORMAL_TENSOR_STD(std); + auto shape = at::infer_size(mean.sizes(), std.sizes()); + Tensor ret = at::empty(shape, mean.options(), MemoryFormat::Contiguous); + normal_out_impl(ret, mean, std, gen); + return ret; +} + +// ==================================================== Uniform ======================================================= + +template class uniform_kernel, typename RNG> +at::Tensor& uniform_impl_(at::Tensor& self, double from, double to, std::optional generator) { + if (self.is_complex()) { + CHECK_EMPTY_AND_RETURN(self); + auto float_tensor = at::view_as_real(self); + uniform_impl_(float_tensor, from, to, generator); + } else { + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, self.scalar_type(), "check_uniform_bounds", [&] { + [[maybe_unused]] const auto dtype = self.dtype(); + const auto min = static_cast(std::numeric_limits::lowest()); + const auto max = static_cast(std::numeric_limits::max()); + CHECK_OUT_OF_BOUNDS(from, "from", min, max, dtype); + CHECK_OUT_OF_BOUNDS(to, "to", min, max, dtype); + TORCH_CHECK(from <= to, "uniform_ expects to return a [from, to) range, but found from=", from, " > to=", to); + TORCH_CHECK((to - from) <= std::numeric_limits::max(), + "uniform_ expects to-from <= std::numeric_limits<", toString(self.scalar_type()), + ">::max(), but found to=", to, " and from=", from, + " which result in to-from to exceed the limit"); + from = std::min(std::max(from, min), max); + to = std::max(std::min(to, max), min); + }); + CHECK_EMPTY_AND_RETURN(self); + auto iter = at::TensorIterator::borrowing_nullary_op(self); + uniform_kernel()(iter, from, to, generator); + } + return self; +} + +// ================================================== LogNormal ======================================================= + +template class log_normal_kernel, typename RNG> +at::Tensor& log_normal_impl_(at::Tensor& self, double mean, double std, std::optional gen) { + TORCH_CHECK(std > 0.0, "log_normal_ expects std > 0.0, but found std=", std); + CHECK_EMPTY_AND_RETURN(self); + auto iter = TensorIterator::borrowing_nullary_op(self); + log_normal_kernel()(iter, mean, std, gen); + return self; +} + +// =================================================== Geometric ====================================================== + +template class geometric_kernel, typename RNG> +Tensor& geometric_impl_(Tensor& self, double p, std::optional gen) { + TORCH_CHECK(0 < p && p < 1, "geometric_ expects p to be in (0, 1), but got p=", p); + CHECK_EMPTY_AND_RETURN(self); + auto iter = TensorIterator::borrowing_nullary_op(self); + geometric_kernel()(iter, p, gen); + return self; +} + +// ================================================== Exponential ===================================================== + +template class exponential_kernel, typename RNG> +Tensor& exponential_impl_(Tensor& self, double lambda, std::optional gen) { + TORCH_CHECK(lambda > 0.0, "exponential_ expects lambda > 0.0, but found lambda=", lambda); + CHECK_EMPTY_AND_RETURN(self); + auto iter = TensorIterator::borrowing_nullary_op(self); + exponential_kernel()(iter, lambda, gen); + return self; +} + +// ==================================================== Cauchy ======================================================== + +template class cauchy_kernel, typename RNG> +Tensor& cauchy_impl_(Tensor& self, double median, double sigma, std::optional gen) { + // TODO: instead of variable name 'sigma', use 'gamma' or 'scale' + // the variance, squared sigma, is undefined for cauchy distribution + TORCH_CHECK(sigma > 0.0, "cauchy_ expects sigma > 0.0, but found sigma=", sigma); + TORCH_CHECK(at::isFloatingType(self.scalar_type()), "Cauchy distribution is a continuous probability distribution. dtype must be a floating point but you specified ", self.dtype()); + CHECK_EMPTY_AND_RETURN(self); + auto iter = TensorIterator::borrowing_nullary_op(self); + cauchy_kernel()(iter, median, sigma, gen); + return self; +} + +// ==================================================== Bernoulli ===================================================== + +template class bernoulli_tensor_kernel, typename RNG> +Tensor& bernoulli_impl_(Tensor& self, const Tensor& p_, std::optional gen) { + CHECK_EMPTY_AND_RETURN(self); + NoNamesGuard guard; + at::assert_no_internal_overlap(self); + bernoulli_tensor_kernel()(self, p_, gen); + return self; +} + +template class bernoulli_scalar_kernel, typename RNG> +Tensor& bernoulli_impl_(Tensor& self, double p, std::optional gen) { + TORCH_CHECK(0 <= p && p <= 1, "bernoulli_ expects p to be in [0, 1], but got p=", p); + CHECK_EMPTY_AND_RETURN(self); + at::assert_no_internal_overlap(self); + bernoulli_scalar_kernel()(self, p, gen); + return self; +} + +template class bernoulli_tensor_kernel, typename RNG> +Tensor& bernoulli_out_impl(Tensor& result, const Tensor& self, std::optional gen) { + // result.resize_as_(self) requires self to have same dtype as result, so we + // use resize_ instead. + // TODO: Fix resize_as_. See pytorch/pytorch#11665. + result.resize_(self.sizes()); + bernoulli_impl_(result, self, gen); + namedinference::propagate_names(result, self); + return result; +} + +#undef CHECK_OUT_OF_BOUNDS +#undef WARN_OUT_OF_BOUNDS + +} // namespace at::native::templates diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Distributions.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Distributions.h new file mode 100644 index 0000000000000000000000000000000000000000..1c9db44aebb032c393e1261c5179db22af392460 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Distributions.h @@ -0,0 +1,518 @@ +#pragma once + +#include +#include +#include + +// ROCM hcc doesn't work well with using std:: in kernel functions +#if defined(__CUDA_ARCH__) +#include +#define compat_exp c10::cuda::compat::exp +#define compat_ceil c10::cuda::compat::ceil +#define compat_floor c10::cuda::compat::floor +#define compat_log c10::cuda::compat::log +#define compat_pow c10::cuda::compat::pow +#define compat_sqrt c10::cuda::compat::sqrt +#define compat_tan c10::cuda::compat::tan +#define compat_abs c10::cuda::compat::abs +#define compat_log1p c10::cuda::compat::log1p +#elif defined(__HIPCC__) +#include +#define compat_exp c10::hip::compat::exp +#define compat_ceil c10::hip::compat::ceil +#define compat_floor c10::hip::compat::floor +#define compat_log c10::hip::compat::log +#define compat_pow c10::hip::compat::pow +#define compat_sqrt c10::hip::compat::sqrt +#define compat_tan c10::hip::compat::tan +#define compat_abs c10::hip::compat::abs +#define compat_log1p c10::hip::compat::log1p +#else +#define compat_exp std::exp +#define compat_ceil std::ceil +#define compat_floor std::floor +#define compat_log std::log +#define compat_pow std::pow +#define compat_sqrt std::sqrt +#define compat_tan std::tan +#define compat_abs std::abs +#define compat_log1p std::log1p +#endif + +namespace { + +#if !defined(__CUDA_ARCH__) && !defined(__HIPCC__) +// we cannot use std::isnan directly due to some incompatibility of +// gcc constexpr'ing and nvcc +using std::isnan; +#endif + +// Here sampler_t should be function type scalar_t(void). For gpu +// "sampler" is a device function, but since ROCM doesn't have +// equivalent to nvstd::function, we use a template type parameter to +// capture it. +template +struct BaseSampler { + sampler_t sampler; + C10_DEVICE BaseSampler(const sampler_t& sampler): sampler(sampler) {} + C10_DEVICE scalar_t sample() { + return sampler(); + } +}; + +// The function `sample_gamma` is +// is adapted from Numpy's distributions.c implementation. +// It is MIT licensed, so here is the copyright: + +/* Copyright 2005 Robert Kern (robert.kern@gmail.com) + * + * Permission is hereby granted, free of charge, to any person obtaining a + * copy of this software and associated documentation files (the + * "Software"), to deal in the Software without restriction, including + * without limitation the rights to use, copy, modify, merge, publish, + * distribute, sublicense, and/or sell copies of the Software, and to + * permit persons to whom the Software is furnished to do so, subject to + * the following conditions: + * + * The above copyright notice and this permission notice shall be included + * in all copies or substantial portions of the Software. + * + * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS + * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF + * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. + * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY + * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, + * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE + * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. +*/ + +template +C10_DEVICE scalar_t sample_gamma(scalar_t alpha, BaseSampler& standard_uniform, BaseSampler& standard_normal) { + accscalar_t scale = 1.0f; + + // Boost alpha for higher acceptance probability. + if (alpha < 1.0f) { + if (alpha == 0.f) return 0.f; + scale *= compat_pow(1 - standard_uniform.sample(), 1.0f / alpha); + alpha += 1.0f; + } + + // This implements the acceptance-rejection method of Marsaglia and Tsang (2000) + // doi:10.1145/358407.358414 + const accscalar_t d = alpha - 1.0f / 3.0f; + const accscalar_t c = 1.0f / compat_sqrt(9.0f * d); + for (;;) { + accscalar_t x, y; + do { + x = standard_normal.sample(); + y = 1.0f + c * x; + } while (y <= 0); + const accscalar_t v = y * y * y; + const accscalar_t u = 1 - standard_uniform.sample(); + const accscalar_t xx = x * x; + if (u < 1.0f - 0.0331f * xx * xx) + return static_cast(scale * d * v); + if (compat_log(u) < 0.5f * xx + d * (1.0f - v + compat_log(v))) + return static_cast(scale * d * v); + } +} + +/* the functions stirling_approx_tail, binomial_inversion, and btrs are adapted + * from TensorFlow's random_binomial_op.cc implementation. That code is under + * copyright: 2019 The TensorFlow Authors. + * + * It was released under the Apache License, Version 2.0 (the "License"), available at: + * http://www.apache.org/licenses/LICENSE-2.0 + */ + +template +C10_DEVICE scalar_t stirling_approx_tail(scalar_t k) { + const static scalar_t kTailValues[] = { + 0.0810614667953272, + 0.0413406959554092, + 0.0276779256849983, + 0.02079067210376509, + 0.0166446911898211, + 0.0138761288230707, + 0.0118967099458917, + 0.0104112652619720, + 0.00925546218271273, + 0.00833056343336287 + }; + if (k <= 9) { + return kTailValues[static_cast(k)]; + } + scalar_t kp1sq = (k + 1) * (k + 1); + return (1.0 / 12 - (1.0 / 360 - 1.0 / 1260 / kp1sq) / kp1sq) / (k + 1); +} + + +template +C10_DEVICE scalar_t binomial_inversion(scalar_t count, scalar_t prob, BaseSampler& standard_uniform) { + accscalar_t U; + accscalar_t geom_sum = 0; + scalar_t num_geom = 0; + + accscalar_t logprob = compat_log1p(-prob); + + while (true) { + U = standard_uniform.sample(); + accscalar_t geom = compat_ceil(compat_log(U) / logprob); + geom_sum += geom; + if (geom_sum > count) { + break; + } + num_geom = num_geom + 1; + } + return num_geom; +} + +template +C10_DEVICE scalar_t btrs(scalar_t count, scalar_t prob, BaseSampler& standard_uniform) { + scalar_t k; + accscalar_t U, V, us; + + // This is spq in the paper. + const accscalar_t stddev = compat_sqrt(count * prob * (1 - prob)); + + // Other coefficients for Transformed Rejection sampling. + const accscalar_t b = 1.15 + 2.53 * stddev; + const accscalar_t a = -0.0873 + 0.0248 * b + 0.01 * prob; + const accscalar_t c = count * prob + 0.5; + const accscalar_t v_r = 0.92 - 4.2 / b; + const accscalar_t r = prob / (1 - prob); + + const accscalar_t alpha = (2.83 + 5.1 / b) * stddev; + const accscalar_t m = compat_floor((count + 1) * prob); + + while (true) { + U = standard_uniform.sample() - 0.5; + V = standard_uniform.sample(); + + us = 0.5 - compat_abs(U); + k = static_cast(compat_floor((2 * a / us + b) * U + c)); + + // Reject non-sensical answers. + if (k < 0 || k > count) { + continue; + } + // Region for which the box is tight, and we can return our calculated value. + // This should happen 0.86 * v_r times. In the limit as n * p is large, + // the acceptance rate converges to ~79% (and in the lower regime it is ~24%). + if (us >= 0.07 && V <= v_r) { + return k; + } + + // This deviates from Hormann's BTRS algorithm, as there is a log missing. + // For all (u, v) pairs outside of the bounding box, this calculates the + // transformed-reject ratio. + V = compat_log(V * alpha / (a / (us * us) + b)); + accscalar_t upperbound = + ((m + 0.5) * compat_log((m + 1) / (r * (count - m + 1))) + + (count + 1) * compat_log((count - m + 1) / (count - k + 1)) + + (k + 0.5) * compat_log(r * (count - k + 1) / (k + 1)) + + stirling_approx_tail(m) + stirling_approx_tail(count - m) - + stirling_approx_tail(k) - stirling_approx_tail(count - k)); + + if (V <= upperbound) { + return k; + } + } +} + +template +C10_DEVICE scalar_t sample_binomial(scalar_t count, scalar_t prob, BaseSampler& standard_uniform) { + if (count <= 0.0 || prob <= 0.0) { + return 0; + } else if (prob >= 1.0) { + return count; + } else if (prob <= 0.5) { + if (count * prob >= 10.0) { + // btrs + return btrs(count, prob, standard_uniform); + } else { + // binomial inversion + return binomial_inversion(count, prob, standard_uniform); + } + } else if (prob > 0.5) { + scalar_t qprob = 1.0 - prob; + if (count * qprob >= 10.0) { + // btrs + return count - btrs(count, qprob, standard_uniform); + } else { + // count - binomial inversion + return count - binomial_inversion(count, qprob, standard_uniform); + } + } else { + // prob is nan? + return static_cast(NAN); + } +} + +/* + * This function is derived from the implementation of the digamma function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library] in ATen/native/Math.h. + */ +template +C10_DEVICE inline scalar_t digamma_one(scalar_t x) { + constexpr accscalar_t PSI_10 = 2.25175258906672110764; + if (x == 0) { + return INFINITY; + } + accscalar_t additional_summand = 0; + int x_is_integer = x == compat_floor(x); + if (x < 0) { + if (x_is_integer) { + return INFINITY; + } + // it is more standard to write this as recursion, but + // nvcc does not like that + additional_summand = -c10::pi / + compat_tan(c10::pi * x); + x = 1 - x; + } + + // Push x to be >= 10 + accscalar_t result = 0; + while (x < 10) { + result -= 1 / x; + x += 1; + } + if (x == 10) { + return result + PSI_10 + additional_summand; + } + + // Compute asymptotic digamma + static const accscalar_t A[] = { + 8.33333333333333333333E-2, + -2.10927960927960927961E-2, + 7.57575757575757575758E-3, + -4.16666666666666666667E-3, + 3.96825396825396825397E-3, + -8.33333333333333333333E-3, + 8.33333333333333333333E-2, + }; + + accscalar_t y = 0; + if (x < 1.0e17f) { + accscalar_t z = 1.0 / (x * x); + y = z * polevl(z, A, 6); + } + return static_cast( + result + compat_log(x) - (0.5f / x) - y + additional_summand); +} + +// Computes the reparameterized gradient -(d/dalpha cdf(x;alpha)) / pdf(x;alpha) +// for random number x drawn from a standard Gamma distribution Gamma(alpha). +template +C10_HOST_DEVICE scalar_t standard_gamma_grad_one(scalar_t alpha_, scalar_t x_) { + // Use a Taylor series expansion for small x. + accscalar_t x = static_cast(x_); + accscalar_t alpha = static_cast(alpha_); + if (x < 0.8f) { + accscalar_t numer = 1; + accscalar_t denom = alpha; + auto series1 = numer / denom; + auto series2 = numer / (denom * denom); + for (int i = 1; i <= 5; ++i) { + numer *= -x / static_cast(i); + denom += 1; + series1 += numer / denom; + series2 += numer / (denom * denom); + } + const auto pow_x_alpha = compat_pow(x, alpha); + const auto gamma_pdf = compat_pow(x, alpha - 1) * compat_exp(-x); + const auto gamma_cdf = pow_x_alpha * series1; + const auto gamma_cdf_alpha = + (compat_log(x) - digamma_one(alpha)) * + gamma_cdf - + pow_x_alpha * series2; + const auto result = -gamma_cdf_alpha / gamma_pdf; + return isnan(result) ? static_cast( 0.f ) : static_cast(result); + } + + // Use a Rice saddle point expansion for large alpha. + if (alpha > 8.0f) { + if (0.9f * alpha <= x && x <= 1.1f * alpha) { + const auto numer_1 = 1 + 24 * alpha * (1 + 12 * alpha); + const auto numer_2 = 1440 * (alpha * alpha) + 6 * x * (53 - 120 * x) + - 65 * x * x / alpha + alpha * (107 + 3600 * x); + const auto denom = 1244160 * (alpha * alpha) * (alpha * alpha); + return static_cast(numer_1 * numer_2 / denom); + } + const auto denom = compat_sqrt(8 * alpha); + const auto term2 = denom / (alpha - x); + const auto term3 = compat_pow( + x - alpha - alpha * compat_log(x / alpha), + static_cast(-1.5)); + const auto term23 = (x < alpha) ? term2 - term3 : term2 + term3; + const auto term1 = compat_log(x / alpha) * term23 - + compat_sqrt(2 / alpha) * (alpha + x) / ((alpha - x) * (alpha - x)); + const auto stirling = 1 + 1 / (12 * alpha) * (1 + 1 / (24 * alpha)); + const auto numer = x * term1; + return static_cast(-stirling * numer / denom); + } + + // Use a bivariate rational approximation to the reparameterized gradient. + const auto u = compat_log(x / alpha); + const auto v = compat_log(alpha); + static const accscalar_t coef_uv[3][8] = { + {0.16009398, -0.094634809, 0.025146376, -0.0030648343, + 1, 0.32668115, 0.10406089, 0.0014179084}, + {0.53487893, 0.1298071, 0.065735949, -0.0015649758, + 0.16639465, 0.020070113, -0.0035938915, -0.00058392623}, + {0.040121004, -0.0065914022, -0.0026286047, -0.0013441777, + 0.017050642, -0.0021309326, 0.00085092367, -1.5247877e-07}, + }; + accscalar_t coef_v[8]; + for (int i = 0; i < 8; ++ i) { + coef_v[i] = coef_uv[0][i] + u * (coef_uv[1][i] + u * coef_uv[2][i]); + } + const auto p = coef_v[0] + v * (coef_v[1] + v * (coef_v[2] + v * coef_v[3])); + const auto q = coef_v[4] + v * (coef_v[5] + v * (coef_v[6] + v * coef_v[7])); + return static_cast(compat_exp(p / q)); +} + +// Approximate reparameterized gradient of Beta(x,alpha,beta) wrt alpha. +// Assumes x is close to zero and uses a Taylor expansion. +template +C10_DEVICE inline scalar_t _beta_grad_alpha_small(scalar_t x, scalar_t alpha, scalar_t beta) { + const scalar_t factor = digamma_one(alpha) + - digamma_one(alpha + beta) - compat_log(x); + scalar_t numer = 1; + scalar_t series = numer / alpha * (factor + 1 / alpha); + for (int i = 1; i <= 10; ++i) { + scalar_t casted_i = static_cast(i); + numer *= (casted_i - beta) * x / casted_i; + const scalar_t denom = alpha + casted_i; + series += numer / denom * (factor + 1 / denom); + } + const scalar_t result = x * compat_pow(1 - x, -beta) * series; + return isnan(result) ? static_cast( 0.f ) : result; +} + +// Approximate reparameterized gradient of Beta(x,alpha,beta) wrt beta. +// Assumes x is close to zero and uses a Taylor expansion. +template +C10_DEVICE inline scalar_t _beta_grad_beta_small(scalar_t x, scalar_t alpha, scalar_t beta) { + const scalar_t factor = digamma_one(alpha + beta) - digamma_one(beta); + scalar_t numer = 1, betas = 1, dbetas = 0, series = factor / alpha; + for (int i = 1; i <= 8; ++i) { + scalar_t casted_i = static_cast(i); + numer *= -x / casted_i; + dbetas = dbetas * (beta - casted_i) + betas; + betas = betas * (beta - casted_i); + series += numer / (alpha + casted_i) * (dbetas + factor * betas); + } + const scalar_t result = -compat_pow(1 - x, 1 - beta) * series; + return isnan(result) ? static_cast( 0.f ) : result; +} + +// Approximate reparameterized gradient of Beta(x,alpha,beta) wrt alpha. +// Assumes alpha and beta are both large and uses a Rice saddle point expansion. +// To ensure numerical stability, this computation is performed at higher precision. +template +C10_DEVICE inline scalar_t _beta_grad_alpha_mid(accscalar_t x, accscalar_t alpha, accscalar_t beta) { + const accscalar_t total = alpha + beta; + const accscalar_t mean = alpha / total; + const accscalar_t std = compat_sqrt(alpha * beta / (total + 1)) / total; + if (mean - 0.1 * std <= x && x <= mean + 0.1 * std) { + // Avoid the singularity at x = mean. + const accscalar_t poly = 47 * x * (beta * beta) * (beta * beta) + alpha * ( + (43 + 20 * (16 + 27 * beta) * x) * (beta * beta) * beta + alpha * ( + 3 * (59 + 180 * beta - 90 * x) * (beta * beta) + alpha * ( + (453 + 1620 * beta * (1 - x) - 455 * x) * beta + alpha * ( + 8 * (1 - x) * (135 * beta - 11))))); + const accscalar_t prefactor_num = (1 + 12 * alpha) * (1 + 12 * beta) / (total * total); + const accscalar_t prefactor_den = 12960 * alpha * alpha * alpha * beta * beta * (1 + 12 * total); + return prefactor_num / (1 - x) * poly / prefactor_den; + } + const accscalar_t prefactor = -x / compat_sqrt(2 * alpha * beta / total); + const accscalar_t stirling = (1 + 1 / (12 * alpha) + 1 / (288 * alpha * alpha)) + * (1 + 1 / (12 * beta) + 1 / (288 * beta * beta)) + / (1 + 1 / (12 * total) + 1 / (288 * total * total)); + const accscalar_t term1_num = 2 * (alpha * alpha) * (x - 1) + alpha * beta * (x - 1) - x * (beta * beta); + const accscalar_t axbx = alpha * (x - 1) + beta * x; + const accscalar_t term1_den = compat_sqrt(2 * alpha / beta) * compat_pow(total, static_cast(1.5f)) * axbx * axbx; + const accscalar_t term1 = term1_num / term1_den; + const accscalar_t term2 = 0.5f * compat_log(alpha / (total * x)); + const accscalar_t term3_num = compat_sqrt(8 * alpha * beta / total); + const accscalar_t term3_den = beta * x + alpha * (x - 1); + const accscalar_t term3 = term3_num / term3_den; + const accscalar_t term4_base = beta * compat_log(beta / (total * (1 - x))) + + alpha * compat_log(alpha / (total * x)); + const accscalar_t term4 = compat_pow(term4_base, static_cast(-1.5f)); + const accscalar_t term1234 = term1 + term2 * (term3 + (x < mean ? term4 : -term4)); + return static_cast(stirling * prefactor * term1234); +} + +// Computes a scaled reparameterized gradient +// -(d/dalpha cdf(x;alpha,beta)) / pdf(x;alpha,beta) / (1-x) +// for random number x drawn from a Beta distribution Beta(alpha,beta). +// This function inputs total=alpha+beta to make it easy to implement +// Dirichlet reparameterized gradients in terms of Betas. +template +C10_HOST_DEVICE inline scalar_t dirichlet_grad_one(scalar_t x, scalar_t alpha, scalar_t total) { + accscalar_t x_ = static_cast(x); + accscalar_t alpha_ = static_cast(alpha); + accscalar_t total_ = static_cast(total); + + const scalar_t beta = total - alpha; + const accscalar_t beta_ = total_ - alpha_; + const scalar_t boundary = total * x * (1 - x); + + // Use an asymptotic approximation for x close to 0. + if (x <= 0.5f && boundary < 2.5f) { + return _beta_grad_alpha_small(x, alpha, beta); + } + + // Use an asymptotic approximation for x close to 1. + if (x >= 0.5f && boundary < 0.75f) { + return -_beta_grad_beta_small(1 - x, beta, alpha); + } + + // Use an asymptotic approximation when alpha and (total - alpha) are both large. + if (alpha > 6 && beta > 6) { + return _beta_grad_alpha_mid(x_, alpha_, beta_); + } + + // Use a rational correction to an analytic approximation. + static const accscalar_t c[2][3][3][4] = { + {{{1.003668233, -0.01061107488, -0.0657888334, 0.01201642863}, + {0.6336835991, -0.3557432599, 0.05486251648, -0.001465281033}, + {-0.03276231906, 0.004474107445, 0.002429354597, -0.0001557569013}}, + {{0.221950385, -0.3187676331, 0.01799915743, 0.01074823814}, + {-0.2951249643, 0.06219954479, 0.01535556598, 0.001550077057}, + {0.02155310298, 0.004170831599, 0.001292462449, 6.976601077e-05}}, + {{-0.05980841433, 0.008441916499, 0.01085618172, 0.002319392565}, + {0.02911413504, 0.01400243777, -0.002721828457, 0.000751041181}, + {0.005900514878, -0.001936558688, -9.495446725e-06, 5.385558597e-05}}}, + {{{1, -0.02924021934, -0.04438342661, 0.007285809825}, + {0.6357567472, -0.3473456711, 0.05454656494, -0.002407477521}, + {-0.03301322327, 0.004845219414, 0.00231480583, -0.0002307248149}}, + {{0.5925320577, -0.1757678135, 0.01505928619, 0.000564515273}, + {0.1014815858, -0.06589186703, 0.01272886114, -0.0007316646956}, + {-0.007258481865, 0.001096195486, 0.0003934994223, -4.12701925e-05}}, + {{0.06469649321, -0.0236701437, 0.002902096474, -5.896963079e-05}, + {0.001925008108, -0.002869809258, 0.0008000589141, -6.063713228e-05}, + {-0.0003477407336, 6.959756487e-05, 1.097287507e-05, -1.650964693e-06}}}, + }; + const accscalar_t u = compat_log(x_); + const accscalar_t a = compat_log(alpha_) - u; + const accscalar_t b = compat_log(total_) - a; + const accscalar_t pow_u[3] = {1, u, u * u}; + const accscalar_t pow_a[3] = {1, a, a * a}; + accscalar_t p = 0.0; + accscalar_t q = 0.0; + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 3; ++j) { + const accscalar_t ua = pow_u[i] * pow_a[j]; + p += ua * (c[0][i][j][0] + b * (c[0][i][j][1] + b * (c[0][i][j][2] + b * c[0][i][j][3]))); + q += ua * (c[1][i][j][0] + b * (c[1][i][j][1] + b * (c[1][i][j][2] + b * c[1][i][j][3]))); + } + } + const accscalar_t approx = x_ * (digamma_one(total_) - digamma_one(alpha_)) / beta_; + return static_cast(p / q * approx); +} + +} // namespace diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/EmbeddingBag.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/EmbeddingBag.h new file mode 100644 index 0000000000000000000000000000000000000000..eb29e1171dcd60a5d9fbc5cb35b488603c1b0886 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/EmbeddingBag.h @@ -0,0 +1,153 @@ +#include +#include +#include + +#ifdef USE_FBGEMM +#include +#endif + +namespace at::native { + +enum class EmbeddingBagMode { + SUM = 0, + MEAN = 1, + MAX = 2, +}; + +[[maybe_unused]] static bool operator==(int64_t op1, EmbeddingBagMode op2) { + return op1 == static_cast(op2); +} + +[[maybe_unused]] static bool operator!=(int64_t op1, EmbeddingBagMode op2) { + return !(op1 == op2); +} + +void check_arguments( + const Tensor& weight, + const Tensor& indices, + const Tensor& offsets, + const int64_t mode, + const std::optional& per_sample_weights, + bool include_last_offset); + +void make_bag_size_out( + Tensor& bag_size_out, + const Tensor& offsets, + const Tensor& indices, + const int64_t mode, + const bool include_last_offset, + const bool requires_grad); + +void make_max_indices_out( + Tensor& max_indices_out, + const Tensor& weight, + const Tensor& indices, + const Tensor& offsets, + const Tensor& bag_size, + const int64_t mode, + bool include_last_offset); + +void make_offset2bag_out( + Tensor& offset2bag, + Tensor& output, + const Tensor& weight, + const Tensor& indices, + const Tensor& offsets, + const int64_t mode, + const std::optional& per_sample_weights, + const int64_t padding_idx = -1); + +#ifdef USE_FBGEMM + +template +struct _CallbackAndBlockSize { + using TCallback = typename fbgemm::EmbeddingSpMDMKernelSignature::Type; + + int64_t blockSize = -1; + TCallback callback = nullptr; + + static TCallback generateCallback(int64_t block_size) { + return fbgemm::GenerateEmbeddingSpMDM( + block_size, + has_weight, + /* normalize_by_lengths */false, + /* prefetch */16, + /* is_weight_positional */false, + /* use_offsets */true); + } + + _CallbackAndBlockSize() = default; + + explicit _CallbackAndBlockSize(std::optional maybe_block_size) + : blockSize(maybe_block_size.value_or(-1)) + , callback(maybe_block_size.has_value() ? generateCallback(maybe_block_size.value()) : nullptr) + {} +}; + +template +struct _EmbeddingBagKernelCacheImpl : private StorageMixins... { + + _EmbeddingBagKernelCacheImpl() = default; + // use each of the mixins to store corresponding kernel and block size + explicit _EmbeddingBagKernelCacheImpl(std::optional maybe_block_size) + : StorageMixins(maybe_block_size)... + {} + + // this method is thread safe (call sites may call from different threads) + template + typename _CallbackAndBlockSize::TCallback + getCallback(int64_t block_size) const { + // if the cache doesn't store the kernel for the incoming block size + // (so it is different from the one stored in corresponding mixin) + // regenerate the kernel (not writing it into the cache so we avoid locks) + if (block_size != _CallbackAndBlockSize::blockSize) { + return _CallbackAndBlockSize::generateCallback(block_size); + } + // else retrieve the cached kernel from the corresponding mixin + return _CallbackAndBlockSize::callback; + } +}; + +// instantiate the cache with the list of storage mixins +// for each of the 8 _EmbeddingBagKernelCache* usages in the EmbeddingBag.cpp impl file +using _EmbeddingBagKernelCache = _EmbeddingBagKernelCacheImpl< + _CallbackAndBlockSize, + _CallbackAndBlockSize, + _CallbackAndBlockSize, + _CallbackAndBlockSize, + _CallbackAndBlockSize, + _CallbackAndBlockSize, + _CallbackAndBlockSize, + _CallbackAndBlockSize>; +#else +struct _EmbeddingBagKernelCache { + explicit _EmbeddingBagKernelCache(std::optional /* maybe_block_size */) {} +}; +#endif + +void _embedding_bag_cpu_impl_out(Tensor& output, Tensor& offset2bag, + Tensor& bag_size, Tensor* max_indices, + const Tensor &weight, const Tensor &indices, + const Tensor &offsets, const int64_t mode = 0, + const std::optional& per_sample_weights = std::nullopt, + bool include_last_offset = false, + int64_t padding_idx = -1, + _EmbeddingBagKernelCache* fbgemm_kernel_cache = nullptr); + +void _embedding_bag_cpu_out( + at::Tensor& output, + at::Tensor& offset2bag, + at::Tensor& bag_size, + at::Tensor* p_max_indices, + const at::Tensor& weight, + const at::Tensor& indices, + const at::Tensor& offsets, + const bool scale_grad_by_freq, + const int64_t mode, + const bool sparse, + const std::optional& per_sample_weights, + const bool include_last_offset, + const std::optional& padding_idx, + _EmbeddingBagKernelCache* fbgemm_kernel_cache = nullptr); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Fill.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Fill.h new file mode 100644 index 0000000000000000000000000000000000000000..d37198030128b1d5337f45bc81d6f8989041ac24 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Fill.h @@ -0,0 +1,21 @@ +// Functions that fill Tensors with constants. Implementations are in Fill.cpp. + +#pragma once + +#include + +namespace c10 { +class Scalar; +} + +namespace at { +class Tensor; +struct TensorIterator; + +namespace native { + +DECLARE_DISPATCH(void(*)(TensorIterator&, const c10::Scalar&), fill_stub) + +Tensor& fill_out(Tensor& self, const Scalar& value); + +}} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ForeachUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ForeachUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..56b7a6f98e779c0a83c04d0c58b6b6cf2577e875 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ForeachUtils.h @@ -0,0 +1,409 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + +#include +#include + +namespace at::native { +namespace { +// Check if tensor list has either a boolean tensor or a integer tensor +inline bool has_integral_tensor(TensorList tensors, const bool includeBool) { + return std::any_of( + tensors.begin(), tensors.end(), [&includeBool](const auto& t) { + return at::isIntegralType(t.scalar_type(), includeBool); + }); +} +// check if tensor list has bool tensors +inline bool has_bool_tensor(TensorList tensors) { + return std::any_of(tensors.begin(), tensors.end(), [](const auto& t) -> bool { + return t.scalar_type() == ScalarType::Bool; + }); +} + +// Check foreach API restrictions +// - Tensor lists must be non-empty. +// - All TensorLists and ScalarLists must have the same number of elements. +// - Corresponding tensors must have the same size. +inline void check_foreach_api_restrictions(TensorList tensors) { + TORCH_CHECK(!tensors.empty(), "Tensor list must have at least one tensor."); +} + +inline void check_foreach_api_restrictions( + TensorList tensors, + ArrayRef scalars) { + check_foreach_api_restrictions(tensors); + TORCH_CHECK( + tensors.size() == scalars.size(), + "Tensor list must have same number of elements as scalar list."); +} + +inline void check_foreach_api_restrictions( + TensorList tensors1, + TensorList tensors2) { + TORCH_CHECK(!tensors1.empty(), "Tensor list must have at least one tensor."); + TORCH_CHECK(!tensors2.empty(), "Tensor list must have at least one tensor."); + TORCH_CHECK( + tensors1.size() == tensors2.size(), + "Tensor lists must have the same number of tensors, got ", + tensors1.size(), + " and ", + tensors2.size()); +} + +inline void check_foreach_api_restrictions( + TensorList tensors1, + TensorList tensors2, + TensorList tensors3) { + TORCH_CHECK(!tensors1.empty(), "Tensor list must have at least one tensor."); + TORCH_CHECK(!tensors2.empty(), "Tensor list must have at least one tensor."); + TORCH_CHECK(!tensors3.empty(), "Tensor list must have at least one tensor."); + TORCH_CHECK( + tensors1.size() == tensors2.size(), + "Tensor lists must have the same number of tensors, got ", + tensors1.size(), + " and ", + tensors2.size()); + TORCH_CHECK( + tensors1.size() == tensors3.size(), + "Tensor lists must have the same number of tensors, got ", + tensors1.size(), + " and ", + tensors3.size()); +} + +inline void check_foreach_api_restrictions( + TensorList tensors1, + TensorList tensors2, + TensorList tensors3, + ArrayRef scalars) { + check_foreach_api_restrictions(tensors1, tensors2, tensors3); + TORCH_CHECK( + tensors1.size() == scalars.size(), + "Tensor list must have same number of elements as scalar list, got ", + tensors1.size(), + " and ", + scalars.size()); +} + +inline void check_foreach_api_restrictions( + TensorList tensors1, + TensorList tensors2, + ArrayRef scalars) { + check_foreach_api_restrictions(tensors1, tensors2); + TORCH_CHECK( + tensors1.size() == scalars.size(), + "Tensor list must have same number of elements as scalar list, got ", + tensors1.size(), + " and ", + scalars.size()); +} + +// Helper function called in check_fast_path_restrictions to check whether all +// corresponding tensors (aligning in index across the tensorLists) share the +// same device and dtype. +inline bool _check_tensors_share_device_and_dtype( + ArrayRef tensorLists, + const bool skip_dtype_check = false) { + const auto expected_dtype = tensorLists[0][0].dtype(); + const auto expected_device = tensorLists[0][0].device(); + + auto is_tensor_okay = [&](const Tensor& tensor) { + return (skip_dtype_check || tensor.dtype() == expected_dtype) && + tensor.device() == expected_device && tensor.layout() == at::kStrided && + tensor.is_non_overlapping_and_dense(); + }; + + for (const auto& tensorList : tensorLists) { + for (const auto& tensor : tensorList) { + if (!is_tensor_okay(tensor)) { + return false; + } + } + } + + return true; +} + +// Helper function called in check_fast_path_restrictions to check if +// corresponding tensors in tensor lists have the same sizes and strides. +inline bool _check_tensors_share_sizes_and_strides( + ArrayRef tensorLists) { + auto is_diff_stride = [](const IntArrayRef& size, + const IntArrayRef& left_stride, + const IntArrayRef& right_stride) -> bool { + const size_t size_size = size.size(); + for (const auto dim : c10::irange(size_size)) { + if (size[dim] == 1) + continue; + if (left_stride[dim] != right_stride[dim]) { + return true; + } + } + return false; + }; + for (const auto i : c10::irange(1, tensorLists.size())) { + for (const auto j : c10::irange(tensorLists[0].size())) { + if (tensorLists[0][j].sizes() != tensorLists[i][j].sizes() || + is_diff_stride( + tensorLists[0][j].sizes(), + tensorLists[0][j].strides(), + tensorLists[i][j].strides())) { + return false; + } + } + } + + return true; +} + +// Helper function called in check_fast_path_restrictions to check whether +// all tensors type promote properly with the scalars in scalarList. This +// function assumes that _check_tensors_share_device_and_dtype has already been +// called so that all corresponding tensors in tensorLists have the same dtype. +// Then, it is sufficient to check the type promotion with just one tensorList. +inline bool _check_tensors_do_type_promotion_with_scalars( + TensorList tensorList, + ArrayRef scalarList = {}, + bool does_op_promote_integer_inputs_to_float = false) { + for (const auto i : c10::irange(tensorList.size())) { + // For division, integer inputs will result in float. + if (does_op_promote_integer_inputs_to_float) { + if (at::isIntegralType( + tensorList[i].scalar_type(), /*includeBool*/ true)) { + return false; + } + } + if (!scalarList.empty()) { + const auto& scalar = + scalarList.size() == 1 ? scalarList[0] : scalarList[i]; + const auto& tensor = tensorList[i]; + // note(mkozuki): This check might be responsible for + // `_foreach_add(bool_tensors, bool_tensors)` being pushed to slow path. + if (tensor.scalar_type() != at::native::result_type(scalar, tensor)) { + return false; + } + } + } + + return true; +} + +// To go via 'fast' path, several conditions must be satisfied +// - All tensors in all lists must have the same dtype. +// - All tensors must be on the same device +// - All tensors must have strided layout +// - All tensors must be non-overlapping and dense +// - Resulting tensor must have the same dtype as the input one + +// [note: what's ``does_op_promote_integer_inputs_to_float=true``?] +// ``does_op_promote_integer_inputs_to_float=true`` means that the result of +// the op will be float even if inputs are integer or boolean, which +// currently fast path does not support. In short, this flag, when +// turned on, gatekeeps the op from going down the fastpath. + +// Please, make sure to call check_foreach_api_restrictions before calling this +// method. There is a set of preconditions that have to be satisfied. +inline bool check_fast_path_restrictions( + ArrayRef tensorLists, + ArrayRef scalarList = {}, + bool does_op_promote_integer_inputs_to_float = false) { + return _check_tensors_share_device_and_dtype(tensorLists) && + _check_tensors_share_sizes_and_strides(tensorLists) && + _check_tensors_do_type_promotion_with_scalars( + tensorLists[0], + scalarList, + does_op_promote_integer_inputs_to_float); +} + +inline std::vector convert_tensor_to_scalar_list( + const Tensor& scalarList_, + int64_t expect_length) { + std::vector scalarList; + TORCH_CHECK( + scalarList_.device() == c10::kCPU, + "Expected scalars to be on CPU, got ", + scalarList_.device(), + " instead."); + TORCH_CHECK( + scalarList_.is_contiguous(), "Expected scalars to be contiguous."); + TORCH_CHECK( + scalarList_.dim() == 1, + "Expected packed scalar Tensor to be of dimension 1. Got ", + scalarList_.dim(), + " instead."); + AT_DISPATCH_ALL_TYPES_AND_COMPLEX_AND4( + kComplexHalf, + kHalf, + kBool, + kBFloat16, + scalarList_.scalar_type(), + "convert_tensor_to_scalar_list", + [&]() { + const scalar_t* scalar_data = scalarList_.const_data_ptr(); + TORCH_CHECK( + (expect_length == scalarList_.size(0)), + "Expected length of scalars to match input of length ", + expect_length, + " but got ", + scalarList_.size(0), + " instead."); + for (int64_t i = 0; i < scalarList_.size(0); i++) { + scalarList.emplace_back(scalar_data[i]); + } + }); + return scalarList; +} + +// see: [note: what's ``does_op_promote_integer_inputs_to_float=true``?] +inline bool can_use_fast_route( + ArrayRef tensorLists, + ArrayRef scalarList = {}, + bool does_op_promote_integer_inputs_to_float = false) { + return check_fast_path_restrictions( + tensorLists, scalarList, does_op_promote_integer_inputs_to_float); +} + +// see: [note: what's ``does_op_promote_integer_inputs_to_float=true``?] +inline bool can_use_fast_route( + TensorList tensors1, + TensorList tensors2, + bool does_op_promote_integer_inputs_to_float = false) { + return can_use_fast_route( + {tensors1, tensors2}, {}, does_op_promote_integer_inputs_to_float); +} + +using DeviceDtypeKey = std::pair; +using IndicesT = std::vector; +using nested_optional_tensorvec_t = + std::vector>>; +using TensorsAndIndicesT = std::pair; +using FlatMap = std::unordered_map< + DeviceDtypeKey, + TensorsAndIndicesT, + ParamsHash>; + +inline FlatMap _group_tensors_by_first_tensors_device_and_dtype( + const nested_optional_tensorvec_t& nested_tensorlist, + const bool with_indices) { + FlatMap grouped_tensors_with_indices; + + TORCH_CHECK(!nested_tensorlist.empty()); + TORCH_CHECK(!nested_tensorlist[0].empty()); + const auto num_lists = nested_tensorlist.size(); + const auto num_tensors = nested_tensorlist[0].size(); + + TORCH_CHECK(std::all_of( + nested_tensorlist.cbegin(), + nested_tensorlist.cend(), + [&](const auto& tensorlist) -> bool { + // note(crcrpar): Allow empty tensorlists following + // ref: + // https://github.com/pytorch/pytorch/blob/85885301fd3c6adb8b9dc3cf7afadf6945566684/torch/utils/_foreach_utils.py#L21-L24 + return tensorlist.size() == num_tensors || tensorlist.size() == 0; + })); + + for (const auto& tensor_index : c10::irange(num_tensors)) { + const auto key = [&]() -> DeviceDtypeKey { + const auto t = nested_tensorlist[0][tensor_index]; + TORCH_CHECK( + t.has_value(), + "Tensors of the first list of nested Tensor lists are supposed to be defined but ", + "the ", + tensor_index, + "-th Tensor is not."); + return {t->device(), t->scalar_type()}; + }(); + TORCH_CHECK( + std::all_of( + nested_tensorlist.cbegin(), + nested_tensorlist.cend(), + [&](const auto& tensorlist) -> bool { + if (tensorlist.size() == 0) { + return true; + } + const auto& tensor = tensorlist[tensor_index]; + // note(crcrpar): Currently the scope of this function is + // optimizers so there could be `state_steps` and other scalars + // whose elements are float tensors no matter what the parameter's + // dtype is. + if (!tensor.has_value()) { + return true; + } else { + const auto s = tensor->scalar_type(); + const auto d = tensor->device(); + // Note: `step` or `state_step` is float32 by default. + if (key.first == d) { + return key.second == s || s == at::ScalarType::Float || + s == at::ScalarType::Double; + } else if (d.is_cpu()) { + // note(crcrpar): There are some test cases (e.g. + // TestOptim::test_adam) where state_steps are on CPU and the + // others are on CUDA. Currently a state_step Tensor has the + // dtype of float. + return s == at::ScalarType::Float || + s == at::ScalarType::Double; + } else { + return false; + } + } + }), + "Tensors of the same index must be on the same device and the same dtype except `step` tensors that can be CPU and float32/64 notwithstanding"); + if (!grouped_tensors_with_indices.count(key)) { + grouped_tensors_with_indices.insert( + {key, + TensorsAndIndicesT{ + [&]() -> nested_optional_tensorvec_t { + nested_optional_tensorvec_t nested_tensorvec; + nested_tensorvec.reserve(num_lists); + for (const auto& i : c10::irange(num_lists)) { + std::vector> tensors; + if (!nested_tensorlist[i].empty()) { + // NB: num_tensors is the max possible length for any of + // the inner lists of tensor references. Reserving the max + // trades memory for perf. This should not have significant + // impact. + tensors.reserve(num_tensors); + } + nested_tensorvec.emplace_back(tensors); + } + return nested_tensorvec; + }(), + [&]() -> IndicesT { + if (!with_indices) { + return {}; + } else { + IndicesT indices; + indices.reserve(num_tensors); + return indices; + } + }()}}); + } + for (const auto& list_index : c10::irange(num_lists)) { + if (!nested_tensorlist[list_index].empty()) { + grouped_tensors_with_indices[key].first[list_index].emplace_back( + nested_tensorlist[list_index][tensor_index]); + } + } + if (with_indices) { + grouped_tensors_with_indices[key].second.emplace_back(tensor_index); + } + } + + return grouped_tensors_with_indices; +} + +} // namespace +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FractionalMaxPooling.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FractionalMaxPooling.h new file mode 100644 index 0000000000000000000000000000000000000000..58c07ac63d72e3eff7554513584e206aaa179978 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FractionalMaxPooling.h @@ -0,0 +1,80 @@ +#pragma once +#include +#include +#include + +namespace at::native { + +template +inline std::vector generate_intervals( + scalar_t sample, + int64_t inputSize, + int64_t outputSize, + int64_t poolSize) { + std::vector sequence(outputSize); + if (outputSize > 1) { + scalar_t alpha = static_cast(inputSize - poolSize) / + static_cast(outputSize - 1); + + for (const auto i : c10::irange(outputSize - 1)) { + sequence[i] = + static_cast((i + sample) * alpha) - static_cast(sample * alpha); + } + } + if (outputSize > 0) { + sequence[outputSize - 1] = inputSize - poolSize; + } + return sequence; +} + +template +inline void fractional_max_pool_check_shape( + const Tensor& input, + const Tensor& randomSamples) { + + TORCH_CHECK( + input.scalar_type() == randomSamples.scalar_type(), + "Expect _random_samples to have the same dtype as input"); + + int64_t ndimension = randomSamples.ndimension(); + TORCH_CHECK( + ndimension == 3, + "Expect _random_samples to have 3 dimensions, got ", ndimension); + + int64_t N = randomSamples.size(0); + int64_t C = randomSamples.size(1); + int64_t D = randomSamples.size(2); + + int64_t input_batch = 0, input_channel = 0; + if (ndim == 2) { + // fractional_max_pool2d + if (input.ndimension() == 3) { + input_batch = 1; + input_channel = input.size(0); + } else { + input_batch = input.size(0); + input_channel = input.size(1); + } + } else { + // factional_max_pool3d + if (input.ndimension() == 4) { + input_batch = 1; + input_channel = input.size(0); + } else { + input_batch = input.size(0); + input_channel = input.size(1); + } + } + + TORCH_CHECK( + N >= input_batch, + "Expect _random_samples.size(0) no less then input batch size."); + TORCH_CHECK( + C == input_channel, + "Expect _random_samples.size(1) equals to input channel size."); + TORCH_CHECK( + D == ndim, + "Expect _random_samples.size(2) equals to ", ndim, "; got ", D, "."); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FunctionOfAMatrixUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FunctionOfAMatrixUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..f37f7e5b0affc221f70aa4abea513b20f59cd90a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FunctionOfAMatrixUtils.h @@ -0,0 +1,20 @@ +#pragma once + +#include +#include + +namespace at { +struct TensorIterator; + +namespace native { + +using _compute_linear_combination_fn = void(*)( + TensorIterator& iter, + int64_t in_stride, + int64_t coeff_stride, + int64_t num_summations +); + +DECLARE_DISPATCH(_compute_linear_combination_fn, _compute_linear_combination_stub) + +}} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FusedAdagrad.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FusedAdagrad.h new file mode 100644 index 0000000000000000000000000000000000000000..16e8f2909837b061c4c1251618e2a60675112aee --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FusedAdagrad.h @@ -0,0 +1,20 @@ +#include +#include + +namespace at::native { + +using fused_adagrad_fn = void (*)( + const at::Tensor& param, + const at::Tensor& grad, + const at::Tensor& state_sum, + const at::Tensor& state_step, + const double lr, + const double lr_decay, + const double weight_decay, + const double eps, + const bool maximize, + const float* grad_scale_ptr); + +DECLARE_DISPATCH(fused_adagrad_fn, fused_adagrad_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FusedAdam.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FusedAdam.h new file mode 100644 index 0000000000000000000000000000000000000000..db93f10bb95f168da44b24cb506ff5c04e3da06e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FusedAdam.h @@ -0,0 +1,27 @@ +#include +#include + +namespace at::native { + +enum class ADAM_MODE : uint8_t { ORIGINAL = 0, ADAMW = 1 }; + +using fused_adam_fn = void (*)( + const at::Tensor& param, + const at::Tensor& grad, + const at::Tensor& exp_avg, + const at::Tensor& exp_avg_sq, + const at::Tensor& max_exp_avg_sq, + const at::Tensor& state_step, + const double lr, + const double beta1, + const double beta2, + const double weight_decay, + const double eps, + const bool amsgrad, + const bool maximize, + const float* grad_scale_ptr, + const ADAM_MODE); + +DECLARE_DISPATCH(fused_adam_fn, fused_adam_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FusedSGD.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FusedSGD.h new file mode 100644 index 0000000000000000000000000000000000000000..e10b0209ff053bfde03b4493c735b9ac6899459b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/FusedSGD.h @@ -0,0 +1,21 @@ +#include +#include + +namespace at::native { + +using fused_sgd_fn = void (*)( + const at::Tensor& param, + const at::Tensor& grad, + const at::Tensor& momentum_buffer, + const double weight_decay, + const double momentum, + const double lr, + const double dampening, + const bool nesterov, + const bool maximize, + const bool is_first_step, + const float* grad_scale_ptr); + +DECLARE_DISPATCH(fused_sgd_fn, fused_sgd_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Gelu.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Gelu.h new file mode 100644 index 0000000000000000000000000000000000000000..9482e2161e2198b25e3f54b7ec40dc22e152cf54 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Gelu.h @@ -0,0 +1,33 @@ +#pragma once + +#include +#include + +namespace at::native { +// These constants control the approximation behavior of gelu function. +enum class GeluType { + None, // Baseline Gelu + Tanh, // Tanh Gelu Approximation + END +}; + +inline GeluType get_gelutype_enum(const std::string_view approximate) { + if (approximate == "none") { + return GeluType::None; + } else if (approximate == "tanh") { + return GeluType::Tanh; + } else { + TORCH_CHECK(false, "approximate argument must be either none or tanh."); + } +} + +inline std::string gelutype_to_string(const GeluType type) { + switch(type) { + case GeluType::None: return "none"; + case GeluType::Tanh: return "tanh"; + default: TORCH_CHECK(false, "unknown GELU type: ", static_cast(type)); + } +} + + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/GridSampler.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/GridSampler.h new file mode 100644 index 0000000000000000000000000000000000000000..509a305fe4b5ed33c128b06fec8473816eeca46a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/GridSampler.h @@ -0,0 +1,298 @@ +#pragma once + +#include +#include +#include +#include + +#include + +namespace at::native { + +using detail::GridSamplerInterpolation; +using detail::GridSamplerPadding; + +// Unnormalizes a coordinate from the -1 to +1 scale to its pixel index value, +// where we view each pixel as an area between (idx - 0.5) and (idx + 0.5). +// if align_corners: -1 and +1 get sent to the centers of the corner pixels +// -1 --> 0 +// +1 --> (size - 1) +// scale_factor = (size - 1) / 2 +// if not align_corners: -1 and +1 get sent to the image edges +// -1 --> -0.5 +// +1 --> (size - 1) + 0.5 == size - 0.5 +// scale_factor = size / 2 +template +static inline scalar_t grid_sampler_unnormalize(scalar_t coord, int64_t size, + bool align_corners) { + if (align_corners) { + // unnormalize coord from [-1, 1] to [0, size - 1] + return ((coord + 1) / 2) * (size - 1); + } else { + // unnormalize coord from [-1, 1] to [-0.5, size - 0.5] + return ((coord + 1) * size - 1) / 2; + } +} + +// grid_sampler_unnormalize_set_grad works the same as grid_sampler_unnormalize +// except that it also returns the `d output / d input` via pointer argument +// `grad_in`. +// This is useful in the backward pass of grid_sampler. +template +static inline scalar_t grid_sampler_unnormalize_set_grad(scalar_t coord, int64_t size, + bool align_corners, scalar_t *grad_in) { + if (align_corners) { + // unnormalize coord from [-1, 1] to [0, size - 1] + *grad_in = static_cast(size - 1) / 2; + return ((coord + 1) / 2) * (size - 1); + } else { + // unnormalize coord from [-1, 1] to [-0.5, size - 0.5] + *grad_in = static_cast(size) / 2; + return ((coord + 1) * size - 1) / 2; + } +} + +// Clips coordinates to between 0 and clip_limit - 1 +template +static inline scalar_t clip_coordinates(scalar_t in, int64_t clip_limit) { + return std::min(static_cast(clip_limit - 1), std::max(in, static_cast(0))); +} + +// clip_coordinates_set_grad works similarly to clip_coordinates except that +// it also returns the `d output / d input` via pointer argument `grad_in`. +// This is useful in the backward pass of grid_sampler. +template +static inline scalar_t clip_coordinates_set_grad(scalar_t in, int64_t clip_limit, + scalar_t *grad_in) { + // Note that it is important for the gradient calculation that borders + // are considered out of bounds. + if (in <= static_cast(0)) { + *grad_in = static_cast(0); + return static_cast(0); + } else { + scalar_t max = static_cast(clip_limit - 1); + if (in >= max) { + *grad_in = static_cast(0); + return max; + } else { + *grad_in = static_cast(1); + return in; + } + } +} + +// Reflects coordinates until they fall between low and high (inclusive). +// The bounds are passed as twice their value so that half-integer values +// can be represented as ints. +template +static inline scalar_t reflect_coordinates(scalar_t in, int64_t twice_low, + int64_t twice_high) { + if (twice_low == twice_high) { + return static_cast(0); + } + scalar_t min = static_cast(twice_low) / 2; + scalar_t span = static_cast(twice_high - twice_low) / 2; + in = std::fabs(in - min); + // `fmod` returns same sign as `in`, which is positive after the `fabs` above. + scalar_t extra = std::fmod(in, span); + int flips = static_cast(std::floor(in / span)); + if (flips % 2 == 0) { + return extra + min; + } else { + return span - extra + min; + } +} + +// reflect_coordinates_set_grad works similarly to reflect_coordinates except +// that it also returns the `d output / d input` via pointer argument +// `grad_in`. +// This is useful in the backward pass of grid_sampler. +template +static inline scalar_t reflect_coordinates_set_grad(scalar_t in, int64_t twice_low, + int64_t twice_high, scalar_t *grad_in) { + if (twice_low == twice_high) { + *grad_in = static_cast(0); + return static_cast(0); + } + int grad_in_mult_; + scalar_t min = static_cast(twice_low) / 2; + scalar_t span = static_cast(twice_high - twice_low) / 2; + in = in - min; + if (in < static_cast(0)) { + grad_in_mult_ = -1; + in = -in; + } else { + grad_in_mult_ = 1; + } + // `fmod` returns same sign as `in`, which is positive after the `if` above. + scalar_t extra = std::fmod(in, span); + int flips = static_cast(std::floor(in / span)); + if (flips % 2 == 0) { + *grad_in = static_cast(grad_in_mult_); + return extra + min; + } else { + *grad_in = static_cast(-grad_in_mult_); + return span - extra + min; + } +} + +// Mapping the out-of-boundary points back into boundary +// This would only affect padding_mode=border or reflection +template +static inline scalar_t compute_coordinates(scalar_t coord, int64_t size, + GridSamplerPadding padding_mode, + bool align_corners) { + if (padding_mode == GridSamplerPadding::Border) { + // clip coordinates to image borders + coord = clip_coordinates(coord, size); + } else if (padding_mode == GridSamplerPadding::Reflection) { + // reflect coordinates by image borders + if (align_corners) { + coord = reflect_coordinates(coord, 0, 2*(size - 1)); + } else { + coord = reflect_coordinates(coord, -1, 2*size - 1); + } + // clip coordinates to image borders + coord = clip_coordinates(coord, size); + } + return coord; +} + +// Computes the pixel source index value for a grid coordinate +template +static inline scalar_t grid_sampler_compute_source_index( + scalar_t coord, + int64_t size, + GridSamplerPadding padding_mode, + bool align_corners) { + coord = grid_sampler_unnormalize(coord, size, align_corners); + coord = compute_coordinates(coord, size, padding_mode, align_corners); + return coord; +} + +// grid_sampler_compute_source_index_set_grad works similarly to +// grid_sampler_compute_source_index except that it also returns the +// `d output / d input` via pointer argument `grad_in`. +// This is useful in the backward pass of grid_sampler. +template +static inline scalar_t grid_sampler_compute_source_index_set_grad( + scalar_t coord, + int64_t size, + GridSamplerPadding padding_mode, + bool align_corners, + scalar_t *grad_in) { + scalar_t grad_clip, grad_refl; + coord = grid_sampler_unnormalize_set_grad(coord, size, align_corners, grad_in); + if (padding_mode == GridSamplerPadding::Border) { + // clip coordinates to image borders + coord = clip_coordinates_set_grad(coord, size, &grad_clip); + *grad_in = (*grad_in) * grad_clip; + } else if (padding_mode == GridSamplerPadding::Reflection) { + // reflect coordinates by image borders + if (align_corners) { + coord = reflect_coordinates_set_grad(coord, 0, 2*(size - 1), &grad_refl); + } else { + coord = reflect_coordinates_set_grad(coord, -1, 2*size - 1, &grad_refl); + } + // clip coordinates to image borders + coord = clip_coordinates_set_grad(coord, size, &grad_clip); + *grad_in = (*grad_in) * grad_refl * grad_clip; + } + return coord; +} + +static inline bool within_bounds_2d(int64_t h, int64_t w, int64_t H, int64_t W) { + return h >= 0 && h < H && w >= 0 && w < W; +} + +static inline bool within_bounds_3d(int64_t d, int64_t h, int64_t w, int64_t D, int64_t H, int64_t W) { + return d >= 0 && d < D && h >= 0 && h < H && w >= 0 && w < W; +} + +template +static inline scalar_t get_value_bounded( + const scalar_t* data, + scalar_t x, + scalar_t y, + int64_t W, + int64_t H, + int64_t sW, + int64_t sH, + GridSamplerPadding padding_mode, + bool align_corners) { + + x = compute_coordinates(x, W, padding_mode, align_corners); + y = compute_coordinates(y, H, padding_mode, align_corners); + + int64_t ix = static_cast(x); + int64_t iy = static_cast(y); + + if (within_bounds_2d(iy, ix, H, W)) { + return data[iy * sH + ix * sW]; + } + return static_cast(0); +} + +template +static inline void safe_add_2d(scalar_t *data, int64_t h, int64_t w, + int64_t sH, int64_t sW, int64_t H, int64_t W, + scalar_t delta) { + if (within_bounds_2d(h, w, H, W)) { + data[h * sH + w * sW] += delta; + } +} + +template +static inline void safe_add_3d(scalar_t *data, int64_t d, int64_t h, int64_t w, + int64_t sD, int64_t sH, int64_t sW, + int64_t D, int64_t H, int64_t W, + scalar_t delta) { + if (within_bounds_3d(d, h, w, D, H, W)) { + data[d * sD + h * sH + w * sW] += delta; + } +} + +template +static inline void add_value_bounded( + scalar_t* data, + scalar_t x, + scalar_t y, + int64_t W, + int64_t H, + int64_t sW, + int64_t sH, + scalar_t delta, + GridSamplerPadding padding_mode, + bool align_corners) { + + x = compute_coordinates(x, W, padding_mode, align_corners); + y = compute_coordinates(y, H, padding_mode, align_corners); + + int64_t ix = static_cast(x); + int64_t iy = static_cast(y); + + safe_add_2d(data, iy, ix, sH, sW, H, W, delta); +} + +// Calculate the differential of the cubic convolution, i.e. `d coeff / d x` +template +static inline void get_cubic_coefficients_grad( + scalar_t coeffs[4], + scalar_t t) { + + // Must be the same as forward calculation in + // aten/src/ATen/native/UpSample.h:get_cubic_upsample_coefficients + scalar_t A = -0.75; + + scalar_t x; + x = -1 - t; // 1 < x = |-1 - tx| < 2 + coeffs[0] = (-3 * A * x - 10 * A ) * x - 8 * A; + x = -t; // x = |0 - tx| <= 1 + coeffs[1] = (-3 * (A + 2) * x - 2 * (A + 3)) * x; + x = 1 - t; // x = |1 - tx| <= 1 + coeffs[2] = (3 * (A + 2) * x - 2 * (A + 3)) * x; + x = 2 - t; // 1 < x = |2 - tx| < 2 + coeffs[3] = (3 * A * x - 10 * A) * x + 8 * A; +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/GridSamplerUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/GridSamplerUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..f783043c7961222302ed0ff2514ffbf138cafac2 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/GridSamplerUtils.h @@ -0,0 +1,105 @@ +#pragma once + +// See NOTE: [Tensor vs. TensorBase] +// https://github.com/pytorch/pytorch/pull/66979 +#include +#include +#include + +namespace at::native { + +namespace detail { + +enum class GridSamplerInterpolation {Bilinear, Nearest, Bicubic}; +enum class GridSamplerPadding {Zeros, Border, Reflection}; + +} // namespace detail + +using detail::GridSamplerInterpolation; +using detail::GridSamplerPadding; + +// See NOTE [ grid_sampler Native Functions ]. +inline void check_grid_sampler_common( + const TensorBase& input, + const TensorBase& grid +) { + auto input_opt = input.options(); + auto grid_opt = grid.options(); + + TORCH_CHECK( + input.defined(), + "grid_sampler(): expected input to not be undefined"); + TORCH_CHECK( + grid.defined(), + "grid_sampler(): expected grid to not be undefined"); + TORCH_CHECK( + input_opt.device() == grid_opt.device(), + "grid_sampler(): expected input and grid to be on same device, but input " + "is on ", input_opt.device(), " and grid is on ", grid_opt.device()); + TORCH_CHECK( + input_opt.layout() == kStrided && grid_opt.layout() == kStrided, + "grid_sampler(): expected input and grid to have torch.strided layout, but " + "input has ", input_opt.layout(), " and grid has ", grid_opt.layout()); + TORCH_CHECK( + input.size(0) == grid.size(0), + "grid_sampler(): expected grid and input to have same batch size, but got " + "input with sizes ", input.sizes(), " and grid with sizes ", grid.sizes()); + TORCH_CHECK( + grid.size(-1) == input.dim() - 2, + "grid_sampler(): expected grid to have size ", input.dim() - 2, " in last " + "dimension, but got grid with sizes ", grid.sizes()); + + for (const auto i : c10::irange(2, input.dim())) { + TORCH_CHECK(input.size(i) > 0, + "grid_sampler(): expected input to have non-empty spatial dimensions, " + "but input has sizes ", input.sizes(), " with dimension ", i, " being " + "empty"); + } +} + +// See NOTE [ grid_sampler Native Functions ]. +inline void check_grid_sampler_2d( + const TensorBase& input, + const TensorBase& grid +) { + TORCH_CHECK( + input.dim() == 4 && input.dim() == grid.dim(), + "grid_sampler(): expected 4D input and grid with same number of " + "dimensions, but got input with sizes ", input.sizes(), + " and grid with sizes ", grid.sizes()); +} + +// See NOTE [ grid_sampler Native Functions ]. +inline void check_grid_sampler_3d( + const TensorBase& input, + const TensorBase& grid, + int64_t interpolation_mode +) { + TORCH_CHECK( + input.dim() == 5 && input.dim() == grid.dim(), + "grid_sampler(): expected 5D input and grid with same number of " + "dimensions, but got input with sizes ", input.sizes(), + " and grid with sizes ", grid.sizes()); + TORCH_CHECK( + !(input.dim() == 5 && + static_cast(interpolation_mode) == + GridSamplerInterpolation::Bicubic), + "grid_sampler(): bicubic interpolation only supports 4D input"); +} + +// See NOTE [ grid_sampler Native Functions ]. +// cudnn does not support inputs larger than 1024. +inline bool cond_cudnn_grid_sampler( + const TensorBase& input, + const TensorBase& grid +) { + return ( + at::native::cudnn_is_acceptable(input) && + at::native::cudnn_is_acceptable(grid) && + at::native::canUse32BitIndexMath(input) && + at::native::canUse32BitIndexMath(grid) && + input.dim() == 4 && + input.sym_size(1) <= 1024); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Histogram.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Histogram.h new file mode 100644 index 0000000000000000000000000000000000000000..6877912d3af573e9746328a8388af771d0d92cb6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Histogram.h @@ -0,0 +1,16 @@ +#pragma once + +#include +#include + +namespace at::native { + +using histogramdd_fn = void(*)(const Tensor&, const std::optional&, bool, Tensor&, const TensorList&); +using histogramdd_linear_fn = void(*)(const Tensor&, const std::optional&, bool, Tensor&, const TensorList&, bool); +using histogram_select_outer_bin_edges_fn = void(*)(const Tensor& input, const int64_t N, std::vector &leftmost_edges, std::vector &rightmost_edges); + +DECLARE_DISPATCH(histogramdd_fn, histogramdd_stub) +DECLARE_DISPATCH(histogramdd_linear_fn, histogramdd_linear_stub) +DECLARE_DISPATCH(histogram_select_outer_bin_edges_fn, histogram_select_outer_bin_edges_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/IndexKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/IndexKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..e4b34dbf318132fbfeb1207cdfe667e9c90334e4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/IndexKernel.h @@ -0,0 +1,41 @@ +#pragma once +#include +#include + +namespace at { +class Tensor; +class TensorBase; +struct TensorIterator; +struct TensorIteratorBase; +} + +namespace c10 { +class Scalar; +} + +namespace at::native { + +using index_fn = void(*)(TensorIteratorBase &, IntArrayRef indexed_sizes, IntArrayRef indexed_strides); +using index_fill_fn = void(*)(TensorIterator & iter, int64_t dim, int64_t self_dim_size, int64_t self_dim_stride, const Scalar& source); +using index_copy_fn = void(*)(TensorIterator & iter, int64_t dim, int64_t self_dim_size, int64_t self_dim_stride); +using index_put_fn = void(*)(TensorIterator &, IntArrayRef indexed_sizes, IntArrayRef indexed_strides, bool accumulate); +using put_fn = void(*)(TensorIterator & iter, const TensorBase& self, const bool accumulate); +using take_fn = void(*)(TensorIterator & iter, const TensorBase& input); +using flip_fn = void(*)(TensorIterator &, const bool); +using masked_fill_fn = void(*)(TensorIterator &, const Scalar& scalar); +using masked_select_fn = void(*)(TensorIterator &, int64_t orig_stride); +using masked_scatter_fn = void(*)(TensorIterator &, const TensorBase &); + +DECLARE_DISPATCH(index_fn, index_stub) +DECLARE_DISPATCH(index_fill_fn, index_fill_stub) +DECLARE_DISPATCH(index_copy_fn, index_copy_stub) +DECLARE_DISPATCH(index_put_fn, index_put_stub) +DECLARE_DISPATCH(put_fn, put_stub) +DECLARE_DISPATCH(take_fn, take_stub) +DECLARE_DISPATCH(flip_fn, flip_stub) +DECLARE_DISPATCH(masked_fill_fn, masked_fill_stub) +DECLARE_DISPATCH(masked_select_fn, masked_select_serial_stub) +DECLARE_DISPATCH(masked_select_fn, masked_select_stub) +DECLARE_DISPATCH(masked_scatter_fn, masked_scatter_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/IndexingUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/IndexingUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..c442b2232a967f3a9d84b783dce3c29987294643 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/IndexingUtils.h @@ -0,0 +1,164 @@ +#pragma once +#include +#include +#include +#include +#include + +namespace at::native { + +[[noreturn]] +static void invalid_mask(const Tensor & self, int64_t idx, const Tensor & mask, int64_t maskIdx) { + TORCH_CHECK_INDEX(false, "The shape of the mask ", mask.sizes(), " at index ", maskIdx, + " does not match the shape of the indexed tensor ", self.sizes(), " at index ", idx); +} + +[[maybe_unused]] static std::vector expandTensors( + const Tensor& self, + IOptTensorListRef indices) { + // If indices come in as ByteTensor or BoolTensor (masks), expand them into + // the equivalent indexing by LongTensors + std::vector result; + for (const auto& index_opt : indices) { + if (!index_opt.has_value()) { + result.emplace_back(); + } else { + const auto& index = *index_opt; + if (index.scalar_type() == kByte || index.scalar_type() == kBool) { + if (index.scalar_type() == kByte) { + TORCH_WARN("indexing with dtype torch.uint8 is now deprecated," \ + " please use a dtype torch.bool instead."); + } + // The sizes of the ByteTensor mask or bool tensor must match the sizes of the + // corresponding dimensions in self + for (const auto j : c10::irange(index.dim())) { + int64_t srcIdx = static_cast(result.size() + j); + if (index.size(j) != self.size(srcIdx)) { + invalid_mask(self, srcIdx, index, j); + } + } + // Replace with nonzeros + auto nonzero = index.nonzero(); + for (const auto j : c10::irange(index.dim())) { + result.emplace_back(nonzero.select(1, j)); + } + } else { + result.emplace_back(index); + } + } + } + return result; +} + +[[maybe_unused]] static void checkIndexTensorTypes( + IOptTensorListRef indices, + bool allow_int = false) { + for (const auto& tensor : indices) { + if (tensor.has_value() && tensor->defined()) { + auto scalarType = tensor->scalar_type(); + if (allow_int) { + if (scalarType != kLong && scalarType != kByte && scalarType != kBool && scalarType != kInt) { + TORCH_CHECK_INDEX(false, "tensors used as indices must be long, int, byte or bool tensors"); + } + } else { + if (scalarType != kLong && scalarType != kByte && scalarType != kBool) { + TORCH_CHECK_INDEX(false, "tensors used as indices must be long, byte or bool tensors"); + } + } + } + } +} + +inline torch::List> toListOfOptionalTensors(ArrayRef list) { + torch::List> result; + result.reserve(list.size()); + for (const Tensor& a : list) { + result.push_back(a); + } + return result; +} + +inline torch::List> toListOfOptionalTensors(ArrayRef list) { + torch::List> result; + result.reserve(list.size()); + for (const IValue& a : list) { + result.push_back(a.isTensor() ? std::optional(a.toTensor()) : std::optional()); + } + return result; +} + +[[maybe_unused]] static bool hasContiguousSubspace(TensorList tl) { + // true if all the non-null tensors are adjacent + auto isDefined = [](const Tensor & tensor){ return tensor.defined(); }; + auto isNull = [](const Tensor & tensor){ return !tensor.defined(); }; + auto start = std::find_if(tl.begin(), tl.end(), isDefined); + auto stop = std::find_if(tl.rbegin(), tl.rend(), isDefined); + auto it = std::find_if(start, stop.base(), isNull); + return it == stop.base(); +} + +// Transposes the tensor and indices together so that all the non-null indices +// index the first k dimensions of the tensor. Returns the transposed tensor +// and the reordered indices. For example: +// transposeToFront(tensor, {nullptr, a, nullptr, b}) +// returns +// tensor.permute([1, 3, 0, 2]), {a, b, nullptr, nullptr} +[[maybe_unused]] static std::tuple> transposeToFront( + const Tensor& self, + TensorList indices) { + std::vector dims; + std::vector transposedIndices; + dims.reserve(self.dim()); + for (const auto i : c10::irange(self.dim())) { + if (indices[i].defined()) { + dims.push_back(i); + transposedIndices.emplace_back(indices[i]); + } + } + for (const auto i : c10::irange(self.dim())) { + if (!indices[i].defined()) { + dims.push_back(i); + transposedIndices.emplace_back(); + } + } + return std::make_tuple(self.permute(dims), std::move(transposedIndices)); +} + +inline std::tuple, std::vector> +transposeToFrontAndInvPerm(const Tensor& self, TensorList indices) { + std::vector dims; + std::vector invPerm; + std::vector transposedIndices; + dims.reserve(self.dim()); + invPerm.resize(self.dim()); + for (const auto i : c10::irange(self.dim())) { + if (indices[i].defined()) { + dims.push_back(i); + transposedIndices.emplace_back(indices[i]); + } + } + for (const auto i : c10::irange(self.dim())) { + if (!indices[i].defined()) { + dims.push_back(i); + transposedIndices.emplace_back(); + } + } + for (const auto i : c10::irange(self.dim())) { + invPerm[dims[i]] = i; + } + return std::make_tuple(self.permute(dims), std::move(transposedIndices), std::move(invPerm)); +} + +struct AdvancedIndex { + AdvancedIndex(const Tensor& src, TensorList indices); + + Tensor src; + std::vector indices; + DimVector indexed_sizes; + DimVector indexed_strides; + int64_t dims_before; + int64_t dims_after; +}; + + +} //namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Lerp.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Lerp.h new file mode 100644 index 0000000000000000000000000000000000000000..88ca08c9bf51cbd72a1cd14c107c07f28668da8b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Lerp.h @@ -0,0 +1,46 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::native { + +template +C10_HOST_DEVICE C10_ALWAYS_INLINE bool is_lerp_weight_small(scalar_t weight) { + return std::abs(weight) < scalar_t(0.5); +} +template +C10_HOST_DEVICE C10_ALWAYS_INLINE bool is_lerp_weight_small(c10::complex weight) { + // Avoid the sqrt in abs(weight) + return (weight.real() * weight.real() + weight.imag() * weight.imag()) < scalar_t(0.25); +} + +template +C10_HOST_DEVICE C10_ALWAYS_INLINE scalar_t lerp(scalar_t self_, scalar_t end_, weight_t weight_) { + using opmath_t = at::opmath_type; + using opmath_weight_t = at::opmath_type; + + opmath_t self = self_; + opmath_t end = end_; + opmath_weight_t weight = weight_; + + // Conditional for better numeric. This has been discussed in + // https://github.com/pytorch/pytorch/pull/18871 + return is_lerp_weight_small(weight) + ? self + weight * (end - self) + : end - (end - self) * (opmath_t(1) - weight); +} + +using lerp_fn_scalar = void (*)( + at::TensorIteratorBase& iter, + const Scalar& weight); + +using lerp_fn_tensor = void (*)( + at::TensorIteratorBase& iter); + +DECLARE_DISPATCH(lerp_fn_scalar, lerp_kernel_scalar_weight) +DECLARE_DISPATCH(lerp_fn_tensor, lerp_kernel_tensor_weight) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/LinearAlgebra.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/LinearAlgebra.h new file mode 100644 index 0000000000000000000000000000000000000000..1374321e898d2afbcc50b548d78176b08df7b5ae --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/LinearAlgebra.h @@ -0,0 +1,17 @@ +#pragma once + +#include + +namespace c10 { +class Scalar; +} + +namespace at { +struct TensorIterator; +} + +namespace at::native { + +using addr_fn = void (*)(TensorIterator &, const Scalar& beta, const Scalar& alpha); +DECLARE_DISPATCH(addr_fn, addr_stub) +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/LinearAlgebraUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/LinearAlgebraUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..6717ccf0c99e05f1a3f1267222edaf70df289dc5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/LinearAlgebraUtils.h @@ -0,0 +1,624 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#include +#include +#include +#include +#endif + +namespace at::native { + +inline c10::MaybeOwned expect_resolved_conj(const Tensor& tensor) { + if (tensor.is_conj()) { + return c10::MaybeOwned::owned(tensor.resolve_conj()); + } else { + return c10::MaybeOwned::borrowed(tensor); + } +} + +inline DimVector batched_matrix_contiguous_strides( + const IntArrayRef sizes, + const bool f_contig = false) { + // f_contig chooses between the strides of a batch of Fortran (F-contiguous) + // and C-contiguous matrices + auto strides = c10::contiguous_strides(sizes); + auto dim = strides.size(); + + if (f_contig && dim >= 2) { + // Fix the strides of the last two dimensions, so that we return + // C-contiguous batches of F-contiguous matrices. + strides[dim - 1] = std::max(sizes[dim - 2], static_cast(1)); + strides[dim - 2] = 1; + } + return strides; +} + +/* + * Clones a Tensor so that the following conditions hold: + * If we think of a Tensor of having size (B, M, N), where B is any number + * of batch dimensions, then: + * - Each (M, N) matrix is in column major form + * - Let Tensor P have size (B, M, N) and Q have size (B, M', N'). + * Then when laid out in memory, the M by N matrix starting at + * P.data_ptr()[B * M * N] is of the same corresponding batch as the M' by N' + * matrix starting at Q.data_ptr()[B * M' * N']. + */ +inline Tensor cloneBatchedColumnMajor(const Tensor& src) { + // If src is already in batched column major format, then + // this will be efficient (no reordering of the data will occur) + // because the first transpose will make the tensor contiguous, + // and cloning a contiguous tensor is fast. + auto result = src.mT().clone(at::MemoryFormat::Contiguous); + result.transpose_(-2, -1); + return result; +} + +/* + * contig chooses between C-contig (true) and F-contig (false) + */ +inline c10::MaybeOwned borrow_else_clone(const bool cond, const Tensor& borrow, const Tensor& clone, const bool contig) { + return cond ? c10::MaybeOwned::borrowed(borrow) + : c10::MaybeOwned::owned(contig ? clone.clone(MemoryFormat::Contiguous) + : cloneBatchedColumnMajor(clone)); +} + +/* + * This method is designed to be a faster alternative to + * `cloneBatchedColumnMajor` with some additional features, + * namely: + * 1. It uses `copy` instead of `clone` which could be much faster. + * 2. `nrows` parameter used to create inputs with the number of rows larger + * than the original input, which is required for some LAPACK/MAGMA methods. + * 3. `desired_batch_size` is used to create copies with the batch size + * which is either the original batch size of the input, or its larger + * broadcasted shape. + */ +inline Tensor copyBatchedColumnMajor(const Tensor& src, int64_t nrows = -1, + at::OptionalIntArrayRef desired_batch_sizes = std::nullopt) { + nrows = (nrows == -1) ? src.size(-2) : nrows; + auto copy_sizes = desired_batch_sizes.has_value() + ? desired_batch_sizes.value().vec() + : IntArrayRef(src.sizes().data(), src.dim() - 2).vec(); + copy_sizes.insert(copy_sizes.end(), {nrows, src.size(-1)}); + const auto copy_strides = batched_matrix_contiguous_strides(copy_sizes, /*f-contig*/true); + auto copy = at::empty_strided(copy_sizes, copy_strides, src.options()); + copy.narrow(-2, 0, src.size(-2)).copy_(src); + return copy; +} + +/* + * Given batches of matrices with arbitrary batch dim, + * computes the number of batches. + */ +inline int64_t batchCount(const Tensor& batched_matrices) { + int64_t result = 1; + for (int64_t i = 0; i < batched_matrices.ndimension() - 2; i++) { + result *= batched_matrices.size(i); + } + return result; +} + +// Computes the number of elements of a matrix in a batched matrix tensor +inline int64_t matrixStride(const Tensor& batched_matrices) { + return batched_matrices.size(-1) * batched_matrices.size(-2); +} + +// Validates input shapes for operations on batches of square matrices (inverse, cholesky, symeig, eig) +inline void checkIsMatrix(const Tensor& A, const char* const f_name, const char* const arg_name = "A") { + TORCH_CHECK(A.dim() >= 2, f_name, ": The input tensor ", arg_name, " must have at least 2 dimensions."); +} +inline void squareCheckInputs(const Tensor& self, const char* const f_name, const char* const arg_name = "A") { + checkIsMatrix(self, f_name, arg_name); + TORCH_CHECK(self.sym_size(-1) == self.sym_size(-2), + f_name, + ": ", arg_name, " must be batches of square matrices, " + "but they are ", self.sym_size(-2), " by ", self.sym_size(-1), " matrices"); +} + +inline void checkInputsSolver(const Tensor& A, + const Tensor& B, + const bool left, + const char* const f_name) { + squareCheckInputs(A, f_name, "A"); + checkIsMatrix(B, f_name, "B"); + TORCH_CHECK(left ? A.size(-2) == B.size(-2) : A.size(-1) == B.size(-1), + f_name, ": Incompatible shapes of A and B for the equation ", + left ? "AX = B" : "XA = B", + " (", A.size(-2), "x", A.size(-1), " and ", B.size(-2), "x", B.size(-1), ")"); +} + +inline bool is_row_or_column_contiguous(const Tensor& t) { + // This could be made more general, similar to how it's checked in matmul, which would allow to + // ellide the copy with strides such as (6, 12, 1, 3) or (3, 1, 9), but this is quite tricky. + // We choose to be conservative for simplicity + return t.is_contiguous() || t.transpose(-2, -1).is_contiguous(); +} + +inline TransposeType to_transpose_type(const bool contig, const bool conj) { + if (conj) { + if (contig) { TORCH_INTERNAL_ASSERT(false, "Invalid transpose type"); } + else { return TransposeType::ConjTranspose; } + } else { + if (contig) { return TransposeType::NoTranspose; } + else { return TransposeType::Transpose; } + } +} + + +// This function is designed to be used with linear algebra methods that minimize +// L(ax - b) = 0, where L is generally the identity map (`solve`, for example) +// or the L2 norm (`lstsq`). +// It is expected that `a` and `b` are contiguous tensors of column-major matrices +// (so that a.view({-1, a.size(-2), a.size(-1)}) succeeds, same for `b`), +// with the following additional properties: +// +// 1. a.dim() == b.dim() +// 2. a.shape[:-2] broadcasts over b.shape[:-2] +// 3. a.size(i) <= b.size(i) for i=0,..., a.dim() - 3 (only for batch dimensions) +// +// MAGMA/LAPACK modify tensor `a` in-place, and the main goal of this method +// is to be memory efficient, which means that if there exists an index i such that +// a.shape[i] < b.shape[i], 0 <= i <= a.dim() - 3, +// then instead of materializing copies of `a` in the broadcasted shape, we keep +// a buffer copy of `a` along with flags that check whether specific batch dimension +// indices for `a` were already accessed. If they were, we copy the data from the buffer +// into `a`. The number of copies does not exceed +// prod(max(a.shape[:-2], b.shape[:-2]) - a.shape[:-2] + 1) +// and this value is attained by tensors with non-empty batch dimensions. +// +// func_t `f` is a callable that is being supplied with +// scalar_t* a_working_ptr, scalar_t* b_working_ptr, int64_t a_linear_batch_idx. +// a_working_ptr and b_working_ptr can directly be passed to LAPACK/MAGMA routines, +// and a_linear_batch_idx is an index in the 3d representation which corresponds to +// the memory a_working_ptr points to, in other words: +// a_working_ptr == a.view({-1, a.size(-2), a.size(-1)}.select(0, a_linear_batch_idx).data_ptr(); +// a_linear_batch_idx is useful to store metadata related to `a`, such as, for example, +// its rank or singular values (see linalg_lstsq). +template +void batch_iterator_with_broadcasting(const Tensor& a, const Tensor& b, const func_t& f) { + IntArrayRef a_batch_sizes(a.sizes().data(), a.dim() - 2); + IntArrayRef b_batch_sizes(b.sizes().data(), b.dim() - 2); + + auto a_linear_batch_idx = at::arange(batchCount(a)).view(a_batch_sizes); + auto b_linear_batch_idx = at::arange(batchCount(b)).view(b_batch_sizes); + + TensorIterator iter = TensorIteratorConfig() + .set_check_mem_overlap(false) + .check_all_same_dtype(false) + .resize_outputs(false) + .add_output(b_linear_batch_idx) + .add_input(a_linear_batch_idx) + .build(); + + auto m = a.size(-2); + auto n = a.size(-1); + auto a_3d = a.view({batchCount(a), m, n}); + auto b_3d = b.view({batchCount(b), b.size(-2), b.size(-1)}); + + auto a_broadcasts_over_b = (a_batch_sizes != b_batch_sizes); + Tensor a_buffer, a_was_accessed, a_buffer_3d; + std::function check_if_copy_needed_for_a + = [](int64_t /*a_curr_linear_batch_idx*/){}; + if (a_broadcasts_over_b) { + a_buffer = at::empty_strided(a.sizes(), a.strides(), a.options()) + .copy_(a); + a_was_accessed = at::zeros(batchCount(a), at::kBool); + a_buffer_3d = a_buffer.view({batchCount(a), m, n}); + check_if_copy_needed_for_a = [&](int64_t a_curr_linear_batch_idx) { + auto* a_was_accessed_flag = a_was_accessed + .select(0, a_curr_linear_batch_idx) + .data_ptr(); + if (!(*a_was_accessed_flag)) { + *a_was_accessed_flag = true; + } + else { + a_3d.select(0, a_curr_linear_batch_idx) + .copy_(a_buffer_3d.select(0, a_curr_linear_batch_idx)); + } + }; + } + + auto loop = [&](char** data, const int64_t* strides, int64_t nelems) { + auto* b_batch_idx_ptr = data[0]; + auto* a_batch_idx_ptr = data[1]; + + for ([[maybe_unused]] const auto elem : c10::irange(nelems)) { + auto b_curr_linear_batch_idx = + *reinterpret_cast(b_batch_idx_ptr); + auto a_curr_linear_batch_idx = *reinterpret_cast(a_batch_idx_ptr); + + check_if_copy_needed_for_a(a_curr_linear_batch_idx); + + auto* a_working_ptr = a_3d.select(0, a_curr_linear_batch_idx) + .data_ptr(); + auto* b_working_ptr = b_3d.select(0, b_curr_linear_batch_idx) + .data_ptr(); + f(a_working_ptr, b_working_ptr, a_curr_linear_batch_idx); + + b_batch_idx_ptr += strides[0]; + a_batch_idx_ptr += strides[1]; + } + }; + iter.serial_for_each(loop, {0, batchCount(b)}); +} + +// Returns the epsilon value for floating types except half +inline double _get_epsilon(const ScalarType& sc_type) { + switch (sc_type) { + case at::ScalarType::Float: + return static_cast(std::numeric_limits::epsilon()); + case at::ScalarType::Double: + return std::numeric_limits::epsilon(); + default: + TORCH_CHECK(false, "This function doesn't handle types other than float and double"); + } +} + +// Validates input shapes and devices +// for linear solve methods (solve, cholesky_solve, lu_solve, triangular_solve) +inline void linearSolveCheckInputs(const Tensor& self, const Tensor& A, const char* name) { + TORCH_CHECK(self.device() == A.device(), + "Expected b and A to be on the same device, but found b on ", + self.device(), " and A on ", A.device(), " instead."); + + TORCH_CHECK(self.scalar_type() == A.scalar_type(), + "Expected b and A to have the same dtype, but found b of type ", + self.scalar_type(), " and A of type ", A.scalar_type(), " instead."); + + TORCH_CHECK(A.size(-1) == A.size(-2), + "A must be batches of square matrices, " + "but they are ", A.size(-2), " by ", A.size(-1), " matrices"); + + TORCH_CHECK(A.size(-1) == self.size(-2), + "Incompatible matrix sizes for ", name, ": each A " + "matrix is ", A.size(-1), " by ", A.size(-1), + " but each b matrix is ", self.size(-2), " by ", self.size(-1)); +} + +inline void checkFloatingOrComplex(const Tensor& t, const char* const f_name, const bool allow_low_precision_dtypes=true) { + auto dtype = t.scalar_type(); + TORCH_CHECK((at::isFloatingType(dtype) || at::isComplexType(dtype)), + f_name, ": Expected a floating point or complex tensor as input. Got ", dtype); + if (!allow_low_precision_dtypes) { + TORCH_CHECK(dtype == kFloat || dtype == kDouble || dtype == kComplexFloat || dtype == kComplexDouble, + f_name, ": Low precision dtypes not supported. Got ", dtype); + } +} + + +// Checks if all the Tensors in a TensorList are of the same dimensions +inline void checkAllSameDim(TensorList tensors, int64_t dim) { + for (auto &t : tensors) { + TORCH_CHECK(t.dim() == dim, "Tensor dimension is ", t.dim(), ", expected ", dim, " instead."); + } +} + +inline std::tuple, std::vector> _linalg_broadcast_batch_dims(const Tensor& arg1, const Tensor& arg2) { + // broadcast the batch dimensions of arg1 and arg2. + IntArrayRef arg1_batch_sizes(arg1.sizes().data(), arg1.ndimension() - 2); + IntArrayRef arg2_batch_sizes(arg2.sizes().data(), arg2.ndimension() - 2); + std::vector expand_batch_portion = infer_size(arg1_batch_sizes, arg2_batch_sizes); + + std::vector arg1_expand_size({expand_batch_portion}); + arg1_expand_size.insert(arg1_expand_size.end(), { arg1.size(-2), arg1.size(-1) }); + + std::vector arg2_expand_size({expand_batch_portion}); + arg2_expand_size.insert(arg2_expand_size.end(), { arg2.size(-2), arg2.size(-1) }); + return std::make_tuple(std::move(arg1_expand_size), std::move(arg2_expand_size)); +} + +inline std::tuple _linalg_broadcast_batch_dims(const Tensor& arg1, const Tensor& arg2, const char* name) { + // If there's no name we assume we don't want to check the errors + if (name != nullptr) { + linearSolveCheckInputs(arg1, arg2, name); + } + + auto [arg1_expand_size, arg2_expand_size] = at::native::_linalg_broadcast_batch_dims(arg1, arg2); + + auto arg1_broadcasted = arg1_expand_size == arg1.sizes() ? arg1 : arg1.expand(arg1_expand_size); + auto arg2_broadcasted = arg2_expand_size == arg2.sizes() ? arg2 : arg2.expand(arg2_expand_size); + return std::make_tuple(arg1_broadcasted, arg2_broadcasted); +} + +inline std::vector broadcast_batch_size(const Tensor& t1, const Tensor& t2, int64_t n_batch_dims) { + IntArrayRef t1_batch_sizes(t1.sizes().data(), n_batch_dims); + IntArrayRef t2_batch_sizes(t2.sizes().data(), n_batch_dims); + auto broadcasted_batch_sizes = infer_size(t1_batch_sizes, t2_batch_sizes); + return broadcasted_batch_sizes; +} + +// Return a permutation with the given axes moved to the end. +inline Tensor _move_to_end(const Tensor& self, IntArrayRef axes) { + const std::vector a = axes.vec(); + const int64_t ndim = self.ndimension(); + std::vector perm; + + for (const auto i : c10::irange(ndim)) { + auto it = std::find(a.begin(), a.end(), i); + if (it == a.end()) { + perm.push_back(i); + } + } + for (auto i : a) { + perm.push_back(i); + } + + TORCH_CHECK((int64_t)perm.size() == ndim, + "duplicate or invalid axis in 'dim' argument for tensor with ndim==", ndim); + + return self.permute(perm); +} + +// parse the "mode" param in linalg_qr: return a tuple of bools (compute_q, reduced) +inline std::tuple _parse_qr_mode(std::string_view mode) { + bool compute_q; + bool reduced; + if (mode == "reduced") { + compute_q = true; + reduced = true; + } else if (mode == "complete") { + compute_q = true; + reduced = false; + } else if (mode == "r") { + compute_q = false; + reduced = true; // this is actually irrelevant in this mode + } else { + TORCH_CHECK(false, "qr received unrecognized mode '", mode, + "' but expected one of 'reduced' (default), 'r', or 'complete'"); + } + return std::make_tuple(compute_q, reduced); +} + +// Function to compute sizes, strides and the extra columns for the Q matrix in the QR Decomposition +inline std::tuple _compute_geometry_for_Q( + const Tensor& input, + bool reduced) { + int64_t m = input.size(-2), n = input.size(-1); + int64_t n_columns_q; + + // We need to compute the required size of Q based on the `reduced` option + DimVector q_sizes(input.sizes()); + if (!reduced && m > n) { + q_sizes[input.dim() - 1] = m; + n_columns_q = m; + } else { + q_sizes[input.dim() - 1] = n; + n_columns_q = std::min(m, n); + } + auto q_strides = batched_matrix_contiguous_strides(q_sizes, /*f-contig*/true); + return std::make_tuple(q_sizes, q_strides, n_columns_q); +} + +inline bool svd_uses_cusolver(const Tensor& A) { + // if cusolver is available, it is used unconditionally + return A.is_cuda() + && at::globalContext().hasCuSOLVER() + && at::globalContext().linalgPreferredBackend() != at::LinalgBackend::Magma; +} + + +// Function used instead of .to so that the original strides are retained +// .to doesn't retain strides and make the output tensor contiguous +inline Tensor same_stride_to(const Tensor& original_tensor, const at::TensorOptions& options) { + auto strided_to = at::empty_strided(original_tensor.sizes(), + original_tensor.strides(), + options); + strided_to.copy_(original_tensor); + return strided_to; +} + +// Creates a dimension permutation array that can be given to `at::permute()`, which will shift +// the two specified dimensions to the end of a tensor, without changing the order of +// the other dimensions. `dim1` will be placed at the very end, and `dim0` will be +// placed just to the left of it. +// +// For instance, given a 4-D tensor, dimensions 1 and 3 can be shifted to the end by +// calling `create_dim_backshift_permutation(1, 3, 4)`. The resulting vector will +// be `vec(0, 2, 1, 3)`. +inline std::vector create_dim_backshift_permutation(int64_t dim0, int64_t dim1, int64_t ndim) { + TORCH_CHECK( + (dim0 != dim1) && (dim0 < ndim) && (dim0 >= 0) && (dim1 < ndim) && (dim1 >= 0), + "duplicate or invalid dimensions"); + std::vector permutation(ndim); + int64_t cur_permuted_dim = 0; + for (const auto dim_ind : c10::irange(ndim)) { + if ((dim_ind != dim0) && (dim_ind != dim1)) { + permutation[cur_permuted_dim++] = dim_ind; + } + } + permutation[cur_permuted_dim++] = dim0; + permutation[cur_permuted_dim] = dim1; + return permutation; +} + +// Creates a dimension permutation array that can be given to `at::permute()`, which +// will reverse a given permutation. +// The reverse permutation array is created by swapping the indices and their +// associated values from the given permutation array. +inline std::vector create_reverse_permutation(std::vector permutation) { + int64_t ndim = permutation.size(); + std::vector reverse_permutation(ndim); + for (const auto dim_ind : c10::irange(ndim)) { + reverse_permutation[permutation[dim_ind]] = dim_ind; + } + return reverse_permutation; +} + +// Compute R-work array size for MAGMA/LAPACK cgesdd/zgesdd +// See https://github.com/Reference-LAPACK/lapack/blob/122506cd8b6ce050a200920c3d4c0b153b150fd8/SRC/cgesdd.f#L186 +inline int64_t computeLRWorkDim(const char jobz, int64_t m, int64_t n) { + auto mn = std::min(m, n); + auto mx = std::max(m, n); + if (jobz == 'N') { +#ifdef __APPLE__ + // According to `vecLib.framework/Headers/clapack.h` Accelerate.framework is based on LAPACK 3.2.1 + return 7 * mn; +#else + // These setting is valid for on LAPACK 3.6+ + return 5 * mn; +#endif + } + if (mx > 10 * mn) { + return 5 * mn * mn + 5 * mn; + } + return std::max(5 * mn * mn + 5 * mn, 2 * mx * mn + 2 * mn * mn + mn); +} + +// This function checks whether the uplo argument input is valid +// Allowed strings are "u", "U", "l", "L" +inline void checkUplo(const std::string_view uplo) { + // To use std::toupper safely with plain chars (or signed chars), the argument should first be converted to unsigned char + char uplo_uppercase = static_cast(std::toupper(static_cast(uplo[0]))); + TORCH_CHECK(uplo.size() == 1 && (uplo_uppercase == 'U' || uplo_uppercase == 'L'), + "Expected UPLO argument to be 'L' or 'U', but got ", uplo); +} + +inline void checkSameDevice(const std::string& fn_name, Tensor result, Tensor input, const std::string& result_name = "result") { + TORCH_CHECK( + result.device() == input.device(), + fn_name, + ": Expected ", result_name, " and input tensors to be on the same device, but got ", + result_name, " on ", result.device(), " and input on ", input.device()); +} + +// Check the dtype of result and input tensors (for _out variants). +// Most linear algebra functions have the same dtype for input and output +// (either floating or complex type input), so we can check whether input's dtype can be casted to result's dtype. +// According to https://github.com/pytorch/pytorch/wiki/Developer-FAQ#how-does-out-work-in-pytorch +// c10::canCast is used for checking the "safe copy" dtype requirements. +inline void checkLinalgCompatibleDtype(const std::string& fn_name, Tensor result, Tensor input, const std::string& result_name = "result") { + bool can_cast = c10::canCast(input.scalar_type(), result.scalar_type()); + TORCH_CHECK( + can_cast, + fn_name, + ": Expected ", result_name, " to be safely castable from ", input.scalar_type(), " dtype, but got ", + result_name, " with dtype ", result.scalar_type()); +} + +// Alternatively, we can check whether the specific expected output type (result_type) can be safely casted to out tensor dtype (out_type) +inline void checkLinalgCompatibleDtype(const std::string& fn_name, ScalarType out_type, ScalarType result_type, const std::string& out_name = "result") { + bool can_cast = c10::canCast(result_type, out_type); + TORCH_CHECK( + can_cast, + fn_name, + ": Expected ", out_name, " to be safely castable from ", result_type, " dtype, but got ", + out_name, " with dtype ", out_type); +} + +inline void checkNotComplexTolerance(const Tensor& tol, const std::string_view f_name, const std::string_view tol_name) { + TORCH_CHECK(!at::isComplexType(tol.scalar_type()), + f_name, ": ", tol_name, " tensor of complex type is not supported. Got ", tol.scalar_type()); +} + +/* + Two types of 'other' tensors are supported when solving + a system of linear equations matmul(input, x) = other: + * 1-dimensional (1D) tensor or batch of 1D tensors (vector case) + * 2-dimensional (2D) tensor or batch of 2D tensors (matrix case). + The original torch.solve supported only the matrix case, while NumPy works for both cases. + For the batched input we need to be able to distinguish them. + Let input.shape = (batch_dimensions, m, n), then 'other' is of vector type if other.shape == (batch_dimensions, m). + This rule is compatible with NumPy, see https://github.com/numpy/numpy/blob/v1.20.0/numpy/linalg/linalg.py#L384-L389 +*/ +inline bool linalg_solve_is_vector_rhs(const Tensor& input, const Tensor& other) { + auto expected_batched_rhs_shape = SymIntArrayRef(input.sym_sizes().data(), input.dim() - 1); // input.shape[:-1] + bool vector_case = other.dim() == 1 || (input.dim() - 1 == other.dim() && other.sym_sizes().equals(expected_batched_rhs_shape)); + return vector_case; +} + +/* + Computes linear indices for a tensor with original_shape to access its elements like it was a materialized broadcast tensor. +*/ +inline Tensor get_linear_indices(int64_t numel, IntArrayRef original_shape, IntArrayRef broadcast_shape) { + TensorOptions options = at::TensorOptions().dtype(at::kLong).device(at::kCPU); + return at::arange(numel, options).view(original_shape).broadcast_to(broadcast_shape).contiguous(); +} + +class BroadcastLinearIndices { + private: + Tensor linear_indices_; + bool is_broadcasting_; + + public: + BroadcastLinearIndices( + int64_t numel, + IntArrayRef original_shape, + IntArrayRef broadcast_shape) : is_broadcasting_(!original_shape.equals(broadcast_shape)) { + // The assumption is that the broadcast_shape is a materialized broadcast + // shape of the original_shape. We need to compute the linear indices + // compatible with the original_shape to access the elements in the original + // tensor corresponding to the broadcast tensor. + if (is_broadcasting_) { + linear_indices_ = + get_linear_indices(numel, original_shape, broadcast_shape); + } + } + int64_t operator()(int64_t broadcast_linear_index) { + return is_broadcasting_ + ? linear_indices_.data_ptr()[broadcast_linear_index] + : broadcast_linear_index; + } +}; + +inline bool is_blas_compatible_column_major_order(const Tensor& input) { + IntArrayRef input_strides = input.strides(); + IntArrayRef input_sizes = input.sizes(); + auto ndim = input.dim(); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(ndim >= 2); + if (ndim > 3) { + return input.transpose(-2, -1).is_contiguous(); + } + auto leading_dimension = input_strides[ndim - 1]; + auto rows = input_sizes[ndim - 2]; + bool batch_stride_compatible = true; + if (ndim == 3) { + auto cols = input_sizes[ndim - 1]; + batch_stride_compatible = + input_strides[ndim - 3] >= leading_dimension * cols; + } + return (input_strides[ndim - 2] == 1) && + (leading_dimension >= std::max(1, rows)) && + batch_stride_compatible; +} + +inline bool is_blas_compatible_row_major_order(const Tensor& input) { + IntArrayRef input_strides = input.strides(); + IntArrayRef input_sizes = input.sizes(); + auto ndim = input.dim(); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(ndim >= 2); + if (ndim > 3) { + return input.is_contiguous(); + } + auto leading_dimension = input_strides[ndim - 2]; + auto cols = input_sizes[ndim - 1]; + bool batch_stride_compatible = true; + if (ndim == 3) { + auto rows = input_sizes[ndim - 2]; + batch_stride_compatible = + input_strides[ndim - 3] >= leading_dimension * rows; + } + return (input_strides[ndim - 1] == 1) && + (leading_dimension >= std::max(1, cols)) && + batch_stride_compatible; +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/LossMulti.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/LossMulti.h new file mode 100644 index 0000000000000000000000000000000000000000..8877b05a54cc380e99bfce40ef9b9b05b0031c49 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/LossMulti.h @@ -0,0 +1,69 @@ +#pragma once +#include +#include +#include +#include + +namespace at::native { + inline void multilabel_margin_loss_shape_check( + int64_t& nframe, + int64_t& dim, + const int64_t& ndims, + const Tensor& input, + const Tensor& target) { + TORCH_CHECK( + (ndims == 2 && input.size(1) != 0) || (ndims == 1 && input.size(0) != 0) || ndims == 0, + "Expected non-empty vector or matrix with optional 0-dim batch size, but got: ", + input.sizes()); + + if (ndims <= 1) { + nframe = 1; + dim = ndims == 0 ? 1 : input.size(0); + TORCH_CHECK( + target.dim() <= 1 && target.numel() == dim, + "inconsistent target size: ", target.sizes(), " for input of size: ", + input.sizes()); + } else { + nframe = input.size(0); + dim = input.size(1); + TORCH_CHECK( + target.dim() == 2 && target.size(0) == nframe && + target.size(1) == dim, + "inconsistent target size: ", target.sizes(), " for input of size: ", + input.sizes()); + } + } + + inline void multi_margin_loss_shape_check( + int64_t& nframe, + int64_t& dim, + const int64_t& ndims, + const Tensor& input, + const Tensor& target, + const std::optional& weight) { + TORCH_CHECK( + (ndims == 2 && input.size(1) != 0) || (ndims == 1 && input.size(0) != 0) || ndims == 0, + "Expected non-empty vector or matrix with optional 0-dim batch size, but got: ", + input.sizes()); + + if (ndims <= 1) { + nframe = 1; + dim = ndims == 0 ? 1 : input.size(0); + } else { + nframe = input.size(0); + dim = input.size(1); + } + + TORCH_CHECK( + target.dim() <= 1 && target.numel() == nframe, + "inconsistent target size, expected ", nframe, " but got ", + target.sizes()); + if (weight && weight->defined()) { + TORCH_CHECK( + weight->dim() <= 1 && weight->numel() == dim, + "inconsistent weight size, expected ", dim, " but got ", + weight->sizes()); + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Math.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Math.h new file mode 100644 index 0000000000000000000000000000000000000000..47c0a2be030311a603b2b9675cb109ef0947c1bf --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Math.h @@ -0,0 +1,3927 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +C10_CLANG_DIAGNOSTIC_PUSH() +#if C10_CLANG_HAS_WARNING("-Wimplicit-float-conversion") +C10_CLANG_DIAGNOSTIC_IGNORE("-Wimplicit-float-conversion") +#endif + +/* The next function is taken from https://github.com/antelopeusersgroup/antelope_contrib/blob/master/lib/location/libgenloc/erfinv.c. +Below is the copyright. +Output was modified to be inf or -inf when input is 1 or -1. */ + + +/* + Copyright (c) 2014 Indiana University + All rights reserved. + + Written by Prof. Gary L. Pavlis, Dept. of Geol. Sci., + Indiana University, Bloomington, IN + + This software is licensed under the New BSD license: + + Redistribution and use in source and binary forms, + with or without modification, are permitted provided + that the following conditions are met: + + Redistributions of source code must retain the above + copyright notice, this list of conditions and the + following disclaimer. + + Redistributions in binary form must reproduce the + above copyright notice, this list of conditions and + the following disclaimer in the documentation and/or + other materials provided with the distribution. + + Neither the name of Indiana University nor + the names of its contributors may be used to endorse + or promote products derived from this software without + specific prior written permission. + + THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND + CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED + WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED + WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A + PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL + THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY + DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR + CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, + PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF + USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) + HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER + IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING + NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE + USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE + POSSIBILITY OF SUCH DAMAGE. +*/ + +namespace { +/* + * This function is derived from the implementation of the i0e function in the + * Cephes Math Library. See note [3-Clause BSD License for the Cephes Math + * Library]. + * + * Computes an approximation of the exponentially scaled zeroth order modified + * Bessel function of the first kind. The approximation is actually two + * (sub)approximations, both using a Chebyshev polynomial expansion. One + * approximates the function over [0, 8], and the other over (8, infinity). This + * function takes the absolute value of all inputs to convert them into the + * domain of the approximation. + */ +jiterator_also_stringify_as(jiterator_code( + template + JITERATOR_HOST_DEVICE T chbevl(T x, const T array[], const int len) { + T b0, b1, b2; + + b0 = array[0]; + b1 = 0; + + for (int i = 1; i < len; ++i) { + b2 = b1; + b1 = b0; + b0 = x * b1 - b2 + array[i]; + } + + return T{0.5} * (b0 - b2); + } + + template + JITERATOR_HOST_DEVICE T calc_i0e(T _x) { + T x = std::fabs(_x); + + if (x <= T{8.0}) { + static const T coefficients[] = { + -4.41534164647933937950E-18, 3.33079451882223809783E-17, + -2.43127984654795469359E-16, 1.71539128555513303061E-15, + -1.16853328779934516808E-14, 7.67618549860493561688E-14, + -4.85644678311192946090E-13, 2.95505266312963983461E-12, + -1.72682629144155570723E-11, 9.67580903537323691224E-11, + -5.18979560163526290666E-10, 2.65982372468238665035E-9, + -1.30002500998624804212E-8, 6.04699502254191894932E-8, + -2.67079385394061173391E-7, 1.11738753912010371815E-6, + -4.41673835845875056359E-6, 1.64484480707288970893E-5, + -5.75419501008210370398E-5, 1.88502885095841655729E-4, + -5.76375574538582365885E-4, 1.63947561694133579842E-3, + -4.32430999505057594430E-3, 1.05464603945949983183E-2, + -2.37374148058994688156E-2, 4.93052842396707084878E-2, + -9.49010970480476444210E-2, 1.71620901522208775349E-1, + -3.04682672343198398683E-1, 6.76795274409476084995E-1}; + + T y = (x / T{2.0}) - T{2.0}; + return chbevl(y, coefficients, int{30}); + } + + // x > 8 + static const T coefficients[] = { + -7.23318048787475395456E-18, -4.83050448594418207126E-18, + 4.46562142029675999901E-17, 3.46122286769746109310E-17, + -2.82762398051658348494E-16, -3.42548561967721913462E-16, + 1.77256013305652638360E-15, 3.81168066935262242075E-15, + -9.55484669882830764870E-15, -4.15056934728722208663E-14, + 1.54008621752140982691E-14, 3.85277838274214270114E-13, + 7.18012445138366623367E-13, -1.79417853150680611778E-12, + -1.32158118404477131188E-11, -3.14991652796324136454E-11, + 1.18891471078464383424E-11, 4.94060238822496958910E-10, + 3.39623202570838634515E-9, 2.26666899049817806459E-8, + 2.04891858946906374183E-7, 2.89137052083475648297E-6, + 6.88975834691682398426E-5, 3.36911647825569408990E-3, + 8.04490411014108831608E-1}; + + return chbevl(T{32.0} / x - T{2.0}, coefficients, int{25}) / std::sqrt(x); + }), + i0e_string) // i0e_string +} + +#define CENTRAL_RANGE 0.7 + +template +inline typename std::enable_if_t, T> +calc_erfinv(T y) { +/* Function to calculate inverse error function. Rational approximation +is used to generate an initial approximation, which is then improved to +full accuracy by two steps of Newton's method. Code is a direct +translation of the erfinv m file in matlab version 2.0. +Author: Gary L. Pavlis, Indiana University +Date: February 1996 +*/ + T x, z, num, dem; /*working variables */ + /* coefficients in rational expansion */ + T a[4] = { T(0.886226899), T(-1.645349621), T(0.914624893), T(-0.140543331) }; + T b[4] = { T(-2.118377725), T(1.442710462), T(-0.329097515), T(0.012229801) }; + T c[4] = { T(-1.970840454), T(-1.624906493), T(3.429567803), T(1.641345311) }; + T d[2] = { T(3.543889200), T(1.637067800) }; + T y_abs = std::abs(y); + if(y_abs > 1.0) return std::numeric_limits::quiet_NaN(); +#ifdef _WIN32 + // error C2039: '_copysign': is not a member of 'std' + if(y_abs == 1.0) return copysign(std::numeric_limits::infinity(), y); +#else + if(y_abs == 1.0) return std::copysign(std::numeric_limits::infinity(), y); +#endif + if(y_abs <= static_cast(CENTRAL_RANGE)) { + z = y * y; + num = (((a[3]*z + a[2])*z + a[1])*z + a[0]); + dem = ((((b[3]*z + b[2])*z + b[1])*z +b[0]) * z + static_cast(1.0)); + x = y * num / dem; + } + else{ + z = std::sqrt(-std::log((static_cast(1.0)-y_abs)/static_cast(2.0))); + num = ((c[3]*z + c[2])*z + c[1]) * z + c[0]; + dem = (d[1]*z + d[0])*z + static_cast(1.0); +#ifdef _WIN32 + // error C2039: '_copysign': is not a member of 'std' + x = copysign(num, y) / dem; +#else + x = std::copysign(num, y) / dem; +#endif + } + /* Two steps of Newton-Raphson correction */ + x = x - (std::erf(x) - y) / ((static_cast(2.0)/static_cast(std::sqrt(c10::pi)))*std::exp(-x*x)); + x = x - (std::erf(x) - y) / ((static_cast(2.0)/static_cast(std::sqrt(c10::pi)))*std::exp(-x*x)); + + return(x); +} + +#undef CENTRAL_RANGE + +/* + * Note [3-Clause BSD License for the Cephes Math Library] + * Code derived from implementations in the Cephes Math Library should mention its derivation and reference + * this note (ex. 'This function is derived from the implementation of X in the Cephes Math Library. See note + * [3-Clause BSD License for the Cephes Math Library]. The license is: + * Copyright (c) 2018, Steven Moshier + * All rights reserved. + * + * Redistribution and use in source and binary forms, with or without + * modification, are permitted provided that the following conditions are met: + * * Redistributions of source code must retain the above copyright + * notice, this list of conditions and the following disclaimer. + * * Redistributions in binary form must reproduce the above copyright + * notice, this list of conditions and the following disclaimer in the + * documentation and/or other materials provided with the distribution. + * * Neither the name of the nor the + * names of its contributors may be used to endorse or promote products + * derived from this software without specific prior written permission. + * + * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND + * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED + * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE + * DISCLAIMED. IN NO EVENT SHALL Steven Moshier BE LIABLE FOR ANY + * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES + * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; + * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND + * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT + * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS + * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + */ + +/* + * This function is derived from the implementation of the zeta function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + */ +template +C10_HOST_DEVICE inline scalar_t zeta(scalar_t x, scalar_t q) __ubsan_ignore_float_divide_by_zero__ { + using acc_t = at::acc_type; + const acc_t MACHEP = acc_t{1.11022302462515654042E-16}; + constexpr acc_t zero = acc_t{0.0}; + constexpr acc_t half = acc_t{0.5}; + constexpr acc_t one = acc_t{1.0}; + static const acc_t A[] = { + 12.0, + -720.0, + 30240.0, + -1209600.0, + 47900160.0, + -1.8924375803183791606e9, /*1.307674368e12/691*/ + 7.47242496e10, + -2.950130727918164224e12, /*1.067062284288e16/3617*/ + 1.1646782814350067249e14, /*5.109094217170944e18/43867*/ + -4.5979787224074726105e15, /*8.028576626982912e20/174611*/ + 1.8152105401943546773e17, /*1.5511210043330985984e23/854513*/ + -7.1661652561756670113e18 /*1.6938241367317436694528e27/236364091*/ + }; + + acc_t a, b, k, s, t, w; + if (x == one) { + return std::numeric_limits::infinity(); + } + + if (x < one) { + return std::numeric_limits::quiet_NaN(); + } + + if (q <= zero) { + if (q == std::floor(q)) { + return std::numeric_limits::infinity(); + } + if (x != std::floor(x)) { + return std::numeric_limits::quiet_NaN(); + } + } + + s = std::pow(q, -x); + a = q; + int i = 0; + b = zero; + while ((i < 9) || (a <= acc_t{9.0})) { + i += 1; + a += one; + b = ::pow(a, -x); + s += b; + if ((-MACHEP * s < b) && (b < MACHEP * s)) { + return static_cast(s); + } + }; + + w = a; + s += b * w / (x - one); + s -= half * b; + a = one; + k = zero; + for (i = 0; i < 12; i++) { + a *= x + k; + b /= w; + t = a * b / A[i]; + s = s + t; + t = ::fabs(t / s); + if (t < MACHEP) { + return static_cast(s); + } + k += one; + a *= x + k; + b /= w; + k += one; + } + return static_cast(s); +} + +/* + * This function is derived from the implementation of the digamma function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + * + * Evaluates polynomial of degree N: + * + * 2 N + * y = C + C x + C x +...+ C x + * 0 1 2 N + * + * Coefficients are stored in reverse order: + * + * coef[0] = C , ..., coef[N] = C . + * N 0 + */ +template +C10_HOST_DEVICE inline T polevl(const T x, const T A[], size_t len) { + T result = 0; + for (size_t i = 0; i <= len; i++) { + result = result * x + A[i]; + } + return result; +} + +inline double trigamma(double x) __ubsan_ignore_float_divide_by_zero__ { + double sign = +1; + double result = 0; + if (x < 0.5) { + sign = -1; + const double sin_pi_x = sin(c10::pi * x); + result -= (c10::pi * c10::pi) / (sin_pi_x * sin_pi_x); + x = 1 - x; + } + for (int i = 0; i < 6; ++i) { + result += 1 / (x * x); + x += 1; + } + const double ixx = 1 / (x*x); + result += (1 + 1 / (2*x) + ixx * (1./6 - ixx * (1./30 - ixx * (1./42)))) / x; + return sign * result; +} + +inline float trigamma(float x) __ubsan_ignore_float_divide_by_zero__ { + float sign = +1; + float result = 0; + if (x < 0.5f) { + sign = -1; + const float sin_pi_x = sinf(c10::pi * x); + result -= (c10::pi * c10::pi) / (sin_pi_x * sin_pi_x); + x = 1 - x; + } + for (int i = 0; i < 6; ++i) { + result += 1 / (x * x); + x += 1; + } + const float ixx = 1 / (x*x); + result += (1 + 1 / (2*x) + ixx * (1.f/6 - ixx * (1.f/30 - ixx * (1.f/42)))) / x; + return sign * result; +} + +/* + * This function is derived from the implementation of the digamma function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + */ +inline double calc_digamma(double x) { + // [C++ Standard Reference: Gamma Function] https://en.cppreference.com/w/cpp/numeric/math/tgamma + static double PSI_10 = 2.25175258906672110764; + if (x == 0) { + // As per C++ standard for gamma related functions and SciPy, + // If the argument is ±0, ±∞ is returned + return std::copysign(INFINITY, -x); + } + + bool x_is_integer = x == trunc(x); + if (x < 0) { + if (x_is_integer) { + // As per C++ standard for gamma related functions and SciPy, + // If the argument is a negative integer, NaN is returned + return std::numeric_limits::quiet_NaN(); + } + // Extracts the fractional part of x as r, since tan(pi * r) is more numerically + // accurate than tan(pi * x). While these operations are mathematically equivalent + // since both x and r are in radians and tan() has a periodicity of pi, in practice + // the computation of pi * x is a source of error (when |x| > 1). + double q, r; + r = std::modf(x, &q); + return calc_digamma(1 - x) - c10::pi / tan(c10::pi * r); + } + + // Push x to be >= 10 + double result = 0; + while (x < 10) { + result -= 1 / x; + x += 1; + } + if (x == 10) { + return result + PSI_10; + } + + // Compute asymptotic digamma + static const double A[] = { + 8.33333333333333333333E-2, + -2.10927960927960927961E-2, + 7.57575757575757575758E-3, + -4.16666666666666666667E-3, + 3.96825396825396825397E-3, + -8.33333333333333333333E-3, + 8.33333333333333333333E-2, + }; + + double y = 0; + if (x < 1.0e17) { + double z = 1.0 / (x * x); + y = z * polevl(z, A, 6); + } + return result + log(x) - (0.5 / x) - y; +} + +/* + * This function is derived from the implementation of the digamma function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + */ +inline float calc_digamma(float x) { + // See [C++ Standard Reference: Gamma Function] + static float PSI_10 = 2.25175258906672110764f; + if (x == 0) { + // As per C++ standard for gamma related functions and SciPy, + // If the argument is ±0, ±∞ is returned + return std::copysign(INFINITY, -x); + } + + bool x_is_integer = x == truncf(x); + if (x < 0) { + if (x_is_integer) { + // As per C++ standard for gamma related functions and SciPy, + // If the argument is a negative integer, NaN is returned + return std::numeric_limits::quiet_NaN(); + } + // Extracts the fractional part of x as r, since tan(pi * r) is more numerically + // accurate than tan(pi * x). While these operations are mathematically equivalent + // since both x and r are in radians and tan() has a periodicity of pi, in practice + // the computation of pi * x is a source of error (when |x| > 1). + double q, r; + r = std::modf(x, &q); + float pi_over_tan_pi_x = (float)(c10::pi / tan(c10::pi * r)); + return calc_digamma(1 - x) - pi_over_tan_pi_x; + } + + // Push x to be >= 10 + float result = 0; + while (x < 10) { + result -= 1 / x; + x += 1; + } + if (x == 10) { + return result + PSI_10; + } + + // Compute asymptotic digamma + static const float A[] = { + 8.33333333333333333333E-2f, + -2.10927960927960927961E-2f, + 7.57575757575757575758E-3f, + -4.16666666666666666667E-3f, + 3.96825396825396825397E-3f, + -8.33333333333333333333E-3f, + 8.33333333333333333333E-2f, + }; + + float y = 0; + if (x < 1.0e17f) { + float z = 1 / (x * x); + y = z * polevl(z, A, 6); + } + return result + logf(x) - (0.5f / x) - y; +} + +inline c10::BFloat16 calc_digamma(c10::BFloat16 a) { + return calc_digamma(static_cast(a)); +} + +inline c10::Half calc_digamma(c10::Half a) { + return calc_digamma(static_cast(a)); +} + +template +inline C10_HOST_DEVICE scalar_t calc_polygamma(scalar_t x, int n) { + // already blocked if n <= 1 + const auto one = scalar_t{1}; + return ((n % 2) ? one : -one) * + std::exp(std::lgamma(static_cast(n) + one)) * + zeta(static_cast(n + 1), x); +} + +// regularized lower incomplete gamma +// the regularized lower, upper incomplete gamma, as well as their +// helper functions follow SciPy's implementation + +/* References + * [igam1] "The Digital Library of Mathematical Functions", dlmf.nist.gov + * [igam2] Maddock et al., "Incomplete Gamma Functions", + * https://www.boost.org/doc/libs/1_61_0/libs/math/doc/html/math_toolkit/sf_gamma/igamma.html + */ + +/* + * This implementation of the regularized incomplete gamma functions and + * their helper functions are derived from the implementation of SciPy's + * gammainc, Cephes's igam and igamc, and Boost's Lanczos approximations. + * See NOTICE for the licenses. + */ +template +scalar_t ratevl(scalar_t x, const scalar_t num[], int64_t M, + const scalar_t denom[], int64_t N) { + // evaluating rational function, i.e., the ratio of two polynomials + // the coefficients for numerator are given by `num` while coeffs for + // denumerator are given by `denom` + + int64_t i, dir; + scalar_t y, num_ans, denom_ans; + scalar_t absx = std::fabs(x); + const scalar_t *p; + + if (absx > 1) { + /* Evaluate as a polynomial in 1/x. */ + dir = -1; + p = num + M; + y = 1 / x; + } + else { + dir = 1; + p = num; + y = x; + } + + /* Evaluate the numerator */ + num_ans = *p; + p += dir; + for (i = 1; i <= M; i++) { + num_ans = num_ans * y + *p; + p += dir; + } + /* Evaluate the denominator */ + if (absx > 1) { + p = denom + N; + } + else { + p = denom; + } + + denom_ans = *p; + p += dir; + for (i = 1; i <= N; i++) { + denom_ans = denom_ans * y + *p; + p += dir; + } + if (absx > 1) { + i = N - M; + return std::pow(x, i) * num_ans / denom_ans; + } + else { + return num_ans / denom_ans; + } +} + +// SciPy's lanczos implementation is taken from Boost +/* (C) Copyright John Maddock 2006. + * Use, modification and distribution are subject to the + * Boost Software License, Version 1.0. See + * https://www.boost.org/LICENSE_1_0.txt or see NOTICE. + */ +template +static scalar_t lanczos_sum_expg_scaled(scalar_t x) { + // lanczos approximation + static const scalar_t lanczos_sum_expg_scaled_num[13] = { + 0.006061842346248906525783753964555936883222, + 0.5098416655656676188125178644804694509993, + 19.51992788247617482847860966235652136208, + 449.9445569063168119446858607650988409623, + 6955.999602515376140356310115515198987526, + 75999.29304014542649875303443598909137092, + 601859.6171681098786670226533699352302507, + 3481712.15498064590882071018964774556468, + 14605578.08768506808414169982791359218571, + 43338889.32467613834773723740590533316085, + 86363131.28813859145546927288977868422342, + 103794043.1163445451906271053616070238554, + 56906521.91347156388090791033559122686859 + }; + static const scalar_t lanczos_sum_expg_scaled_denom[13] = { + 1., + 66., + 1925., + 32670., + 357423., + 2637558., + 13339535., + 45995730., + 105258076., + 150917976., + 120543840., + 39916800., + 0. + }; + return ratevl(x, lanczos_sum_expg_scaled_num, + sizeof(lanczos_sum_expg_scaled_num) / sizeof(lanczos_sum_expg_scaled_num[0]) - 1, + lanczos_sum_expg_scaled_denom, + sizeof(lanczos_sum_expg_scaled_denom) / sizeof(lanczos_sum_expg_scaled_denom[0]) - 1); +} + +template +static scalar_t _igam_helper_fac(scalar_t a, scalar_t x) { + // compute x^a * exp(-a) / gamma(a) + // corrected from (15) and (16) in [igam2] by replacing exp(x - a) with + // exp(a - x). + + scalar_t ax, fac, res, num, numfac; + static scalar_t MAXLOG = std::is_same_v ? + 7.09782712893383996843E2 : 88.72283905206835; + static scalar_t EXP1 = 2.718281828459045; + static scalar_t lanczos_g = 6.024680040776729583740234375; + + if (std::fabs(a - x) > 0.4 * std::fabs(a)) { + ax = a * std::log(x) - x - std::lgamma(a); + if (ax < -MAXLOG) { + return 0.0; + } + return std::exp(ax); + } + + fac = a + lanczos_g - 0.5; + res = std::sqrt(fac / EXP1) / lanczos_sum_expg_scaled(a); + + if ((a < 200) && (x < 200)) { + res *= std::exp(a - x) * std::pow(x / fac, a); + } + else { + num = x - a - lanczos_g + 0.5; + numfac = num / fac; + res *= std::exp(a * (std::log1p(numfac) - numfac) + x * (0.5 - lanczos_g) / fac); + } + return res; +} + +template +static scalar_t _igam_helper_series(scalar_t a, scalar_t x) { + // Compute igam using DLMF 8.11.4. [igam1] + static scalar_t MACHEP = std::is_same_v ? + 1.11022302462515654042E-16 : 5.9604644775390625E-8; + static int MAXITER = 2000; + + int i; + scalar_t ans, ax, c, r; + + ax = _igam_helper_fac(a, x); + if (ax == 0.0) { + return 0.0; + } + + /* power series */ + r = a; + c = 1.0; + ans = 1.0; + + for (i = 0; i < MAXITER; i++) { + r += 1.0; + c *= x / r; + ans += c; + if (c <= MACHEP * ans) { + break; + } + } + return (ans * ax / a); +} + +template +static scalar_t _igamc_helper_series(scalar_t a, scalar_t x) { + // Compute igamc using DLMF 8.7.3 [igam1]. This is related to the series in + // _igam_helper_series but extra care is taken to avoid cancellation. + + int n; + scalar_t fac = 1; + scalar_t sum = 0; + scalar_t term, logx; + static scalar_t MAXITER = 2000; + static scalar_t MACHEP = std::is_same_v ? + 1.11022302462515654042E-16 : 5.9604644775390625E-8; + + for (n = 1; n < MAXITER; n++) { + fac *= -x / n; + term = fac / (a + n); + sum += term; + if (std::fabs(term) <= MACHEP * std::fabs(sum)) { + break; + } + } + + logx = std::log(x); + term = -std::expm1(a * logx - std::lgamma(1+a)); + return term - std::exp(a * logx - std::lgamma(a)) * sum; +} + +template +static scalar_t _igam_helper_asymptotic_series(scalar_t a, scalar_t x, bool igam) { + // Compute igam/igamc using DLMF 8.12.3/8.12.4 [igam1] + static const scalar_t d[25][25] = + {{-3.3333333333333333e-1, 8.3333333333333333e-2, -1.4814814814814815e-2, + 1.1574074074074074e-3, 3.527336860670194e-4, -1.7875514403292181e-4, + 3.9192631785224378e-5, -2.1854485106799922e-6, -1.85406221071516e-6, + 8.296711340953086e-7, -1.7665952736826079e-7, 6.7078535434014986e-9, + 1.0261809784240308e-8, -4.3820360184533532e-9, 9.1476995822367902e-10, + -2.551419399494625e-11, -5.8307721325504251e-11, 2.4361948020667416e-11, + -5.0276692801141756e-12, 1.1004392031956135e-13, 3.3717632624009854e-13, + -1.3923887224181621e-13, 2.8534893807047443e-14, -5.1391118342425726e-16, + -1.9752288294349443e-15}, + {-1.8518518518518519e-3, -3.4722222222222222e-3, 2.6455026455026455e-3, + -9.9022633744855967e-4, 2.0576131687242798e-4, -4.0187757201646091e-7, + -1.8098550334489978e-5, 7.6491609160811101e-6, -1.6120900894563446e-6, + 4.6471278028074343e-9, 1.378633446915721e-7, -5.752545603517705e-8, + 1.1951628599778147e-8, -1.7543241719747648e-11, -1.0091543710600413e-9, + 4.1627929918425826e-10, -8.5639070264929806e-11, 6.0672151016047586e-14, + 7.1624989648114854e-12, -2.9331866437714371e-12, 5.9966963656836887e-13, + -2.1671786527323314e-16, -4.9783399723692616e-14, 2.0291628823713425e-14, + -4.13125571381061e-15}, + {4.1335978835978836e-3, -2.6813271604938272e-3, 7.7160493827160494e-4, + 2.0093878600823045e-6, -1.0736653226365161e-4, 5.2923448829120125e-5, + -1.2760635188618728e-5, 3.4235787340961381e-8, 1.3721957309062933e-6, + -6.298992138380055e-7, 1.4280614206064242e-7, -2.0477098421990866e-10, + -1.4092529910867521e-8, 6.228974084922022e-9, -1.3670488396617113e-9, + 9.4283561590146782e-13, 1.2872252400089318e-10, -5.5645956134363321e-11, + 1.1975935546366981e-11, -4.1689782251838635e-15, -1.0940640427884594e-12, + 4.6622399463901357e-13, -9.905105763906906e-14, 1.8931876768373515e-17, + 8.8592218725911273e-15}, + {6.4943415637860082e-4, 2.2947209362139918e-4, -4.6918949439525571e-4, + 2.6772063206283885e-4, -7.5618016718839764e-5, -2.3965051138672967e-7, + 1.1082654115347302e-5, -5.6749528269915966e-6, 1.4230900732435884e-6, + -2.7861080291528142e-11, -1.6958404091930277e-7, 8.0994649053880824e-8, + -1.9111168485973654e-8, 2.3928620439808118e-12, 2.0620131815488798e-9, + -9.4604966618551322e-10, 2.1541049775774908e-10, -1.388823336813903e-14, + -2.1894761681963939e-11, 9.7909989511716851e-12, -2.1782191880180962e-12, + 6.2088195734079014e-17, 2.126978363279737e-13, -9.3446887915174333e-14, + 2.0453671226782849e-14}, + {-8.618882909167117e-4, 7.8403922172006663e-4, -2.9907248030319018e-4, + -1.4638452578843418e-6, 6.6414982154651222e-5, -3.9683650471794347e-5, + 1.1375726970678419e-5, 2.5074972262375328e-10, -1.6954149536558306e-6, + 8.9075075322053097e-7, -2.2929348340008049e-7, 2.956794137544049e-11, + 2.8865829742708784e-8, -1.4189739437803219e-8, 3.4463580499464897e-9, + -2.3024517174528067e-13, -3.9409233028046405e-10, 1.8602338968504502e-10, + -4.356323005056618e-11, 1.2786001016296231e-15, 4.6792750266579195e-12, + -2.1492464706134829e-12, 4.9088156148096522e-13, -6.3385914848915603e-18, + -5.0453320690800944e-14}, + {-3.3679855336635815e-4, -6.9728137583658578e-5, 2.7727532449593921e-4, + -1.9932570516188848e-4, 6.7977804779372078e-5, 1.419062920643967e-7, + -1.3594048189768693e-5, 8.0184702563342015e-6, -2.2914811765080952e-6, + -3.252473551298454e-10, 3.4652846491085265e-7, -1.8447187191171343e-7, + 4.8240967037894181e-8, -1.7989466721743515e-14, -6.3061945000135234e-9, + 3.1624176287745679e-9, -7.8409242536974293e-10, 5.1926791652540407e-15, + 9.3589442423067836e-11, -4.5134262161632782e-11, 1.0799129993116827e-11, + -3.661886712685252e-17, -1.210902069055155e-12, 5.6807435849905643e-13, + -1.3249659916340829e-13}, + {5.3130793646399222e-4, -5.9216643735369388e-4, 2.7087820967180448e-4, + 7.9023532326603279e-7, -8.1539693675619688e-5, 5.6116827531062497e-5, + -1.8329116582843376e-5, -3.0796134506033048e-9, 3.4651553688036091e-6, + -2.0291327396058604e-6, 5.7887928631490037e-7, 2.338630673826657e-13, + -8.8286007463304835e-8, 4.7435958880408128e-8, -1.2545415020710382e-8, + 8.6496488580102925e-14, 1.6846058979264063e-9, -8.5754928235775947e-10, + 2.1598224929232125e-10, -7.6132305204761539e-16, -2.6639822008536144e-11, + 1.3065700536611057e-11, -3.1799163902367977e-12, 4.7109761213674315e-18, + 3.6902800842763467e-13}, + {3.4436760689237767e-4, 5.1717909082605922e-5, -3.3493161081142236e-4, + 2.812695154763237e-4, -1.0976582244684731e-4, -1.2741009095484485e-7, + 2.7744451511563644e-5, -1.8263488805711333e-5, 5.7876949497350524e-6, + 4.9387589339362704e-10, -1.0595367014026043e-6, 6.1667143761104075e-7, + -1.7562973359060462e-7, -1.2974473287015439e-12, 2.695423606288966e-8, + -1.4578352908731271e-8, 3.887645959386175e-9, -3.8810022510194121e-17, + -5.3279941738772867e-10, 2.7437977643314845e-10, -6.9957960920705679e-11, + 2.5899863874868481e-17, 8.8566890996696381e-12, -4.403168815871311e-12, + 1.0865561947091654e-12}, + {-6.5262391859530942e-4, 8.3949872067208728e-4, -4.3829709854172101e-4, + -6.969091458420552e-7, 1.6644846642067548e-4, -1.2783517679769219e-4, + 4.6299532636913043e-5, 4.5579098679227077e-9, -1.0595271125805195e-5, + 6.7833429048651666e-6, -2.1075476666258804e-6, -1.7213731432817145e-11, + 3.7735877416110979e-7, -2.1867506700122867e-7, 6.2202288040189269e-8, + 6.5977038267330006e-16, -9.5903864974256858e-9, 5.2132144922808078e-9, + -1.3991589583935709e-9, 5.382058999060575e-16, 1.9484714275467745e-10, + -1.0127287556389682e-10, 2.6077347197254926e-11, -5.0904186999932993e-18, + -3.3721464474854592e-12}, + {-5.9676129019274625e-4, -7.2048954160200106e-5, 6.7823088376673284e-4, + -6.4014752602627585e-4, 2.7750107634328704e-4, 1.8197008380465151e-7, + -8.4795071170685032e-5, 6.105192082501531e-5, -2.1073920183404862e-5, + -8.8585890141255994e-10, 4.5284535953805377e-6, -2.8427815022504408e-6, + 8.7082341778646412e-7, 3.6886101871706965e-12, -1.5344695190702061e-7, + 8.862466778790695e-8, -2.5184812301826817e-8, -1.0225912098215092e-14, + 3.8969470758154777e-9, -2.1267304792235635e-9, 5.7370135528051385e-10, + -1.887749850169741e-19, -8.0931538694657866e-11, 4.2382723283449199e-11, + -1.1002224534207726e-11}, + {1.3324454494800656e-3, -1.9144384985654775e-3, 1.1089369134596637e-3, + 9.932404122642299e-7, -5.0874501293093199e-4, 4.2735056665392884e-4, + -1.6858853767910799e-4, -8.1301893922784998e-9, 4.5284402370562147e-5, + -3.127053674781734e-5, 1.044986828530338e-5, 4.8435226265680926e-11, + -2.1482565873456258e-6, 1.329369701097492e-6, -4.0295693092101029e-7, + -1.7567877666323291e-13, 7.0145043163668257e-8, -4.040787734999483e-8, + 1.1474026743371963e-8, 3.9642746853563325e-18, -1.7804938269892714e-9, + 9.7480262548731646e-10, -2.6405338676507616e-10, 5.794875163403742e-18, + 3.7647749553543836e-11}, + {1.579727660730835e-3, 1.6251626278391582e-4, -2.0633421035543276e-3, + 2.1389686185689098e-3, -1.0108559391263003e-3, -3.9912705529919201e-7, + 3.6235025084764691e-4, -2.8143901463712154e-4, 1.0449513336495887e-4, + 2.1211418491830297e-9, -2.5779417251947842e-5, 1.7281818956040463e-5, + -5.6413773872904282e-6, -1.1024320105776174e-11, 1.1223224418895175e-6, + -6.8693396379526735e-7, 2.0653236975414887e-7, 4.6714772409838506e-14, + -3.5609886164949055e-8, 2.0470855345905963e-8, -5.8091738633283358e-9, + -1.332821287582869e-16, 9.0354604391335133e-10, -4.9598782517330834e-10, + 1.3481607129399749e-10}, + {-4.0725121195140166e-3, 6.4033628338080698e-3, -4.0410161081676618e-3, + -2.183732802866233e-6, 2.1740441801254639e-3, -1.9700440518418892e-3, + 8.3595469747962458e-4, 1.9445447567109655e-8, -2.5779387120421696e-4, + 1.9009987368139304e-4, -6.7696499937438965e-5, -1.4440629666426572e-10, + 1.5712512518742269e-5, -1.0304008744776893e-5, 3.304517767401387e-6, + 7.9829760242325709e-13, -6.4097794149313004e-7, 3.8894624761300056e-7, + -1.1618347644948869e-7, -2.816808630596451e-15, 1.9878012911297093e-8, + -1.1407719956357511e-8, 3.2355857064185555e-9, 4.1759468293455945e-20, + -5.0423112718105824e-10}, + {-5.9475779383993003e-3, -5.4016476789260452e-4, 8.7910413550767898e-3, + -9.8576315587856125e-3, 5.0134695031021538e-3, 1.2807521786221875e-6, + -2.0626019342754683e-3, 1.7109128573523058e-3, -6.7695312714133799e-4, + -6.9011545676562133e-9, 1.8855128143995902e-4, -1.3395215663491969e-4, + 4.6263183033528039e-5, 4.0034230613321351e-11, -1.0255652921494033e-5, + 6.612086372797651e-6, -2.0913022027253008e-6, -2.0951775649603837e-13, + 3.9756029041993247e-7, -2.3956211978815887e-7, 7.1182883382145864e-8, + 8.925574873053455e-16, -1.2101547235064676e-8, 6.9350618248334386e-9, + -1.9661464453856102e-9}, + {1.7402027787522711e-2, -2.9527880945699121e-2, 2.0045875571402799e-2, + 7.0289515966903407e-6, -1.2375421071343148e-2, 1.1976293444235254e-2, + -5.4156038466518525e-3, -6.3290893396418616e-8, 1.8855118129005065e-3, + -1.473473274825001e-3, 5.5515810097708387e-4, 5.2406834412550662e-10, + -1.4357913535784836e-4, 9.9181293224943297e-5, -3.3460834749478311e-5, + -3.5755837291098993e-12, 7.1560851960630076e-6, -4.5516802628155526e-6, + 1.4236576649271475e-6, 1.8803149082089664e-14, -2.6623403898929211e-7, + 1.5950642189595716e-7, -4.7187514673841102e-8, -6.5107872958755177e-17, + 7.9795091026746235e-9}, + {3.0249124160905891e-2, 2.4817436002649977e-3, -4.9939134373457022e-2, + 5.9915643009307869e-2, -3.2483207601623391e-2, -5.7212968652103441e-6, + 1.5085251778569354e-2, -1.3261324005088445e-2, 5.5515262632426148e-3, + 3.0263182257030016e-8, -1.7229548406756723e-3, 1.2893570099929637e-3, + -4.6845138348319876e-4, -1.830259937893045e-10, 1.1449739014822654e-4, + -7.7378565221244477e-5, 2.5625836246985201e-5, 1.0766165333192814e-12, + -5.3246809282422621e-6, 3.349634863064464e-6, -1.0381253128684018e-6, + -5.608909920621128e-15, 1.9150821930676591e-7, -1.1418365800203486e-7, + 3.3654425209171788e-8}, + {-9.9051020880159045e-2, 1.7954011706123486e-1, -1.2989606383463778e-1, + -3.1478872752284357e-5, 9.0510635276848131e-2, -9.2828824411184397e-2, + 4.4412112839877808e-2, 2.7779236316835888e-7, -1.7229543805449697e-2, + 1.4182925050891573e-2, -5.6214161633747336e-3, -2.39598509186381e-9, + 1.6029634366079908e-3, -1.1606784674435773e-3, 4.1001337768153873e-4, + 1.8365800754090661e-11, -9.5844256563655903e-5, 6.3643062337764708e-5, + -2.076250624489065e-5, -1.1806020912804483e-13, 4.2131808239120649e-6, + -2.6262241337012467e-6, 8.0770620494930662e-7, 6.0125912123632725e-16, + -1.4729737374018841e-7}, + {-1.9994542198219728e-1, -1.5056113040026424e-2, 3.6470239469348489e-1, + -4.6435192311733545e-1, 2.6640934719197893e-1, 3.4038266027147191e-5, + -1.3784338709329624e-1, 1.276467178337056e-1, -5.6213828755200985e-2, + -1.753150885483011e-7, 1.9235592956768113e-2, -1.5088821281095315e-2, + 5.7401854451350123e-3, 1.0622382710310225e-9, -1.5335082692563998e-3, + 1.0819320643228214e-3, -3.7372510193945659e-4, -6.6170909729031985e-12, + 8.4263617380909628e-5, -5.5150706827483479e-5, 1.7769536448348069e-5, + 3.8827923210205533e-14, -3.53513697488768e-6, 2.1865832130045269e-6, + -6.6812849447625594e-7}, + {7.2438608504029431e-1, -1.3918010932653375, 1.0654143352413968, + 1.876173868950258e-4, -8.2705501176152696e-1, 8.9352433347828414e-1, + -4.4971003995291339e-1, -1.6107401567546652e-6, 1.9235590165271091e-1, + -1.6597702160042609e-1, 6.8882222681814333e-2, 1.3910091724608687e-8, + -2.146911561508663e-2, 1.6228980898865892e-2, -5.9796016172584256e-3, + -1.1287469112826745e-10, 1.5167451119784857e-3, -1.0478634293553899e-3, + 3.5539072889126421e-4, 8.1704322111801517e-13, -7.7773013442452395e-5, + 5.0291413897007722e-5, -1.6035083867000518e-5, 1.2469354315487605e-14, + 3.1369106244517615e-6}, + {1.6668949727276811, 1.165462765994632e-1, -3.3288393225018906, + 4.4692325482864037, -2.6977693045875807, -2.600667859891061e-4, + 1.5389017615694539, -1.4937962361134612, 6.8881964633233148e-1, + 1.3077482004552385e-6, -2.5762963325596288e-1, 2.1097676102125449e-1, + -8.3714408359219882e-2, -7.7920428881354753e-9, 2.4267923064833599e-2, + -1.7813678334552311e-2, 6.3970330388900056e-3, 4.9430807090480523e-11, + -1.5554602758465635e-3, 1.0561196919903214e-3, -3.5277184460472902e-4, + 9.3002334645022459e-14, 7.5285855026557172e-5, -4.8186515569156351e-5, + 1.5227271505597605e-5}, + {-6.6188298861372935, 1.3397985455142589e+1, -1.0789350606845146e+1, + -1.4352254537875018e-3, 9.2333694596189809, -1.0456552819547769e+1, + 5.5105526029033471, 1.2024439690716742e-5, -2.5762961164755816, + 2.3207442745387179, -1.0045728797216284, -1.0207833290021914e-7, + 3.3975092171169466e-1, -2.6720517450757468e-1, 1.0235252851562706e-1, + 8.4329730484871625e-10, -2.7998284958442595e-2, 2.0066274144976813e-2, + -7.0554368915086242e-3, 1.9402238183698188e-12, 1.6562888105449611e-3, + -1.1082898580743683e-3, 3.654545161310169e-4, -5.1290032026971794e-11, + -7.6340103696869031e-5}, + {-1.7112706061976095e+1, -1.1208044642899116, 3.7131966511885444e+1, + -5.2298271025348962e+1, 3.3058589696624618e+1, 2.4791298976200222e-3, + -2.061089403411526e+1, 2.088672775145582e+1, -1.0045703956517752e+1, + -1.2238783449063012e-5, 4.0770134274221141, -3.473667358470195, + 1.4329352617312006, 7.1359914411879712e-8, -4.4797257159115612e-1, + 3.4112666080644461e-1, -1.2699786326594923e-1, -2.8953677269081528e-10, + 3.3125776278259863e-2, -2.3274087021036101e-2, 8.0399993503648882e-3, + -1.177805216235265e-9, -1.8321624891071668e-3, 1.2108282933588665e-3, + -3.9479941246822517e-4}, + {7.389033153567425e+1, -1.5680141270402273e+2, 1.322177542759164e+2, + 1.3692876877324546e-2, -1.2366496885920151e+2, 1.4620689391062729e+2, + -8.0365587724865346e+1, -1.1259851148881298e-4, 4.0770132196179938e+1, + -3.8210340013273034e+1, 1.719522294277362e+1, 9.3519707955168356e-7, + -6.2716159907747034, 5.1168999071852637, -2.0319658112299095, + -4.9507215582761543e-9, 5.9626397294332597e-1, -4.4220765337238094e-1, + 1.6079998700166273e-1, -2.4733786203223402e-8, -4.0307574759979762e-2, + 2.7849050747097869e-2, -9.4751858992054221e-3, 6.419922235909132e-6, + 2.1250180774699461e-3}, + {2.1216837098382522e+2, 1.3107863022633868e+1, -4.9698285932871748e+2, + 7.3121595266969204e+2, -4.8213821720890847e+2, -2.8817248692894889e-2, + 3.2616720302947102e+2, -3.4389340280087117e+2, 1.7195193870816232e+2, + 1.4038077378096158e-4, -7.52594195897599e+1, 6.651969984520934e+1, + -2.8447519748152462e+1, -7.613702615875391e-7, 9.5402237105304373, + -7.5175301113311376, 2.8943997568871961, -4.6612194999538201e-7, + -8.0615149598794088e-1, 5.8483006570631029e-1, -2.0845408972964956e-1, + 1.4765818959305817e-4, 5.1000433863753019e-2, -3.3066252141883665e-2, + 1.5109265210467774e-2}, + {-9.8959643098322368e+2, 2.1925555360905233e+3, -1.9283586782723356e+3, + -1.5925738122215253e-1, 1.9569985945919857e+3, -2.4072514765081556e+3, + 1.3756149959336496e+3, 1.2920735237496668e-3, -7.525941715948055e+2, + 7.3171668742208716e+2, -3.4137023466220065e+2, -9.9857390260608043e-6, + 1.3356313181291573e+2, -1.1276295161252794e+2, 4.6310396098204458e+1, + -7.9237387133614756e-6, -1.4510726927018646e+1, 1.1111771248100563e+1, + -4.1690817945270892, 3.1008219800117808e-3, 1.1220095449981468, + -7.6052379926149916e-1, 3.6262236505085254e-1, 2.216867741940747e-1, + 4.8683443692930507e-1}}; + + int k, n, sgn; + int maxpow = 0; + static scalar_t MACHEP = std::is_same_v ? + 1.11022302462515654042E-16 : 5.9604644775390625E-8; + scalar_t lambda = x / a; + scalar_t sigma = (x - a) / a; + scalar_t eta, res, ck, ckterm, term, absterm; + scalar_t absoldterm = INFINITY; + scalar_t etapow[25] = {1}; + scalar_t sum = 0; + scalar_t afac = 1; + + if (igam) { + sgn = -1; + } + else { + sgn = 1; + } + + if (lambda > 1) { + eta = std::sqrt(-2 * (std::log1p(sigma) - sigma)); + } + else if (lambda < 1) { + eta = -std::sqrt(-2 * (std::log1p(sigma) - sigma)); + } + else { + eta = 0; + } + res = 0.5 * std::erfc(sgn * eta * std::sqrt(a / 2)); + + for (k = 0; k < 25; k++) { + ck = d[k][0]; + for (n = 1; n < 25; n++) { + if (n > maxpow) { + etapow[n] = eta * etapow[n-1]; + maxpow += 1; + } + ckterm = d[k][n]*etapow[n]; + ck += ckterm; + if (std::fabs(ckterm) < MACHEP * std::fabs(ck)) { + break; + } + } + term = ck * afac; + absterm = std::fabs(term); + if (absterm > absoldterm) { + break; + } + sum += term; + if (absterm < MACHEP * std::fabs(sum)) { + break; + } + absoldterm = absterm; + afac /= a; + } + res += sgn * std::exp(-0.5 * a * eta * eta) * sum / std::sqrt(2 * c10::pi * a); + + return res; +} + +template +static scalar_t _igamc_helper_continued_fraction(scalar_t a, scalar_t x) { + // Compute igamc using DLMF 8.9.2. [igam1] + int i; + scalar_t ans, ax, c, yc, r, t, y, z; + scalar_t pk, pkm1, pkm2, qk, qkm1, qkm2; + int MAXITER = 2000; + static scalar_t MACHEP = std::is_same_v ? + 1.11022302462515654042E-16 : 5.9604644775390625E-8; + static scalar_t BIG = std::is_same_v ? + 4.503599627370496e15 : 16777216.; + static scalar_t BIGINV = std::is_same_v ? + 2.22044604925031308085e-16 : 5.9604644775390625E-8; + + ax = _igam_helper_fac(a, x); + if (ax == 0.0) { + return 0.0; + } + + /* continued fraction */ + y = 1.0 - a; + z = x + y + 1.0; + c = 0.0; + pkm2 = 1.0; + qkm2 = x; + pkm1 = x + 1.0; + qkm1 = z * x; + ans = pkm1 / qkm1; + + for (i = 0; i < MAXITER; i++) { + c += 1.0; + y += 1.0; + z += 2.0; + yc = y * c; + pk = pkm1 * z - pkm2 * yc; + qk = qkm1 * z - qkm2 * yc; + if (qk != 0) { + r = pk / qk; + t = std::fabs((ans - r) / r); + ans = r; + } + else { + t = 1.0; + } + pkm2 = pkm1; + pkm1 = pk; + qkm2 = qkm1; + qkm1 = qk; + if (std::fabs(pk) > BIG) { + pkm2 *= BIGINV; + pkm1 *= BIGINV; + qkm2 *= BIGINV; + qkm1 *= BIGINV; + } + if (t <= MACHEP) { + break; + } + } + return ans * ax; +} + +template +inline scalar_t calc_igammac(scalar_t a, scalar_t x) { + /* the calculation of the regularized upper incomplete gamma function + * is done differently based on the values of a and x: + * - if x and/or a is at the boundary of defined region, then assign the + * result at the boundary + * - if a is large and a ~ x, then using Uniform Asymptotic Expansions for + * Large Parameter (see DLMF 8.12.4 [igam1]) + * - if x > 1.1 and x < a, using the substraction from the regularized lower + * incomplete gamma + * - otherwise, calculate the series from [igam2] eq (5) + */ + scalar_t absxma_a; + + static scalar_t SMALL = 20.0; + static scalar_t LARGE = 200.0; + static scalar_t SMALLRATIO = 0.3; + static scalar_t LARGERATIO = 4.5; + + // note that in SciPy, a and x are non-negative, with exclusive 0s (i.e., + // at most 1 of them can be 0), where igammac(0, x) = 0.0 iff x > 0. + if ((x < 0) || (a < 0)) { + // out of defined-region of the function + return std::numeric_limits::quiet_NaN(); + } + else if (a == 0) { + if (x > 0) { + return 0.0; + } + else { + return std::numeric_limits::quiet_NaN(); + } + } + else if (x == 0) { + return 1.0; + } + else if (std::isinf(a)) { + if (std::isinf(x)) { + return std::numeric_limits::quiet_NaN(); + } + return 1.0; + } + else if (std::isinf(x)) { + return 0.0; + } + + absxma_a = std::fabs(x - a) / a; + if ((a > SMALL) && (a < LARGE) && (absxma_a < SMALLRATIO)) { + return _igam_helper_asymptotic_series(a, x, 0); + } + else if ((a > LARGE) && (absxma_a < LARGERATIO / std::sqrt(a))) { + return _igam_helper_asymptotic_series(a, x, 0); + } + + if (x > 1.1) { + if (x < a) { + return 1.0 - _igam_helper_series(a, x); + } + else { + return _igamc_helper_continued_fraction(a, x); + } + } + else if (x <= 0.5) { + if (-0.4 / std::log(x) < a) { + return 1.0 - _igam_helper_series(a, x); + } + else { + return _igamc_helper_series(a, x); + } + } + else { + if (x * 1.1 < a) { + return 1.0 - _igam_helper_series(a, x); + } + else { + return _igamc_helper_series(a, x); + } + } +} + +template +scalar_t calc_igamma(scalar_t a, scalar_t x) { + /* the calculation of the regularized lower incomplete gamma function + * is done differently based on the values of a and x: + * - if x and/or a is at the boundary of defined region, then assign the + * result at the boundary + * - if a is large and a ~ x, then using Uniform Asymptotic Expansions for + * Large Parameter (see DLMF 8.12.3 [igam1]) + * - if x > 1 and x > a, using the substraction from the regularized upper + * incomplete gamma + * - otherwise, calculate the series from [igam2] eq (4) + */ + scalar_t absxma_a; + static scalar_t SMALL = 20.0; + static scalar_t LARGE = 200.0; + static scalar_t SMALLRATIO = 0.3; + static scalar_t LARGERATIO = 4.5; + + // boundary values following SciPy + // note that in SciPy, a and x are non-negative, with exclusive 0s (i.e., + // at most 1 of them can be 0), where igamma(0, x) = 1.0 iff x > 0. + if ((x < 0) || (a < 0)) { + // out of defined-region of the function + return std::numeric_limits::quiet_NaN(); + } + else if (a == 0) { + if (x > 0) { + return 1.0; + } + else { + return std::numeric_limits::quiet_NaN(); + } + } + else if (x == 0) { + return 0.0; // zero integration limit + } + else if (std::isinf(a)) { + if (std::isinf(x)) { + return std::numeric_limits::quiet_NaN(); + } + return 0.0; + } + else if (std::isinf(x)) { + return 1.0; + } + + /* Asymptotic regime where a ~ x. See [igam2] */ + absxma_a = std::fabs(x - a) / a; + if ((a > SMALL) && (a < LARGE) && (absxma_a < SMALLRATIO)) { + return _igam_helper_asymptotic_series(a, x, 1); + } + else if ((a > LARGE) && (absxma_a < LARGERATIO / std::sqrt(a))) { + return _igam_helper_asymptotic_series(a, x, 1); + } + + if ((x > 1.0) && (x > a)) { + return 1.0 - calc_igammac(a, x); + } + + return _igam_helper_series(a, x); +} + +template <> +[[maybe_unused]] inline c10::BFloat16 calc_igamma( + c10::BFloat16 a, + c10::BFloat16 x) { + return calc_igamma(float(a), float(x)); +} + +template <> +[[maybe_unused]] inline c10::Half calc_igamma( + c10::Half a, + c10::Half x) { + return calc_igamma(float(a), float(x)); +} + +template <> +[[maybe_unused]] inline c10::BFloat16 calc_igammac( + c10::BFloat16 a, + c10::BFloat16 x) { + return calc_igammac(float(a), float(x)); +} + +template <> +[[maybe_unused]] inline c10::Half calc_igammac( + c10::Half a, + c10::Half x) { + return calc_igammac(float(a), float(x)); +} + +inline c10::BFloat16 calc_erfinv(c10::BFloat16 a) { return calc_erfinv(float(a)); } + +template +inline T abs_impl(T v) { + return std::abs(v); +} + +template <> +[[maybe_unused]] inline uint8_t abs_impl(uint8_t v) { + return v; +} + +template +inline typename std::enable_if_t, T> +calc_gcd(T a, T b) { + a = abs_impl(a); + b = abs_impl(b); + while (a != 0) { + T c = a; + a = b % a; + b = c; + } + return b; +} + +template +C10_HOST_DEVICE T exp2_impl(T x) { + return std::exp2(x); +} + +template +C10_HOST_DEVICE c10::complex exp2_impl(c10::complex x) { + // There is no std::exp2 overload for complex, so instead + // use the identity 2^x = e^(ln(2) * x) + constexpr auto ln2 = c10::ln_2; + return std::exp(ln2 * x); +} + +/* + * This function is derived from the implementation of the chbevl function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + * + * Evaluates the series + * + * len-1 + * - ' + * y = > array[i] T (x/2) + * - i + * i=0 + * + * of Chebyshev polynomials Ti at argument x/2. + * + * Coefficients are stored in reverse order, i.e. the zero order term is last in the array. Note len is the number of + * coefficients, not the order. + * + * If coefficients are for the interval a to b, x must have been transformed to x -> 2(2x - b - a)/(b-a) before + * entering the routine. This maps x from (a, b) to (-1, 1), over which the Chebyshev polynomials are defined. + * + * If the coefficients are for the inverted interval, in which (a, b) is mapped to (1/b, 1/a), the transformation + * required is x -> 2(2ab/x - b - a)/(b-a). If b is infinity, this becomes x -> 4a/x - 1. + */ +template +inline typename std::enable_if_t, T> +chbevl(const T x, const T array[], size_t len) { + T b0, b1, b2; + + b0 = array[0]; + b1 = static_cast(0.0); + + for (size_t i = 1; i < len; ++i) { + b2 = b1; + b1 = b0; + b0 = x * b1 - b2 + array[i]; + } + + return (static_cast(0.5) * (b0 - b2)); +} + +/* + * This function is derived from the implementation of the i0 function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + * + * Computes an approximation of the zeroth order modified Bessel function of the first kind. + * The approximation is actually two (sub)approximations, both using a Chebyshev polynomial expansion. + * One approximates the function over [0, 8], and the other over (8, infinity). This function takes the absolute value + * of all inputs to convert them into the domain of the approximation. + */ +template +inline std::tuple chebyshev_coefficients_i0e_A() { + /* Chebyshev coefficients for exp(-x) I0(x) + * in the interval [0,8]. + * + * lim(x->0){ exp(-x) I0(x) } = 1. + */ + static const T coeff[] = { + -4.41534164647933937950E-18, 3.33079451882223809783E-17, + -2.43127984654795469359E-16, 1.71539128555513303061E-15, + -1.16853328779934516808E-14, 7.67618549860493561688E-14, + -4.85644678311192946090E-13, 2.95505266312963983461E-12, + -1.72682629144155570723E-11, 9.67580903537323691224E-11, + -5.18979560163526290666E-10, 2.65982372468238665035E-9, + -1.30002500998624804212E-8, 6.04699502254191894932E-8, + -2.67079385394061173391E-7, 1.11738753912010371815E-6, + -4.41673835845875056359E-6, 1.64484480707288970893E-5, + -5.75419501008210370398E-5, 1.88502885095841655729E-4, + -5.76375574538582365885E-4, 1.63947561694133579842E-3, + -4.32430999505057594430E-3, 1.05464603945949983183E-2, + -2.37374148058994688156E-2, 4.93052842396707084878E-2, + -9.49010970480476444210E-2, 1.71620901522208775349E-1, + -3.04682672343198398683E-1, 6.76795274409476084995E-1}; + return std::make_tuple(coeff, 30); +} + +template +inline std::tuple chebyshev_coefficients_i0e_B() { + /* Chebyshev coefficients for exp(-x) sqrt(x) I0(x) + * in the inverted interval [8,infinity]. + * + * lim(x->inf){ exp(-x) sqrt(x) I0(x) } = 1/sqrt(2pi). + */ + static const T coeff[] = { + -7.23318048787475395456E-18, -4.83050448594418207126E-18, + 4.46562142029675999901E-17, 3.46122286769746109310E-17, + -2.82762398051658348494E-16, -3.42548561967721913462E-16, + 1.77256013305652638360E-15, 3.81168066935262242075E-15, + -9.55484669882830764870E-15, -4.15056934728722208663E-14, + 1.54008621752140982691E-14, 3.85277838274214270114E-13, + 7.18012445138366623367E-13, -1.79417853150680611778E-12, + -1.32158118404477131188E-11, -3.14991652796324136454E-11, + 1.18891471078464383424E-11, 4.94060238822496958910E-10, + 3.39623202570838634515E-9, 2.26666899049817806459E-8, + 2.04891858946906374183E-7, 2.89137052083475648297E-6, + 6.88975834691682398426E-5, 3.36911647825569408990E-3, + 8.04490411014108831608E-1}; + + return std::make_tuple(coeff, 25); +} + +template +inline typename std::enable_if_t, std::tuple> +chebyshev_coefficients_i1e_A() { + /* Chebyshev coefficients for exp(-x) I1(x) + * in the interval [0,8]. + * + * lim(x->0){ exp(-x) I1(x) / x } = 1/2. + */ + static const T coeff[] = { + 2.77791411276104639959E-18, -2.11142121435816608115E-17, + 1.55363195773620046921E-16, -1.10559694773538630805E-15, + 7.60068429473540693410E-15, -5.04218550472791168711E-14, + 3.22379336594557470981E-13, -1.98397439776494371520E-12, + 1.17361862988909016308E-11, -6.66348972350202774223E-11, + 3.62559028155211703701E-10, -1.88724975172282928790E-9, + 9.38153738649577178388E-9, -4.44505912879632808065E-8, + 2.00329475355213526229E-7, -8.56872026469545474066E-7, + 3.47025130813767847674E-6, -1.32731636560394358279E-5, + 4.78156510755005422638E-5, -1.61760815825896745588E-4, + 5.12285956168575772895E-4, -1.51357245063125314899E-3, + 4.15642294431288815669E-3, -1.05640848946261981558E-2, + 2.47264490306265168283E-2, -5.29459812080949914269E-2, + 1.02643658689847095384E-1, -1.76416518357834055153E-1, + 2.52587186443633654823E-1}; + return std::make_tuple(coeff, 29); +} + +template +inline typename std::enable_if_t, std::tuple> +chebyshev_coefficients_i1e_A() { + /* Chebyshev coefficients for exp(-x) I1(x) + * in the interval [0,8]. + * + * lim(x->0){ exp(-x) I1(x) / x } = 1/2. + */ + static const T coeff[] = { + 9.38153738649577178388E-9f, + -4.44505912879632808065E-8f, + 2.00329475355213526229E-7f, + -8.56872026469545474066E-7f, + 3.47025130813767847674E-6f, + -1.32731636560394358279E-5f, + 4.78156510755005422638E-5f, + -1.61760815825896745588E-4f, + 5.12285956168575772895E-4f, + -1.51357245063125314899E-3f, + 4.15642294431288815669E-3f, + -1.05640848946261981558E-2f, + 2.47264490306265168283E-2f, + -5.29459812080949914269E-2f, + 1.02643658689847095384E-1f, + -1.76416518357834055153E-1f, + 2.52587186443633654823E-1f}; + return std::make_tuple(coeff, 17); +} + +template +inline typename std::enable_if_t, std::tuple> +chebyshev_coefficients_i1e_B() { + /* Chebyshev coefficients for exp(-x) sqrt(x) I1(x) + * in the inverted interval [8,infinity]. + * + * lim(x->inf){ exp(-x) sqrt(x) I1(x) } = 1/sqrt(2pi). + */ + static const T coeff[] = { + 7.51729631084210481353E-18, 4.41434832307170791151E-18, + -4.65030536848935832153E-17, -3.20952592199342395980E-17, + 2.96262899764595013876E-16, 3.30820231092092828324E-16, + -1.88035477551078244854E-15, -3.81440307243700780478E-15, + 1.04202769841288027642E-14, 4.27244001671195135429E-14, + -2.10154184277266431302E-14, -4.08355111109219731823E-13, + -7.19855177624590851209E-13, 2.03562854414708950722E-12, + 1.41258074366137813316E-11, 3.25260358301548823856E-11, + -1.89749581235054123450E-11, -5.58974346219658380687E-10, + -3.83538038596423702205E-9, -2.63146884688951950684E-8, + -2.51223623787020892529E-7, -3.88256480887769039346E-6, + -1.10588938762623716291E-4, -9.76109749136146840777E-3, + 7.78576235018280120474E-1}; + + return std::make_tuple(coeff, 25); +} + +template +inline typename std::enable_if_t, std::tuple> +chebyshev_coefficients_i1e_B() { + /* Chebyshev coefficients for exp(-x) sqrt(x) I1(x) + * in the inverted interval [8,infinity]. + * + * lim(x->inf){ exp(-x) sqrt(x) I1(x) } = 1/sqrt(2pi). + */ + static const T coeff[] = { + -3.83538038596423702205E-9f, + -2.63146884688951950684E-8f, + -2.51223623787020892529E-7f, + -3.88256480887769039346E-6f, + -1.10588938762623716291E-4f, + -9.76109749136146840777E-3f, + 7.78576235018280120474E-1f}; + + return std::make_tuple(coeff, 7); +} + +template +inline typename std::enable_if_t, T> +calc_i0(T _x) { + T x = std::abs(_x); + + if (x <= T{8.0}) { + auto [A, len] = chebyshev_coefficients_i0e_A(); + T y = (x / T{2.0}) - T{2.0}; + return static_cast(std::exp(x) * chbevl(y, A, len)); + } + auto [B, len] = chebyshev_coefficients_i0e_B(); + return std::exp(x) * chbevl(T{32.0} / x - T{2.0}, B, len) / std::sqrt(x); +} + +// Upcast bfloat16/half input to float for numerical accuracy purposes +inline c10::BFloat16 calc_i0(c10::BFloat16 a) { return calc_i0(static_cast(a)); } +inline c10::Half calc_i0(c10::Half a) { return calc_i0(static_cast(a)); } + +/* + * This function is derived from the implementation of the i1 function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + * + * Computes an approximation of the first order modified Bessel function of the first kind. + * The approximation is actually two (sub)approximations, both using a Chebyshev polynomial expansion. + * One approximates the function over [0, 8], and the other over (8, infinity). This function takes the absolute value + * of all inputs to convert them into the domain of the approximation. + */ +template +inline typename std::enable_if_t, T> +calc_i1(T _x) { + T x = std::abs(_x); + + if (x <= T{8.0}) { + auto [A, len] = chebyshev_coefficients_i1e_A(); + T y = (x / T{2.0}) - T{2.0}; + const T out = std::exp(x) * x * chbevl(y, A, len); + return (_x < T{0.0}) ? -out : out; + } + auto [B, len] = chebyshev_coefficients_i1e_B(); + const T out = (std::exp(x) * chbevl(T{32.0} / x - T{2.0}, B, len)) / std::sqrt(x); + return (_x < T{0.0}) ? -out : out; +} + +// Upcast bfloat16/half input to float for numerical accuracy purposes +inline c10::BFloat16 calc_i1(c10::BFloat16 a) { return calc_i1(static_cast(a)); } +inline c10::Half calc_i1(c10::Half a) { return calc_i1(static_cast(a)); } + + +/* + * This function is derived from the implementation of the i1e function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + * + * Computes an approximation of the exponentially scaled first order modified Bessel function of the first kind. + * The approximation is actually two (sub)approximations, both using a Chebyshev polynomial expansion. + * One approximates the function over [0, 8], and the other over (8, infinity). This function takes the absolute value + * of all inputs to convert them into the domain of the approximation. + */ +template +inline typename std::enable_if_t, T> +calc_i1e(T _x) { + T x = std::abs(_x); + + if (x <= T{8.0}) { + auto [A, len] = chebyshev_coefficients_i1e_A(); + T y = (x / T{2.0}) - T{2.0}; + const T out = chbevl(y, A, len) * x; + return (_x < T{0.0}) ? -out : out; + } + auto [B, len] = chebyshev_coefficients_i1e_B(); + const auto out = chbevl(T{32.0} / x - T{2.0}, B, len) / std::sqrt(x); + return (_x < T{0.0}) ? -out : out; +} + +// Upcast bfloat16/half input to float for numerical accuracy purposes +inline c10::BFloat16 calc_i1e(c10::BFloat16 a) { return calc_i1e(static_cast(a)); } +inline c10::Half calc_i1e(c10::Half a) { return calc_i1e(static_cast(a)); } + + +/* + * This function is derived from the implementation of the i1e function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + * + * Computes the argument, x, for which the area under the Gaussian probability density function + * (integrated from minus infinity to x) is equal to y. + */ +template +inline C10_HOST_DEVICE T calc_ndtri(T y0) { + + /* sqrt(2pi) */ + constexpr T s2pi = 2.50662827463100050242E0; + constexpr T one = 1; + constexpr T zero = 0; + + /* approximation for 0 <= |y - 0.5| <= 3/8 */ + static const T P0[5] = { + -5.99633501014107895267E1, + 9.80010754185999661536E1, + -5.66762857469070293439E1, + 1.39312609387279679503E1, + -1.23916583867381258016E0, + }; + + static const T Q0[9] = { + 1.00000000000000000000E0, + 1.95448858338141759834E0, + 4.67627912898881538453E0, + 8.63602421390890590575E1, + -2.25462687854119370527E2, + 2.00260212380060660359E2, + -8.20372256168333339912E1, + 1.59056225126211695515E1, + -1.18331621121330003142E0, + }; + + /* Approximation for interval z = sqrt(-2 log y ) between 2 and 8 + * i.e., y between exp(-2) = .135 and exp(-32) = 1.27e-14. + */ + static const T P1[9] = { + 4.05544892305962419923E0, + 3.15251094599893866154E1, + 5.71628192246421288162E1, + 4.40805073893200834700E1, + 1.46849561928858024014E1, + 2.18663306850790267539E0, + -1.40256079171354495875E-1, + -3.50424626827848203418E-2, + -8.57456785154685413611E-4, + }; + + static const T Q1[9] = { + 1.00000000000000000000E0, + 1.57799883256466749731E1, + 4.53907635128879210584E1, + 4.13172038254672030440E1, + 1.50425385692907503408E1, + 2.50464946208309415979E0, + -1.42182922854787788574E-1, + -3.80806407691578277194E-2, + -9.33259480895457427372E-4, + }; + + /* Approximation for interval z = sqrt(-2 log y ) between 8 and 64 + * i.e., y between exp(-32) = 1.27e-14 and exp(-2048) = 3.67e-890. + */ + + static const T P2[9] = { + 3.23774891776946035970E0, + 6.91522889068984211695E0, + 3.93881025292474443415E0, + 1.33303460815807542389E0, + 2.01485389549179081538E-1, + 1.23716634817820021358E-2, + 3.01581553508235416007E-4, + 2.65806974686737550832E-6, + 6.23974539184983293730E-9, + }; + + static const T Q2[9] = { + 1.00000000000000000000E0, + 6.02427039364742014255E0, + 3.67983563856160859403E0, + 1.37702099489081330271E0, + 2.16236993594496635890E-1, + 1.34204006088543189037E-2, + 3.28014464682127739104E-4, + 2.89247864745380683936E-6, + 6.79019408009981274425E-9, + }; + + if (y0 == zero) { + return -std::numeric_limits::infinity(); + } + if (y0 == one) { + return std::numeric_limits::infinity(); + } + if (y0 < zero || y0 > one) { + return std::numeric_limits::quiet_NaN(); + } + bool code = true; + T y = y0; + if (y > one - T{0.13533528323661269189}) { /* 0.135... = exp(-2) */ + y = one - y; + code = false; + } + + if (y > T{0.13533528323661269189}) { + y = y - T{0.5}; + const T y2 = y * y; + T x = y + y * (y2 * polevl(y2, P0, 4) / polevl(y2, Q0, 8)); + return (x * s2pi); + } + + T x = ::sqrt(T{-2.0} * ::log(y)); + const T x0 = x - ::log(x) / x; + + const T z = one / x; + T x1; + if (x < T{8.0}) /* y > exp(-32) = 1.2664165549e-14 */ + { + x1 = z * polevl(z, P1, 8) / polevl(z, Q1, 8); + } else { + x1 = z * polevl(z, P2, 8) / polevl(z, Q2, 8); + } + x = x0 - x1; + if (code) { + x = -x; + } + return x; +} + +/* The next function is taken from http://ab-initio.mit.edu/Faddeev */ + +/* Copyright (c) 2012 Massachusetts Institute of Technology + * + * Permission is hereby granted, free of charge, to any person obtaining + * a copy of this software and associated documentation files (the + * "Software"), to deal in the Software without restriction, including + * without limitation the rights to use, copy, modify, merge, publish, + * distribute, sublicense, and/or sell copies of the Software, and to + * permit persons to whom the Software is furnished to do so, subject to + * the following conditions: + * + * The above copyright notice and this permission notice shall be + * included in all copies or substantial portions of the Software. + * + * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, + * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF + * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND + * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE + * LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION + * OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION + * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. + */ + +/* erfcx(x) = exp(x^2) erfc(x) function, for real x, written by + Steven G. Johnson, October 2012. + + This function combines a few different ideas. + + First, for x > 50, it uses a continued-fraction expansion (same as + for the Faddeeva function, but with algebraic simplifications for z=i*x). + + Second, for 0 <= x <= 50, it uses Chebyshev polynomial approximations, + but with two twists: + + a) It maps x to y = 4 / (4+x) in [0,1]. This simple transformation, + inspired by a similar transformation in the octave-forge/specfun + erfcx by Soren Hauberg, results in much faster Chebyshev convergence + than other simple transformations I have examined. + + b) Instead of using a single Chebyshev polynomial for the entire + [0,1] y interval, we break the interval up into 100 equal + subintervals, with a switch/lookup table, and use much lower + degree Chebyshev polynomials in each subinterval. This greatly + improves performance in my tests. + + For x < 0, we use the relationship erfcx(-x) = 2 exp(x^2) - erfc(x), + with the usual checks for overflow etcetera. + + Performance-wise, it seems to be substantially faster than either + the SLATEC DERFC function [or an erfcx function derived therefrom] + or Cody's CALERF function (from netlib.org/specfun), while + retaining near machine precision in accuracy. */ + +/* Given y100=100*y, where y = 4/(4+x) for x >= 0, compute erfc(x). + + Uses a look-up table of 100 different Chebyshev polynomials + for y intervals [0,0.01], [0.01,0.02], ...., [0.99,1], generated + with the help of Maple and a little shell script. This allows + the Chebyshev polynomials to be of significantly lower degree (about 1/4) + compared to fitting the whole [0,1] interval with a single polynomial. */ + + +template +C10_HOST_DEVICE inline typename std::enable_if_t, T> +erfcx_y100(T y100) +{ + switch (static_cast(y100)) { +case 0: { +T t = 2*y100 - 1; +return 0.70878032454106438663e-3 + (0.71234091047026302958e-3 + (0.35779077297597742384e-5 + (0.17403143962587937815e-7 + (0.81710660047307788845e-10 + (0.36885022360434957634e-12 + 0.15917038551111111111e-14 * t) * t) * t) * t) * t) * t; +} +case 1: { +T t = 2*y100 - 3; +return 0.21479143208285144230e-2 + (0.72686402367379996033e-3 + (0.36843175430938995552e-5 + (0.18071841272149201685e-7 + (0.85496449296040325555e-10 + (0.38852037518534291510e-12 + 0.16868473576888888889e-14 * t) * t) * t) * t) * t) * t; +} +case 2: { +T t = 2*y100 - 5; +return 0.36165255935630175090e-2 + (0.74182092323555510862e-3 + (0.37948319957528242260e-5 + (0.18771627021793087350e-7 + (0.89484715122415089123e-10 + (0.40935858517772440862e-12 + 0.17872061464888888889e-14 * t) * t) * t) * t) * t) * t; +} +case 3: { +T t = 2*y100 - 7; +return 0.51154983860031979264e-2 + (0.75722840734791660540e-3 + (0.39096425726735703941e-5 + (0.19504168704300468210e-7 + (0.93687503063178993915e-10 + (0.43143925959079664747e-12 + 0.18939926435555555556e-14 * t) * t) * t) * t) * t) * t; +} +case 4: { +T t = 2*y100 - 9; +return 0.66457513172673049824e-2 + (0.77310406054447454920e-3 + (0.40289510589399439385e-5 + (0.20271233238288381092e-7 + (0.98117631321709100264e-10 + (0.45484207406017752971e-12 + 0.20076352213333333333e-14 * t) * t) * t) * t) * t) * t; +} +case 5: { +T t = 2*y100 - 11; +return 0.82082389970241207883e-2 + (0.78946629611881710721e-3 + (0.41529701552622656574e-5 + (0.21074693344544655714e-7 + (0.10278874108587317989e-9 + (0.47965201390613339638e-12 + 0.21285907413333333333e-14 * t) * t) * t) * t) * t) * t; +} +case 6: { +T t = 2*y100 - 13; +return 0.98039537275352193165e-2 + (0.80633440108342840956e-3 + (0.42819241329736982942e-5 + (0.21916534346907168612e-7 + (0.10771535136565470914e-9 + (0.50595972623692822410e-12 + 0.22573462684444444444e-14 * t) * t) * t) * t) * t) * t; +} +case 7: { +T t = 2*y100 - 15; +return 0.11433927298290302370e-1 + (0.82372858383196561209e-3 + (0.44160495311765438816e-5 + (0.22798861426211986056e-7 + (0.11291291745879239736e-9 + (0.53386189365816880454e-12 + 0.23944209546666666667e-14 * t) * t) * t) * t) * t) * t; +} +case 8: { +T t = 2*y100 - 17; +return 0.13099232878814653979e-1 + (0.84167002467906968214e-3 + (0.45555958988457506002e-5 + (0.23723907357214175198e-7 + (0.11839789326602695603e-9 + (0.56346163067550237877e-12 + 0.25403679644444444444e-14 * t) * t) * t) * t) * t) * t; +} +case 9: { +T t = 2*y100 - 19; +return 0.14800987015587535621e-1 + (0.86018092946345943214e-3 + (0.47008265848816866105e-5 + (0.24694040760197315333e-7 + (0.12418779768752299093e-9 + (0.59486890370320261949e-12 + 0.26957764568888888889e-14 * t) * t) * t) * t) * t) * t; +} +case 10: { +T t = 2*y100 - 21; +return 0.16540351739394069380e-1 + (0.87928458641241463952e-3 + (0.48520195793001753903e-5 + (0.25711774900881709176e-7 + (0.13030128534230822419e-9 + (0.62820097586874779402e-12 + 0.28612737351111111111e-14 * t) * t) * t) * t) * t) * t; +} +case 11: { +T t = 2*y100 - 23; +return 0.18318536789842392647e-1 + (0.89900542647891721692e-3 + (0.50094684089553365810e-5 + (0.26779777074218070482e-7 + (0.13675822186304615566e-9 + (0.66358287745352705725e-12 + 0.30375273884444444444e-14 * t) * t) * t) * t) * t) * t; +} +case 12: { +T t = 2*y100 - 25; +return 0.20136801964214276775e-1 + (0.91936908737673676012e-3 + (0.51734830914104276820e-5 + (0.27900878609710432673e-7 + (0.14357976402809042257e-9 + (0.70114790311043728387e-12 + 0.32252476000000000000e-14 * t) * t) * t) * t) * t) * t; +} +case 13: { +T t = 2*y100 - 27; +return 0.21996459598282740954e-1 + (0.94040248155366777784e-3 + (0.53443911508041164739e-5 + (0.29078085538049374673e-7 + (0.15078844500329731137e-9 + (0.74103813647499204269e-12 + 0.34251892320000000000e-14 * t) * t) * t) * t) * t) * t; +} +case 14: { +T t = 2*y100 - 29; +return 0.23898877187226319502e-1 + (0.96213386835900177540e-3 + (0.55225386998049012752e-5 + (0.30314589961047687059e-7 + (0.15840826497296335264e-9 + (0.78340500472414454395e-12 + 0.36381553564444444445e-14 * t) * t) * t) * t) * t) * t; +} +case 15: { +T t = 2*y100 - 31; +return 0.25845480155298518485e-1 + (0.98459293067820123389e-3 + (0.57082915920051843672e-5 + (0.31613782169164830118e-7 + (0.16646478745529630813e-9 + (0.82840985928785407942e-12 + 0.38649975768888888890e-14 * t) * t) * t) * t) * t) * t; +} +case 16: { +T t = 2*y100 - 33; +return 0.27837754783474696598e-1 + (0.10078108563256892757e-2 + (0.59020366493792212221e-5 + (0.32979263553246520417e-7 + (0.17498524159268458073e-9 + (0.87622459124842525110e-12 + 0.41066206488888888890e-14 * t) * t) * t) * t) * t) * t; +} +case 17: { +T t = 2*y100 - 35; +return 0.29877251304899307550e-1 + (0.10318204245057349310e-2 + (0.61041829697162055093e-5 + (0.34414860359542720579e-7 + (0.18399863072934089607e-9 + (0.92703227366365046533e-12 + 0.43639844053333333334e-14 * t) * t) * t) * t) * t) * t; +} +case 18: { +T t = 2*y100 - 37; +return 0.31965587178596443475e-1 + (0.10566560976716574401e-2 + (0.63151633192414586770e-5 + (0.35924638339521924242e-7 + (0.19353584758781174038e-9 + (0.98102783859889264382e-12 + 0.46381060817777777779e-14 * t) * t) * t) * t) * t) * t; +} +case 19: { +T t = 2*y100 - 39; +return 0.34104450552588334840e-1 + (0.10823541191350532574e-2 + (0.65354356159553934436e-5 + (0.37512918348533521149e-7 + (0.20362979635817883229e-9 + (0.10384187833037282363e-11 + 0.49300625262222222221e-14 * t) * t) * t) * t) * t) * t; +} +case 20: { +T t = 2*y100 - 41; +return 0.36295603928292425716e-1 + (0.11089526167995268200e-2 + (0.67654845095518363577e-5 + (0.39184292949913591646e-7 + (0.21431552202133775150e-9 + (0.10994259106646731797e-11 + 0.52409949102222222221e-14 * t) * t) * t) * t) * t) * t; +} +case 21: { +T t = 2*y100 - 43; +return 0.38540888038840509795e-1 + (0.11364917134175420009e-2 + (0.70058230641246312003e-5 + (0.40943644083718586939e-7 + (0.22563034723692881631e-9 + (0.11642841011361992885e-11 + 0.55721092871111111110e-14 * t) * t) * t) * t) * t) * t; +} +case 22: { +T t = 2*y100 - 45; +return 0.40842225954785960651e-1 + (0.11650136437945673891e-2 + (0.72569945502343006619e-5 + (0.42796161861855042273e-7 + (0.23761401711005024162e-9 + (0.12332431172381557035e-11 + 0.59246802364444444445e-14 * t) * t) * t) * t) * t) * t; +} +case 23: { +T t = 2*y100 - 47; +return 0.43201627431540222422e-1 + (0.11945628793917272199e-2 + (0.75195743532849206263e-5 + (0.44747364553960993492e-7 + (0.25030885216472953674e-9 + (0.13065684400300476484e-11 + 0.63000532853333333334e-14 * t) * t) * t) * t) * t) * t; +} +case 24: { +T t = 2*y100 - 49; +return 0.45621193513810471438e-1 + (0.12251862608067529503e-2 + (0.77941720055551920319e-5 + (0.46803119830954460212e-7 + (0.26375990983978426273e-9 + (0.13845421370977119765e-11 + 0.66996477404444444445e-14 * t) * t) * t) * t) * t) * t; +} +case 25: { +T t = 2*y100 - 51; +return 0.48103121413299865517e-1 + (0.12569331386432195113e-2 + (0.80814333496367673980e-5 + (0.48969667335682018324e-7 + (0.27801515481905748484e-9 + (0.14674637611609884208e-11 + 0.71249589351111111110e-14 * t) * t) * t) * t) * t) * t; +} +case 26: { +T t = 2*y100 - 53; +return 0.50649709676983338501e-1 + (0.12898555233099055810e-2 + (0.83820428414568799654e-5 + (0.51253642652551838659e-7 + (0.29312563849675507232e-9 + (0.15556512782814827846e-11 + 0.75775607822222222221e-14 * t) * t) * t) * t) * t) * t; +} +case 27: { +T t = 2*y100 - 55; +return 0.53263363664388864181e-1 + (0.13240082443256975769e-2 + (0.86967260015007658418e-5 + (0.53662102750396795566e-7 + (0.30914568786634796807e-9 + (0.16494420240828493176e-11 + 0.80591079644444444445e-14 * t) * t) * t) * t) * t) * t; +} +case 28: { +T t = 2*y100 - 57; +return 0.55946601353500013794e-1 + (0.13594491197408190706e-2 + (0.90262520233016380987e-5 + (0.56202552975056695376e-7 + (0.32613310410503135996e-9 + (0.17491936862246367398e-11 + 0.85713381688888888890e-14 * t) * t) * t) * t) * t) * t; +} +case 29: { +T t = 2*y100 - 59; +return 0.58702059496154081813e-1 + (0.13962391363223647892e-2 + (0.93714365487312784270e-5 + (0.58882975670265286526e-7 + (0.34414937110591753387e-9 + (0.18552853109751857859e-11 + 0.91160736711111111110e-14 * t) * t) * t) * t) * t) * t; +} +case 30: { +T t = 2*y100 - 61; +return 0.61532500145144778048e-1 + (0.14344426411912015247e-2 + (0.97331446201016809696e-5 + (0.61711860507347175097e-7 + (0.36325987418295300221e-9 + (0.19681183310134518232e-11 + 0.96952238400000000000e-14 * t) * t) * t) * t) * t) * t; +} +case 31: { +T t = 2*y100 - 63; +return 0.64440817576653297993e-1 + (0.14741275456383131151e-2 + (0.10112293819576437838e-4 + (0.64698236605933246196e-7 + (0.38353412915303665586e-9 + (0.20881176114385120186e-11 + 0.10310784480000000000e-13 * t) * t) * t) * t) * t) * t; +} +case 32: { +T t = 2*y100 - 65; +return 0.67430045633130393282e-1 + (0.15153655418916540370e-2 + (0.10509857606888328667e-4 + (0.67851706529363332855e-7 + (0.40504602194811140006e-9 + (0.22157325110542534469e-11 + 0.10964842115555555556e-13 * t) * t) * t) * t) * t) * t; +} +case 33: { +T t = 2*y100 - 67; +return 0.70503365513338850709e-1 + (0.15582323336495709827e-2 + (0.10926868866865231089e-4 + (0.71182482239613507542e-7 + (0.42787405890153386710e-9 + (0.23514379522274416437e-11 + 0.11659571751111111111e-13 * t) * t) * t) * t) * t) * t; +} +case 34: { +T t = 2*y100 - 69; +return 0.73664114037944596353e-1 + (0.16028078812438820413e-2 + (0.11364423678778207991e-4 + (0.74701423097423182009e-7 + (0.45210162777476488324e-9 + (0.24957355004088569134e-11 + 0.12397238257777777778e-13 * t) * t) * t) * t) * t) * t; +} +case 35: { +T t = 2*y100 - 71; +return 0.76915792420819562379e-1 + (0.16491766623447889354e-2 + (0.11823685320041302169e-4 + (0.78420075993781544386e-7 + (0.47781726956916478925e-9 + (0.26491544403815724749e-11 + 0.13180196462222222222e-13 * t) * t) * t) * t) * t) * t; +} +case 36: { +T t = 2*y100 - 73; +return 0.80262075578094612819e-1 + (0.16974279491709504117e-2 + (0.12305888517309891674e-4 + (0.82350717698979042290e-7 + (0.50511496109857113929e-9 + (0.28122528497626897696e-11 + 0.14010889635555555556e-13 * t) * t) * t) * t) * t) * t; +} +case 37: { +T t = 2*y100 - 75; +return 0.83706822008980357446e-1 + (0.17476561032212656962e-2 + (0.12812343958540763368e-4 + (0.86506399515036435592e-7 + (0.53409440823869467453e-9 + (0.29856186620887555043e-11 + 0.14891851591111111111e-13 * t) * t) * t) * t) * t) * t; +} +case 38: { +T t = 2*y100 - 77; +return 0.87254084284461718231e-1 + (0.17999608886001962327e-2 + (0.13344443080089492218e-4 + (0.90900994316429008631e-7 + (0.56486134972616465316e-9 + (0.31698707080033956934e-11 + 0.15825697795555555556e-13 * t) * t) * t) * t) * t) * t; +} +case 39: { +T t = 2*y100 - 79; +return 0.90908120182172748487e-1 + (0.18544478050657699758e-2 + (0.13903663143426120077e-4 + (0.95549246062549906177e-7 + (0.59752787125242054315e-9 + (0.33656597366099099413e-11 + 0.16815130613333333333e-13 * t) * t) * t) * t) * t) * t; +} +case 40: { +T t = 2*y100 - 81; +return 0.94673404508075481121e-1 + (0.19112284419887303347e-2 + (0.14491572616545004930e-4 + (0.10046682186333613697e-6 + (0.63221272959791000515e-9 + (0.35736693975589130818e-11 + 0.17862931591111111111e-13 * t) * t) * t) * t) * t) * t; +} +case 41: { +T t = 2*y100 - 83; +return 0.98554641648004456555e-1 + (0.19704208544725622126e-2 + (0.15109836875625443935e-4 + (0.10567036667675984067e-6 + (0.66904168640019354565e-9 + (0.37946171850824333014e-11 + 0.18971959040000000000e-13 * t) * t) * t) * t) * t) * t; +} +case 42: { +T t = 2*y100 - 85; +return 0.10255677889470089531e0 + (0.20321499629472857418e-2 + (0.15760224242962179564e-4 + (0.11117756071353507391e-6 + (0.70814785110097658502e-9 + (0.40292553276632563925e-11 + 0.20145143075555555556e-13 * t) * t) * t) * t) * t) * t; +} +case 43: { +T t = 2*y100 - 87; +return 0.10668502059865093318e0 + (0.20965479776148731610e-2 + (0.16444612377624983565e-4 + (0.11700717962026152749e-6 + (0.74967203250938418991e-9 + (0.42783716186085922176e-11 + 0.21385479360000000000e-13 * t) * t) * t) * t) * t) * t; +} +case 44: { +T t = 2*y100 - 89; +return 0.11094484319386444474e0 + (0.21637548491908170841e-2 + (0.17164995035719657111e-4 + (0.12317915750735938089e-6 + (0.79376309831499633734e-9 + (0.45427901763106353914e-11 + 0.22696025653333333333e-13 * t) * t) * t) * t) * t) * t; +} +case 45: { +T t = 2*y100 - 91; +return 0.11534201115268804714e0 + (0.22339187474546420375e-2 + (0.17923489217504226813e-4 + (0.12971465288245997681e-6 + (0.84057834180389073587e-9 + (0.48233721206418027227e-11 + 0.24079890062222222222e-13 * t) * t) * t) * t) * t) * t; +} +case 46: { +T t = 2*y100 - 93; +return 0.11988259392684094740e0 + (0.23071965691918689601e-2 + (0.18722342718958935446e-4 + (0.13663611754337957520e-6 + (0.89028385488493287005e-9 + (0.51210161569225846701e-11 + 0.25540227111111111111e-13 * t) * t) * t) * t) * t) * t; +} +case 47: { +T t = 2*y100 - 95; +return 0.12457298393509812907e0 + (0.23837544771809575380e-2 + (0.19563942105711612475e-4 + (0.14396736847739470782e-6 + (0.94305490646459247016e-9 + (0.54366590583134218096e-11 + 0.27080225920000000000e-13 * t) * t) * t) * t) * t) * t; +} +case 48: { +T t = 2*y100 - 97; +return 0.12941991566142438816e0 + (0.24637684719508859484e-2 + (0.20450821127475879816e-4 + (0.15173366280523906622e-6 + (0.99907632506389027739e-9 + (0.57712760311351625221e-11 + 0.28703099555555555556e-13 * t) * t) * t) * t) * t) * t; +} +case 49: { +T t = 2*y100 - 99; +return 0.13443048593088696613e0 + (0.25474249981080823877e-2 + (0.21385669591362915223e-4 + (0.15996177579900443030e-6 + (0.10585428844575134013e-8 + (0.61258809536787882989e-11 + 0.30412080142222222222e-13 * t) * t) * t) * t) * t) * t; +} +case 50: { +T t = 2*y100 - 101; +return 0.13961217543434561353e0 + (0.26349215871051761416e-2 + (0.22371342712572567744e-4 + (0.16868008199296822247e-6 + (0.11216596910444996246e-8 + (0.65015264753090890662e-11 + 0.32210394506666666666e-13 * t) * t) * t) * t) * t) * t; +} +case 51: { +T t = 2*y100 - 103; +return 0.14497287157673800690e0 + (0.27264675383982439814e-2 + (0.23410870961050950197e-4 + (0.17791863939526376477e-6 + (0.11886425714330958106e-8 + (0.68993039665054288034e-11 + 0.34101266222222222221e-13 * t) * t) * t) * t) * t) * t; +} +case 52: { +T t = 2*y100 - 105; +return 0.15052089272774618151e0 + (0.28222846410136238008e-2 + (0.24507470422713397006e-4 + (0.18770927679626136909e-6 + (0.12597184587583370712e-8 + (0.73203433049229821618e-11 + 0.36087889048888888890e-13 * t) * t) * t) * t) * t) * t; +} +case 53: { +T t = 2*y100 - 107; +return 0.15626501395774612325e0 + (0.29226079376196624949e-2 + (0.25664553693768450545e-4 + (0.19808568415654461964e-6 + (0.13351257759815557897e-8 + (0.77658124891046760667e-11 + 0.38173420035555555555e-13 * t) * t) * t) * t) * t) * t; +} +case 54: { +T t = 2*y100 - 109; +return 0.16221449434620737567e0 + (0.30276865332726475672e-2 + (0.26885741326534564336e-4 + (0.20908350604346384143e-6 + (0.14151148144240728728e-8 + (0.82369170665974313027e-11 + 0.40360957457777777779e-13 * t) * t) * t) * t) * t) * t; +} +case 55: { +T t = 2*y100 - 111; +return 0.16837910595412130659e0 + (0.31377844510793082301e-2 + (0.28174873844911175026e-4 + (0.22074043807045782387e-6 + (0.14999481055996090039e-8 + (0.87348993661930809254e-11 + 0.42653528977777777779e-13 * t) * t) * t) * t) * t) * t; +} +case 56: { +T t = 2*y100 - 113; +return 0.17476916455659369953e0 + (0.32531815370903068316e-2 + (0.29536024347344364074e-4 + (0.23309632627767074202e-6 + (0.15899007843582444846e-8 + (0.92610375235427359475e-11 + 0.45054073102222222221e-13 * t) * t) * t) * t) * t) * t; +} +case 57: { +T t = 2*y100 - 115; +return 0.18139556223643701364e0 + (0.33741744168096996041e-2 + (0.30973511714709500836e-4 + (0.24619326937592290996e-6 + (0.16852609412267750744e-8 + (0.98166442942854895573e-11 + 0.47565418097777777779e-13 * t) * t) * t) * t) * t) * t; +} +case 58: { +T t = 2*y100 - 117; +return 0.18826980194443664549e0 + (0.35010775057740317997e-2 + (0.32491914440014267480e-4 + (0.26007572375886319028e-6 + (0.17863299617388376116e-8 + (0.10403065638343878679e-10 + 0.50190265831111111110e-13 * t) * t) * t) * t) * t) * t; +} +case 59: { +T t = 2*y100 - 119; +return 0.19540403413693967350e0 + (0.36342240767211326315e-2 + (0.34096085096200907289e-4 + (0.27479061117017637474e-6 + (0.18934228504790032826e-8 + (0.11021679075323598664e-10 + 0.52931171733333333334e-13 * t) * t) * t) * t) * t) * t; +} +case 60: { +T t = 2*y100 - 121; +return 0.20281109560651886959e0 + (0.37739673859323597060e-2 + (0.35791165457592409054e-4 + (0.29038742889416172404e-6 + (0.20068685374849001770e-8 + (0.11673891799578381999e-10 + 0.55790523093333333334e-13 * t) * t) * t) * t) * t) * t; +} +case 61: { +T t = 2*y100 - 123; +return 0.21050455062669334978e0 + (0.39206818613925652425e-2 + (0.37582602289680101704e-4 + (0.30691836231886877385e-6 + (0.21270101645763677824e-8 + (0.12361138551062899455e-10 + 0.58770520160000000000e-13 * t) * t) * t) * t) * t) * t; +} +case 62: { +T t = 2*y100 - 125; +return 0.21849873453703332479e0 + (0.40747643554689586041e-2 + (0.39476163820986711501e-4 + (0.32443839970139918836e-6 + (0.22542053491518680200e-8 + (0.13084879235290858490e-10 + 0.61873153262222222221e-13 * t) * t) * t) * t) * t) * t; +} +case 63: { +T t = 2*y100 - 127; +return 0.22680879990043229327e0 + (0.42366354648628516935e-2 + (0.41477956909656896779e-4 + (0.34300544894502810002e-6 + (0.23888264229264067658e-8 + (0.13846596292818514601e-10 + 0.65100183751111111110e-13 * t) * t) * t) * t) * t) * t; +} +case 64: { +T t = 2*y100 - 129; +return 0.23545076536988703937e0 + (0.44067409206365170888e-2 + (0.43594444916224700881e-4 + (0.36268045617760415178e-6 + (0.25312606430853202748e-8 + (0.14647791812837903061e-10 + 0.68453122631111111110e-13 * t) * t) * t) * t) * t) * t; +} +case 65: { +T t = 2*y100 - 131; +return 0.24444156740777432838e0 + (0.45855530511605787178e-2 + (0.45832466292683085475e-4 + (0.38352752590033030472e-6 + (0.26819103733055603460e-8 + (0.15489984390884756993e-10 + 0.71933206364444444445e-13 * t) * t) * t) * t) * t) * t; +} +case 66: { +T t = 2*y100 - 133; +return 0.25379911500634264643e0 + (0.47735723208650032167e-2 + (0.48199253896534185372e-4 + (0.40561404245564732314e-6 + (0.28411932320871165585e-8 + (0.16374705736458320149e-10 + 0.75541379822222222221e-13 * t) * t) * t) * t) * t) * t; +} +case 67: { +T t = 2*y100 - 135; +return 0.26354234756393613032e0 + (0.49713289477083781266e-2 + (0.50702455036930367504e-4 + (0.42901079254268185722e-6 + (0.30095422058900481753e-8 + (0.17303497025347342498e-10 + 0.79278273368888888890e-13 * t) * t) * t) * t) * t) * t; +} +case 68: { +T t = 2*y100 - 137; +return 0.27369129607732343398e0 + (0.51793846023052643767e-2 + (0.53350152258326602629e-4 + (0.45379208848865015485e-6 + (0.31874057245814381257e-8 + (0.18277905010245111046e-10 + 0.83144182364444444445e-13 * t) * t) * t) * t) * t) * t; +} +case 69: { +T t = 2*y100 - 139; +return 0.28426714781640316172e0 + (0.53983341916695141966e-2 + (0.56150884865255810638e-4 + (0.48003589196494734238e-6 + (0.33752476967570796349e-8 + (0.19299477888083469086e-10 + 0.87139049137777777779e-13 * t) * t) * t) * t) * t) * t; +} +case 70: { +T t = 2*y100 - 141; +return 0.29529231465348519920e0 + (0.56288077305420795663e-2 + (0.59113671189913307427e-4 + (0.50782393781744840482e-6 + (0.35735475025851713168e-8 + (0.20369760937017070382e-10 + 0.91262442613333333334e-13 * t) * t) * t) * t) * t) * t; +} +case 71: { +T t = 2*y100 - 143; +return 0.30679050522528838613e0 + (0.58714723032745403331e-2 + (0.62248031602197686791e-4 + (0.53724185766200945789e-6 + (0.37827999418960232678e-8 + (0.21490291930444538307e-10 + 0.95513539182222222221e-13 * t) * t) * t) * t) * t) * t; +} +case 72: { +T t = 2*y100 - 145; +return 0.31878680111173319425e0 + (0.61270341192339103514e-2 + (0.65564012259707640976e-4 + (0.56837930287837738996e-6 + (0.40035151353392378882e-8 + (0.22662596341239294792e-10 + 0.99891109760000000000e-13 * t) * t) * t) * t) * t) * t; +} +case 73: { +T t = 2*y100 - 147; +return 0.33130773722152622027e0 + (0.63962406646798080903e-2 + (0.69072209592942396666e-4 + (0.60133006661885941812e-6 + (0.42362183765883466691e-8 + (0.23888182347073698382e-10 + 0.10439349811555555556e-12 * t) * t) * t) * t) * t) * t; +} +case 74: { +T t = 2*y100 - 149; +return 0.34438138658041336523e0 + (0.66798829540414007258e-2 + (0.72783795518603561144e-4 + (0.63619220443228800680e-6 + (0.44814499336514453364e-8 + (0.25168535651285475274e-10 + 0.10901861383111111111e-12 * t) * t) * t) * t) * t) * t; +} +case 75: { +T t = 2*y100 - 151; +return 0.35803744972380175583e0 + (0.69787978834882685031e-2 + (0.76710543371454822497e-4 + (0.67306815308917386747e-6 + (0.47397647975845228205e-8 + (0.26505114141143050509e-10 + 0.11376390933333333333e-12 * t) * t) * t) * t) * t) * t; +} +case 76: { +T t = 2*y100 - 153; +return 0.37230734890119724188e0 + (0.72938706896461381003e-2 + (0.80864854542670714092e-4 + (0.71206484718062688779e-6 + (0.50117323769745883805e-8 + (0.27899342394100074165e-10 + 0.11862637614222222222e-12 * t) * t) * t) * t) * t) * t; +} +case 77: { +T t = 2*y100 - 155; +return 0.38722432730555448223e0 + (0.76260375162549802745e-2 + (0.85259785810004603848e-4 + (0.75329383305171327677e-6 + (0.52979361368388119355e-8 + (0.29352606054164086709e-10 + 0.12360253370666666667e-12 * t) * t) * t) * t) * t) * t; +} +case 78: { +T t = 2*y100 - 157; +return 0.40282355354616940667e0 + (0.79762880915029728079e-2 + (0.89909077342438246452e-4 + (0.79687137961956194579e-6 + (0.55989731807360403195e-8 + (0.30866246101464869050e-10 + 0.12868841946666666667e-12 * t) * t) * t) * t) * t) * t; +} +case 79: { +T t = 2*y100 - 159; +return 0.41914223158913787649e0 + (0.83456685186950463538e-2 + (0.94827181359250161335e-4 + (0.84291858561783141014e-6 + (0.59154537751083485684e-8 + (0.32441553034347469291e-10 + 0.13387957943111111111e-12 * t) * t) * t) * t) * t) * t; +} +case 80: { +T t = 2*y100 - 161; +return 0.43621971639463786896e0 + (0.87352841828289495773e-2 + (0.10002929142066799966e-3 + (0.89156148280219880024e-6 + (0.62480008150788597147e-8 + (0.34079760983458878910e-10 + 0.13917107176888888889e-12 * t) * t) * t) * t) * t) * t; +} +case 81: { +T t = 2*y100 - 163; +return 0.45409763548534330981e0 + (0.91463027755548240654e-2 + (0.10553137232446167258e-3 + (0.94293113464638623798e-6 + (0.65972492312219959885e-8 + (0.35782041795476563662e-10 + 0.14455745872000000000e-12 * t) * t) * t) * t) * t) * t; +} +case 82: { +T t = 2*y100 - 165; +return 0.47282001668512331468e0 + (0.95799574408860463394e-2 + (0.11135019058000067469e-3 + (0.99716373005509038080e-6 + (0.69638453369956970347e-8 + (0.37549499088161345850e-10 + 0.15003280712888888889e-12 * t) * t) * t) * t) * t) * t; +} +case 83: { +T t = 2*y100 - 167; +return 0.49243342227179841649e0 + (0.10037550043909497071e-1 + (0.11750334542845234952e-3 + (0.10544006716188967172e-5 + (0.73484461168242224872e-8 + (0.39383162326435752965e-10 + 0.15559069118222222222e-12 * t) * t) * t) * t) * t) * t; +} +case 84: { +T t = 2*y100 - 169; +return 0.51298708979209258326e0 + (0.10520454564612427224e-1 + (0.12400930037494996655e-3 + (0.11147886579371265246e-5 + (0.77517184550568711454e-8 + (0.41283980931872622611e-10 + 0.16122419680000000000e-12 * t) * t) * t) * t) * t) * t; +} +case 85: { +T t = 2*y100 - 171; +return 0.53453307979101369843e0 + (0.11030120618800726938e-1 + (0.13088741519572269581e-3 + (0.11784797595374515432e-5 + (0.81743383063044825400e-8 + (0.43252818449517081051e-10 + 0.16692592640000000000e-12 * t) * t) * t) * t) * t) * t; +} +case 86: { +T t = 2*y100 - 173; +return 0.55712643071169299478e0 + (0.11568077107929735233e-1 + (0.13815797838036651289e-3 + (0.12456314879260904558e-5 + (0.86169898078969313597e-8 + (0.45290446811539652525e-10 + 0.17268801084444444444e-12 * t) * t) * t) * t) * t) * t; +} +case 87: { +T t = 2*y100 - 175; +return 0.58082532122519320968e0 + (0.12135935999503877077e-1 + (0.14584223996665838559e-3 + (0.13164068573095710742e-5 + (0.90803643355106020163e-8 + (0.47397540713124619155e-10 + 0.17850211608888888889e-12 * t) * t) * t) * t) * t) * t; +} +case 88: { +T t = 2*y100 - 177; +return 0.60569124025293375554e0 + (0.12735396239525550361e-1 + (0.15396244472258863344e-3 + (0.13909744385382818253e-5 + (0.95651595032306228245e-8 + (0.49574672127669041550e-10 + 0.18435945564444444444e-12 * t) * t) * t) * t) * t) * t; +} +case 89: { +T t = 2*y100 - 179; +return 0.63178916494715716894e0 + (0.13368247798287030927e-1 + (0.16254186562762076141e-3 + (0.14695084048334056083e-5 + (0.10072078109604152350e-7 + (0.51822304995680707483e-10 + 0.19025081422222222222e-12 * t) * t) * t) * t) * t) * t; +} +case 90: { +T t = 2*y100 - 181; +return 0.65918774689725319200e0 + (0.14036375850601992063e-1 + (0.17160483760259706354e-3 + (0.15521885688723188371e-5 + (0.10601827031535280590e-7 + (0.54140790105837520499e-10 + 0.19616655146666666667e-12 * t) * t) * t) * t) * t) * t; +} +case 91: { +T t = 2*y100 - 183; +return 0.68795950683174433822e0 + (0.14741765091365869084e-1 + (0.18117679143520433835e-3 + (0.16392004108230585213e-5 + (0.11155116068018043001e-7 + (0.56530360194925690374e-10 + 0.20209663662222222222e-12 * t) * t) * t) * t) * t) * t; +} +case 92: { +T t = 2*y100 - 185; +return 0.71818103808729967036e0 + (0.15486504187117112279e-1 + (0.19128428784550923217e-3 + (0.17307350969359975848e-5 + (0.11732656736113607751e-7 + (0.58991125287563833603e-10 + 0.20803065333333333333e-12 * t) * t) * t) * t) * t) * t; +} +case 93: { +T t = 2*y100 - 187; +return 0.74993321911726254661e0 + (0.16272790364044783382e-1 + (0.20195505163377912645e-3 + (0.18269894883203346953e-5 + (0.12335161021630225535e-7 + (0.61523068312169087227e-10 + 0.21395783431111111111e-12 * t) * t) * t) * t) * t) * t; +} +case 94: { +T t = 2*y100 - 189; +return 0.78330143531283492729e0 + (0.17102934132652429240e-1 + (0.21321800585063327041e-3 + (0.19281661395543913713e-5 + (0.12963340087354341574e-7 + (0.64126040998066348872e-10 + 0.21986708942222222222e-12 * t) * t) * t) * t) * t) * t; +} +case 95: { +T t = 2*y100 - 191; +return 0.81837581041023811832e0 + (0.17979364149044223802e-1 + (0.22510330592753129006e-3 + (0.20344732868018175389e-5 + (0.13617902941839949718e-7 + (0.66799760083972474642e-10 + 0.22574701262222222222e-12 * t) * t) * t) * t) * t) * t; +} +case 96: { +T t = 2*y100 - 193; +return 0.85525144775685126237e0 + (0.18904632212547561026e-1 + (0.23764237370371255638e-3 + (0.21461248251306387979e-5 + (0.14299555071870523786e-7 + (0.69543803864694171934e-10 + 0.23158593688888888889e-12 * t) * t) * t) * t) * t) * t; +} +case 97: { +T t = 2*y100 - 195; +return 0.89402868170849933734e0 + (0.19881418399127202569e-1 + (0.25086793128395995798e-3 + (0.22633402747585233180e-5 + (0.15008997042116532283e-7 + (0.72357609075043941261e-10 + 0.23737194737777777778e-12 * t) * t) * t) * t) * t) * t; +} +case 98: { +T t = 2*y100 - 197; +return 0.93481333942870796363e0 + (0.20912536329780368893e-1 + (0.26481403465998477969e-3 + (0.23863447359754921676e-5 + (0.15746923065472184451e-7 + (0.75240468141720143653e-10 + 0.24309291271111111111e-12 * t) * t) * t) * t) * t) * t; +} +case 99: { +T t = 2*y100 - 199; +return 0.97771701335885035464e0 + (0.22000938572830479551e-1 + (0.27951610702682383001e-3 + (0.25153688325245314530e-5 + (0.16514019547822821453e-7 + (0.78191526829368231251e-10 + 0.24873652355555555556e-12 * t) * t) * t) * t) * t) * t; +} + } + // we only get here if y = 1, i.e. |x| < 4*eps, in which case + // erfcx is within 1e-15 of 1.. + return 1.0; +} + +template +C10_HOST_DEVICE inline typename std::enable_if_t, T> +calc_erfcx(T x) +{ + if (at::_isnan(x)) { + return x; + } + + if (x >= 0) { + if (x > 50) { // continued-fraction expansion is faster + const T ispi = 0.56418958354775628694807945156; // 1 / sqrt(pi) + if (x > 5e7) { // 1-term expansion, important to avoid overflow + return ispi / x; + } + /* 5-term expansion (rely on compiler for CSE), simplified from: + ispi / (x+0.5/(x+1/(x+1.5/(x+2/x)))) */ + return ispi*((x*x) * (x*x+4.5) + 2) / (x * ((x*x) * (x*x+5) + 3.75)); + } + return erfcx_y100(400/(4+x)); + } + else { + if (x < -26.7) { + return std::numeric_limits::infinity(); + } + else if (x < -6.1) { + return 2*exp(x*x); + } + else { + return 2*exp(x*x) - erfcx_y100(400/(4-x)); + } + } +} + +/* + * Logarithm of Gaussian cumulative distribution function. + + * This implementation of log_ndtr and its helper functions + * follow SciPy's implementation + * See NOTICE for the licenses. + */ +template +inline C10_HOST_DEVICE T calc_log_ndtr(T x) { + T t = x * c10::frac_sqrt_2; + if (x < T{-1.0}) { + return std::log(calc_erfcx(-t) / 2) - t * t; + } else { + return std::log1p(-std::erfc(t) / 2); + } +} + +template +inline C10_HOST_DEVICE T airy_ai_forward(T x) { + static const T AN[] = { + +3.46538101525629032477e-01, + +1.20075952739645805542e+01, + +7.62796053615234516538e+01, + +1.68089224934630576269e+02, + +1.59756391350164413639e+02, + +7.05360906840444183113e+01, + +1.40264691163389668864e+01, + +9.99999999999999995305e-01, + }; + + static const T AD[] = { + +5.67594532638770212846e-01, + +1.47562562584847203173e+01, + +8.45138970141474626562e+01, + +1.77318088145400459522e+02, + +1.64234692871529701831e+02, + +7.14778400825575695274e+01, + +1.40959135607834029598e+01, + +1.00000000000000000470e+00, + }; + + static const T AFN[] = { + -1.31696323418331795333e-01, + -6.26456544431912369773e-01, + -6.93158036036933542233e-01, + -2.79779981545119124951e-01, + -4.91900132609500318020e-02, + -4.06265923594885404393e-03, + -1.59276496239262096340e-04, + -2.77649108155232920844e-06, + -1.67787698489114633780e-08, + }; + + static const T AFD[] = { + +1.33560420706553243746e+01, + +3.26825032795224613948e+01, + +2.67367040941499554804e+01, + +9.18707402907259625840e+00, + +1.47529146771666414581e+00, + +1.15687173795188044134e-01, + +4.40291641615211203805e-03, + +7.54720348287414296618e-05, + +4.51850092970580378464e-07, + }; + + static const T AGN[] = { + +1.97339932091685679179e-02, + +3.91103029615688277255e-01, + +1.06579897599595591108e+00, + +9.39169229816650230044e-01, + +3.51465656105547619242e-01, + +6.33888919628925490927e-02, + +5.85804113048388458567e-03, + +2.82851600836737019778e-04, + +6.98793669997260967291e-06, + +8.11789239554389293311e-08, + +3.41551784765923618484e-10, + }; + + static const T AGD[] = { + +9.30892908077441974853e+00, + +1.98352928718312140417e+01, + +1.55646628932864612953e+01, + +5.47686069422975497931e+00, + +9.54293611618961883998e-01, + +8.64580826352392193095e-02, + +4.12656523824222607191e-03, + +1.01259085116509135510e-04, + +1.17166733214413521882e-06, + +4.91834570062930015649e-09, + }; + + int domain_flag = 0; + + T ai; + + if (std::isinf(x)) { + return std::numeric_limits::quiet_NaN(); + } + + if (x > T(103.892)) { + return T(0.0); + } + + T f; + T g; + T k; + + if (x < T(-2.09)) { + T z = T(1.0) / (T(-2.0) * x * std::sqrt(-x) / T(3.0)); + + T afn = 0.0; + + for (uint8_t index = 0; index <= 8; index++) { + afn = afn * (z * z) + AFN[index]; + } + + T afd = 0.0; + + for (uint8_t index = 0; index <= 8; index++) { + afd = afd * (z * z) + AFD[index]; + } + + T agn = 0.0; + + for (uint8_t index = 0; index <= 10 + 0; index++) { + agn = agn * (z * z) + AGN[index]; + } + + T agd = 0.0; + + for (uint8_t index = 0; index <= 10 - 1; index++) { + agd = agd * (z * z) + AGD[index]; + } + + T t = T(-2.0) * x * std::sqrt(-x) / T(3.0) + T(0.25) * c10::pi; + + return T(5.64189583547756286948e-01) / std::sqrt(std::sqrt(-x)) * (std::sin(t) * (T(1.0) + z * z * afn / afd) - std::cos(t) * (z * agn / agd)); + } + + if (x >= T(2.09)) { + domain_flag = 5; + + T zeta = T(2.0) * x * std::sqrt(x) / T(3.0); + + T an = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + an = an * (T(1.0) / zeta) + AN[index]; + } + + T ad = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + ad = ad * (T(1.0) / zeta) + AD[index]; + } + + ai = T(5.64189583547756286948e-01) * (an / ad) / (T(2.0) * std::sqrt(std::sqrt(x)) * std::exp(zeta)); + + if (x > T(8.3203353)) { + return ai; + } + } + + f = 1.0; + g = x; + k = 1.0; + + T m = 1.0; + T n = x; + T t = 1.0; + T z = x * x * x; + + while (t > std::numeric_limits::epsilon()) { + m *= z; + k += T(1.0); + m /= k; + n *= z; + k += T(1.0); + n /= k; + m /= k; + f += m; + k += T(1.0); + n /= k; + g += n; + + t = std::abs(m / f); + } + + if ((domain_flag & 1) == 0) { + return T(0.355028053887817239260) * f - T(0.258819403792806798405) * g; + } + + return ai; +} // T airy_ai(T x) + +template +inline C10_HOST_DEVICE T bessel_j0_forward(T x) { + static const T PP[] = { + +7.96936729297347051624e-04, + +8.28352392107440799803e-02, + +1.23953371646414299388e+00, + +5.44725003058768775090e+00, + +8.74716500199817011941e+00, + +5.30324038235394892183e+00, + +9.99999999999999997821e-01, + }; + + static const T PQ[] = { + +9.24408810558863637013e-04, + +8.56288474354474431428e-02, + +1.25352743901058953537e+00, + +5.47097740330417105182e+00, + +8.76190883237069594232e+00, + +5.30605288235394617618e+00, + +1.00000000000000000218e+00, + }; + + static const T QP[] = { + -1.13663838898469149931e-02, + -1.28252718670509318512e+00, + -1.95539544257735972385e+01, + -9.32060152123768231369e+01, + -1.77681167980488050595e+02, + -1.47077505154951170175e+02, + -5.14105326766599330220e+01, + -6.05014350600728481186e+00, + }; + + static const T QQ[] = { + +6.43178256118178023184e+01, + +8.56430025976980587198e+02, + +3.88240183605401609683e+03, + +7.24046774195652478189e+03, + +5.93072701187316984827e+03, + +2.06209331660327847417e+03, + +2.42005740240291393179e+02, + }; + + static const T RP[] = { + -4.79443220978201773821e+09, + +1.95617491946556577543e+12, + -2.49248344360967716204e+14, + +9.70862251047306323952e+15, + }; + + static const T RQ[] = { + +4.99563147152651017219e+02, + +1.73785401676374683123e+05, + +4.84409658339962045305e+07, + +1.11855537045356834862e+10, + +2.11277520115489217587e+12, + +3.10518229857422583814e+14, + +3.18121955943204943306e+16, + +1.71086294081043136091e+18, + }; + + if (x < T(0)) { + x = -x; + } + + if (x <= T(5.0)) { + if (x < T(0.00001)) { + return T(1.0) - x * x / T(4.0); + } + + T rp = 0.0; + + for (uint8_t index = 0; index <= 3; index++) { + rp = rp * (x * x) + RP[index]; + } + + T rq = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + rq = rq * (x * x) + RQ[index]; + } + + return (x * x - T(5.78318596294678452118e+00)) * (x * x - T(3.04712623436620863991e+01)) * rp / rq; + } + + T pp = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pp = pp * (T(25.0) / (x * x)) + PP[index]; + } + + T pq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pq = pq * (T(25.0) / (x * x)) + PQ[index]; + } + + T qp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + qp = qp * (T(25.0) / (x * x)) + QP[index]; + } + + T qq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + qq = qq * (T(25.0) / (x * x)) + QQ[index]; + } + + return (pp / pq * std::cos(x - T(0.785398163397448309615660845819875721)) - T(5.0) / x * (qp / qq) * std::sin(x - T(0.785398163397448309615660845819875721))) * T(0.797884560802865355879892119868763737) / std::sqrt(x); +} // bessel_j0_forward(T x) + +template +inline C10_HOST_DEVICE T bessel_j1_forward(T x) { + static const T PP[] = { + +7.62125616208173112003e-04, + +7.31397056940917570436e-02, + +1.12719608129684925192e+00, + +5.11207951146807644818e+00, + +8.42404590141772420927e+00, + +5.21451598682361504063e+00, + +1.00000000000000000254e+00, + }; + + static const T PQ[] = { + +5.71323128072548699714e-04, + +6.88455908754495404082e-02, + +1.10514232634061696926e+00, + +5.07386386128601488557e+00, + +8.39985554327604159757e+00, + +5.20982848682361821619e+00, + +9.99999999999999997461e-01, + }; + + static const T QP[] = { + +5.10862594750176621635e-02, + +4.98213872951233449420e+00, + +7.58238284132545283818e+01, + +3.66779609360150777800e+02, + +7.10856304998926107277e+02, + +5.97489612400613639965e+02, + +2.11688757100572135698e+02, + +2.52070205858023719784e+01, + }; + + static const T QQ[] = { + +7.42373277035675149943e+01, + +1.05644886038262816351e+03, + +4.98641058337653607651e+03, + +9.56231892404756170795e+03, + +7.99704160447350683650e+03, + +2.82619278517639096600e+03, + +3.36093607810698293419e+02, + }; + + static const T RP[] = { + -8.99971225705559398224e+08, + +4.52228297998194034323e+11, + -7.27494245221818276015e+13, + +3.68295732863852883286e+15, + }; + + static const T RQ[] = { + +6.20836478118054335476e+02, + +2.56987256757748830383e+05, + +8.35146791431949253037e+07, + +2.21511595479792499675e+10, + +4.74914122079991414898e+12, + +7.84369607876235854894e+14, + +8.95222336184627338078e+16, + +5.32278620332680085395e+18, + }; + + if (x < T(0.0)) { + return -bessel_j1_forward(-x); + } + + if (x <= T(5.0)) { + T rp = 0.0; + + for (uint8_t index = 0; index <= 3; index++) { + rp = rp * (x * x) + RP[index]; + } + + T rq = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + rq = rq * (x * x) + RQ[index]; + } + + return rp / rq * x * (x * x - T(1.46819706421238932572e+01)) * (x * x - T(4.92184563216946036703e+01)); + } + + T pp = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pp = pp * (T(5.0) / x * (T(5.0) / x)) + PP[index]; + } + + T pq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pq = pq * (T(5.0) / x * (T(5.0) / x)) + PQ[index]; + } + + T qp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + qp = qp * (T(5.0) / x * (T(5.0) / x)) + QP[index]; + } + + T qq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + qq = qq * (T(5.0) / x * (T(5.0) / x)) + QQ[index]; + } + + return (pp / pq * std::cos(x - T(2.356194490192344928846982537459627163)) - T(5.0) / x * (qp / qq) * std::sin(x - T(2.356194490192344928846982537459627163))) * T(0.797884560802865355879892119868763737) / std::sqrt(x); +} // bessel_j1_forward(T x) + +template +inline C10_HOST_DEVICE T bessel_y0_forward(T x) { + static const T PP[] = { + +7.96936729297347051624e-04, + +8.28352392107440799803e-02, + +1.23953371646414299388e+00, + +5.44725003058768775090e+00, + +8.74716500199817011941e+00, + +5.30324038235394892183e+00, + +9.99999999999999997821e-01, + }; + + static const T PQ[] = { + +9.24408810558863637013e-04, + +8.56288474354474431428e-02, + +1.25352743901058953537e+00, + +5.47097740330417105182e+00, + +8.76190883237069594232e+00, + +5.30605288235394617618e+00, + +1.00000000000000000218e+00, + }; + + static const T QP[] = { + -1.13663838898469149931e-02, + -1.28252718670509318512e+00, + -1.95539544257735972385e+01, + -9.32060152123768231369e+01, + -1.77681167980488050595e+02, + -1.47077505154951170175e+02, + -5.14105326766599330220e+01, + -6.05014350600728481186e+00, + }; + + static const T QQ[] = { + +6.43178256118178023184e+01, + +8.56430025976980587198e+02, + +3.88240183605401609683e+03, + +7.24046774195652478189e+03, + +5.93072701187316984827e+03, + +2.06209331660327847417e+03, + +2.42005740240291393179e+02, + }; + + static const T YP[] = { + +1.55924367855235737965e+04, + -1.46639295903971606143e+07, + +5.43526477051876500413e+09, + -9.82136065717911466409e+11, + +8.75906394395366999549e+13, + -3.46628303384729719441e+15, + +4.42733268572569800351e+16, + -1.84950800436986690637e+16, + }; + + static const T YQ[] = { + +1.04128353664259848412e+03, + +6.26107330137134956842e+05, + +2.68919633393814121987e+08, + +8.64002487103935000337e+10, + +2.02979612750105546709e+13, + +3.17157752842975028269e+15, + +2.50596256172653059228e+17, + }; + + if (x <= T(5.0)) { + if (x == T(0.0)) { + return -std::numeric_limits::infinity(); + } + + if (x < T(0.0)) { + return std::numeric_limits::quiet_NaN(); + } + + T yp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + yp = yp * (x * x) + YP[index]; + } + + T yq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + yq = yq * (x * x) + YQ[index]; + } + + return yp / yq + (T(0.636619772367581343075535053490057448) * std::log(x) * bessel_j0_forward(x)); + } + + T pp = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pp = pp * (T(25.0) / (x * x)) + PP[index]; + } + + T pq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pq = pq * (T(25.0) / (x * x)) + PQ[index]; + } + + T qp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + qp = qp * (T(25.0) / (x * x)) + QP[index]; + } + + T qq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + qq = qq * (T(25.0) / (x * x)) + QQ[index]; + } + + return (pp / pq * std::sin(x - T(0.785398163397448309615660845819875721)) + T(5.0) / x * (qp / qq) * std::cos(x - T(0.785398163397448309615660845819875721))) * T(0.797884560802865355879892119868763737) / std::sqrt(x); +} // bessel_y0_forward(T x) + +template +inline C10_HOST_DEVICE T bessel_y1_forward(T x) { + static const T PP[] = { + +7.62125616208173112003e-04, + +7.31397056940917570436e-02, + +1.12719608129684925192e+00, + +5.11207951146807644818e+00, + +8.42404590141772420927e+00, + +5.21451598682361504063e+00, + +1.00000000000000000254e+00, + }; + + static const T PQ[] = { + +5.71323128072548699714e-04, + +6.88455908754495404082e-02, + +1.10514232634061696926e+00, + +5.07386386128601488557e+00, + +8.39985554327604159757e+00, + +5.20982848682361821619e+00, + +9.99999999999999997461e-01, + }; + + static const T QP[] = { + +5.10862594750176621635e-02, + +4.98213872951233449420e+00, + +7.58238284132545283818e+01, + +3.66779609360150777800e+02, + +7.10856304998926107277e+02, + +5.97489612400613639965e+02, + +2.11688757100572135698e+02, + +2.52070205858023719784e+01, + }; + + static const T QQ[] = { + +7.42373277035675149943e+01, + +1.05644886038262816351e+03, + +4.98641058337653607651e+03, + +9.56231892404756170795e+03, + +7.99704160447350683650e+03, + +2.82619278517639096600e+03, + +3.36093607810698293419e+02, + }; + + static const T YP[] = { + +1.26320474790178026440e+09, + -6.47355876379160291031e+11, + +1.14509511541823727583e+14, + -8.12770255501325109621e+15, + +2.02439475713594898196e+17, + -7.78877196265950026825e+17, + }; + + static const T YQ[] = { + +5.94301592346128195359e+02, + +2.35564092943068577943e+05, + +7.34811944459721705660e+07, + +1.87601316108706159478e+10, + +3.88231277496238566008e+12, + +6.20557727146953693363e+14, + +6.87141087355300489866e+16, + +3.97270608116560655612e+18, + }; + + if (x <= T(5.0)) { + if (x == T(0.0)) { + return -std::numeric_limits::infinity(); + } + + if (x <= T(0.0)) { + return std::numeric_limits::quiet_NaN(); + } + + T yp = 0.0; + + for (uint8_t index = 0; index <= 5; index++) { + yp = yp * (x * x) + YP[index]; + } + + T yq = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + yq = yq * (x * x) + YQ[index]; + } + + return x * (yp / yq) + (T(0.636619772367581343075535053490057448) * (bessel_j1_forward(x) * std::log(x) - T(1.0) / x)); + } + + T pp = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pp = pp * (T(5.0) / x * (T(5.0) / x)) + PP[index]; + } + + T pq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pq = pq * (T(5.0) / x * (T(5.0) / x)) + PQ[index]; + } + + T qp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + qp = qp * (T(5.0) / x * (T(5.0) / x)) + QP[index]; + } + + T qq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + qq = qq * (T(5.0) / x * (T(5.0) / x)) + QQ[index]; + } + + return (pp / pq * std::sin(x - T(2.356194490192344928846982537459627163)) + T(5.0) / x * (qp / qq) * std::cos(x - T(2.356194490192344928846982537459627163))) * T(0.797884560802865355879892119868763737) / std::sqrt(x); +} // bessel_y1_forward(T x) + +template +inline C10_HOST_DEVICE T chebyshev_polynomial_t_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (std::abs(x) == T(1.0)) { + if (x > T(0.0) || n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if ((n > 6) && (std::abs(x) < T(1.0))) { + return std::cos(n * std::acos(x)); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x; + } + + T p = T(1.0); + T q = x; + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x) * q - p; + p = q; + q = r; + } + + return r; +} // chebyshev_polynomial_t_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T chebyshev_polynomial_t_forward(T x, T n) { + return chebyshev_polynomial_t_forward(x, static_cast(n)); +} // chebyshev_polynomial_t_forward(T x, T n) + +template +inline C10_HOST_DEVICE T chebyshev_polynomial_u_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (std::abs(x) == T(1.0)) { + if (x > T(0.0) || n % 2 == 0) { + return n + 1; + } + + return -(n + 1); + } + + if ((n > 8) && (std::abs(x) < T(1.0))) { + if (std::sin(std::acos(x)) != T(0.0)) { + return std::sin((n + 1) * std::acos(x)) / std::sin(std::acos(x)); + } + + return (n + 1) * std::cos((n + 1) * std::acos(x)) / x; + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x; + } + + T p = T(1.0); + T q = x + x; + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x) * q - p; + p = q; + q = r; + } + + return r; +} // chebyshev_polynomial_u_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T chebyshev_polynomial_u_forward(T x, T n) { + return chebyshev_polynomial_u_forward(x, static_cast(n)); +} // chebyshev_polynomial_u_forward(T x, T n) + +template +inline C10_HOST_DEVICE T chebyshev_polynomial_v_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (std::abs(x) == T(1.0)) { + if (x > T(0.0)) { + return T(1.0); + } + + if (n % 2 == 0) { + return n + n + 1; + } + + return -(n + n + 1); + } + + if ((n > 8) && (std::abs(x) < T(1.0))) { + if (std::sin(std::acos(x) / T(2.0)) != T(1.0)) { + return std::cos((n + T(0.5)) * std::acos(x)) / std::cos(std::acos(x) / T(2.0)); + } + + if (n % 2 == 0) { + return n + n + 1; + } + + return -(n + n + 1); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0); + } + + T p = T(1.0); + T q = x + x - T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x) * q - p; + p = q; + q = r; + } + + return r; +} // chebyshev_polynomial_v_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T chebyshev_polynomial_v_forward(T x, T n) { + return chebyshev_polynomial_v_forward(x, static_cast(n)); +} // chebyshev_polynomial_v_forward(T x, T n) + +template +inline C10_HOST_DEVICE T chebyshev_polynomial_w_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (std::abs(x) == T(1.0)) { + if (x > T(0.0)) { + return n + n + 1; + } + + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if ((n > 8) && (std::abs(x) < T(1.0))) { + if (std::cos(std::acos(x) / T(2.0)) != T(1.0)) { + return std::sin((n + T(0.5)) * std::acos(x)) / std::sin(std::acos(x) / T(2.0)); + } + + if (x > T(0.0)) { + return n + n + 1; + } + + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x + T(1.0); + } + + T p = T(1.0); + T q = x + x + T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x) * q - p; + p = q; + q = r; + } + + return r; +} // chebyshev_polynomial_w_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T chebyshev_polynomial_w_forward(T x, T n) { + return chebyshev_polynomial_w_forward(x, static_cast(n)); +} // chebyshev_polynomial_w_forward(T x, T n) + +template +constexpr auto getHermitianLimit() { + if constexpr (std::is_same_v) { + return 128; + } else if constexpr (std::is_same_v) { + return 512; + } else { + return 1024; + } +} + +template +inline C10_HOST_DEVICE T hermite_polynomial_h_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x; + } + + if (n > getHermitianLimit()) { + return std::numeric_limits::quiet_NaN(); + } + + T p = T(1.0); + T q = x + x; + T r = T(0.0); + + for (int64_t k = 2; k < n + n; k += 2) { + r = (x + x) * q - k * p; + p = q; + q = r; + } + + return r; +} // hermite_polynomial_h_forward(T x, int64_t n) + +template, int> = 0> +inline C10_HOST_DEVICE T hermite_polynomial_h_forward(T x, T n) { + return hermite_polynomial_h_forward(x, static_cast(n)); +} // hermite_polynomial_h_forward(T x, T n) + +template, int> = 0> +__ubsan_ignore_float_cast_overflow__ inline C10_HOST_DEVICE T hermite_polynomial_h_forward(T x, T n) { + return hermite_polynomial_h_forward(x, (!std::isinf(n) && !std::isnan(n)) ? static_cast(n) : static_cast(-1)); +} // hermite_polynomial_h_forward(T x, T n) + +template +inline C10_HOST_DEVICE T hermite_polynomial_he_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x; + } + + if (n > getHermitianLimit()) { + return std::numeric_limits::quiet_NaN(); + } + + T p = T(1.0); + T q = x; + T r; + + for (int64_t k = 1; k < n; k++) { + r = x * q - k * p; + p = q; + q = r; + } + + return r; +} // hermite_polynomial_he_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T hermite_polynomial_he_forward(T x, T n) { + return hermite_polynomial_he_forward(x, static_cast(n)); +} // hermite_polynomial_he_forward(T x, T n) + +template +inline C10_HOST_DEVICE T laguerre_polynomial_l_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (std::abs(x) == T(0.0)) { + return T(1.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return T(1.0) - x; + } + + T p = T(1.0); + T q = T(1.0) - x; + T r; + + for (int64_t k = 1; k < n; k++) { + r = (((k + k) + (T(1.0) - x)) * q - k * p) / (k + 1); + p = q; + q = r; + } + + return r; +} // laguerre_polynomial_l_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T laguerre_polynomial_l_forward(T x, T n) { + return laguerre_polynomial_l_forward(x, static_cast(n)); +} // laguerre_polynomial_l_forward(T x, T n) + +template +inline C10_HOST_DEVICE T legendre_polynomial_p_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (std::abs(x) == T(1.0)) { + if (x > T(0.0) || n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x; + } + + T p = T(1.0); + T q = x; + T r; + + for (int64_t k = 1; k < n; k++) { + r = ((k + k + 1) * x * q - k * p) / (k + 1); + p = q; + q = r; + } + + return r; +} // legendre_polynomial_p_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T legendre_polynomial_p_forward(T x, T n) { + return legendre_polynomial_p_forward(x, static_cast(n)); +} // legendre_polynomial_p_forward(T x, T n) + +template +inline C10_HOST_DEVICE T modified_bessel_i0_forward(T x) { + static const T A[] = { + -4.41534164647933937950e-18, + +3.33079451882223809783e-17, + -2.43127984654795469359e-16, + +1.71539128555513303061e-15, + -1.16853328779934516808e-14, + +7.67618549860493561688e-14, + -4.85644678311192946090e-13, + +2.95505266312963983461e-12, + -1.72682629144155570723e-11, + +9.67580903537323691224e-11, + -5.18979560163526290666e-10, + +2.65982372468238665035e-09, + -1.30002500998624804212e-08, + +6.04699502254191894932e-08, + -2.67079385394061173391e-07, + +1.11738753912010371815e-06, + -4.41673835845875056359e-06, + +1.64484480707288970893e-05, + -5.75419501008210370398e-05, + +1.88502885095841655729e-04, + -5.76375574538582365885e-04, + +1.63947561694133579842e-03, + -4.32430999505057594430e-03, + +1.05464603945949983183e-02, + -2.37374148058994688156e-02, + +4.93052842396707084878e-02, + -9.49010970480476444210e-02, + +1.71620901522208775349e-01, + -3.04682672343198398683e-01, + +6.76795274409476084995e-01, + }; + + static const T B[] = { + -7.23318048787475395456e-18, + -4.83050448594418207126e-18, + +4.46562142029675999901e-17, + +3.46122286769746109310e-17, + -2.82762398051658348494e-16, + -3.42548561967721913462e-16, + +1.77256013305652638360e-15, + +3.81168066935262242075e-15, + -9.55484669882830764870e-15, + -4.15056934728722208663e-14, + +1.54008621752140982691e-14, + +3.85277838274214270114e-13, + +7.18012445138366623367e-13, + -1.79417853150680611778e-12, + -1.32158118404477131188e-11, + -3.14991652796324136454e-11, + +1.18891471078464383424e-11, + +4.94060238822496958910e-10, + +3.39623202570838634515e-09, + +2.26666899049817806459e-08, + +2.04891858946906374183e-07, + +2.89137052083475648297e-06, + +6.88975834691682398426e-05, + +3.36911647825569408990e-03, + +8.04490411014108831608e-01, + }; + + T p; + T q = 0.0; + + if (std::abs(x) <= T(8.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 30; index++) { + p = q; + q = a; + a = ((std::abs(x) / T(2.0)) - T(2.0)) * q - p + A[index]; + } + + return std::exp(std::abs(x)) * (T(0.5) * (a - p)); + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(32.0) / std::abs(x) - T(2.0)) * q - p + B[index]; + } + + return std::exp(std::abs(x)) * (T(0.5) * (b - p)) / std::sqrt(std::abs(x)); +} // modified_bessel_i0_forward(T x) + +template +inline C10_HOST_DEVICE T modified_bessel_i1_forward(T x) { + static const T A[] = { + +2.77791411276104639959e-18, + -2.11142121435816608115e-17, + +1.55363195773620046921e-16, + -1.10559694773538630805e-15, + +7.60068429473540693410e-15, + -5.04218550472791168711e-14, + +3.22379336594557470981e-13, + -1.98397439776494371520e-12, + +1.17361862988909016308e-11, + -6.66348972350202774223e-11, + +3.62559028155211703701e-10, + -1.88724975172282928790e-09, + +9.38153738649577178388e-09, + -4.44505912879632808065e-08, + +2.00329475355213526229e-07, + -8.56872026469545474066e-07, + +3.47025130813767847674e-06, + -1.32731636560394358279e-05, + +4.78156510755005422638e-05, + -1.61760815825896745588e-04, + +5.12285956168575772895e-04, + -1.51357245063125314899e-03, + +4.15642294431288815669e-03, + -1.05640848946261981558e-02, + +2.47264490306265168283e-02, + -5.29459812080949914269e-02, + +1.02643658689847095384e-01, + -1.76416518357834055153e-01, + +2.52587186443633654823e-01, + }; + + static const T B[] = { + +7.51729631084210481353e-18, + +4.41434832307170791151e-18, + -4.65030536848935832153e-17, + -3.20952592199342395980e-17, + +2.96262899764595013876e-16, + +3.30820231092092828324e-16, + -1.88035477551078244854e-15, + -3.81440307243700780478e-15, + +1.04202769841288027642e-14, + +4.27244001671195135429e-14, + -2.10154184277266431302e-14, + -4.08355111109219731823e-13, + -7.19855177624590851209e-13, + +2.03562854414708950722e-12, + +1.41258074366137813316e-11, + +3.25260358301548823856e-11, + -1.89749581235054123450e-11, + -5.58974346219658380687e-10, + -3.83538038596423702205e-09, + -2.63146884688951950684e-08, + -2.51223623787020892529e-07, + -3.88256480887769039346e-06, + -1.10588938762623716291e-04, + -9.76109749136146840777e-03, + +7.78576235018280120474e-01, + }; + + T p; + T q = 0.0; + + if (std::abs(x) <= T(8.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 29; index++) { + p = q; + q = a; + a = ((std::abs(x) / T(2.0)) - T(2.0)) * q - p + A[index]; + } + + if (x < T(0.0)) { + return -(T(0.5) * (a - p) * std::abs(x) * std::exp(std::abs(x))); + } + + return T(0.5) * (a - p) * std::abs(x) * std::exp(std::abs(x)); + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(32.0) / std::abs(x) - T(2.0)) * q - p + B[index]; + } + + if (x < T(0.0)) { + return -(std::exp(std::abs(x)) * (T(0.5) * (b - p)) / std::sqrt(std::abs(x))); + } + + return std::exp(std::abs(x)) * (T(0.5) * (b - p)) / std::sqrt(std::abs(x)); +} // modified_bessel_i1_forward(T x) + +template +inline C10_HOST_DEVICE T modified_bessel_k0_forward(T x) { + static const T A[] = { + +1.37446543561352307156e-16, + +4.25981614279661018399e-14, + +1.03496952576338420167e-11, + +1.90451637722020886025e-09, + +2.53479107902614945675e-07, + +2.28621210311945178607e-05, + +1.26461541144692592338e-03, + +3.59799365153615016266e-02, + +3.44289899924628486886e-01, + -5.35327393233902768720e-01, + }; + + static const T B[] = { + +5.30043377268626276149e-18, + -1.64758043015242134646e-17, + +5.21039150503902756861e-17, + -1.67823109680541210385e-16, + +5.51205597852431940784e-16, + -1.84859337734377901440e-15, + +6.34007647740507060557e-15, + -2.22751332699166985548e-14, + +8.03289077536357521100e-14, + -2.98009692317273043925e-13, + +1.14034058820847496303e-12, + -4.51459788337394416547e-12, + +1.85594911495471785253e-11, + -7.95748924447710747776e-11, + +3.57739728140030116597e-10, + -1.69753450938905987466e-09, + +8.57403401741422608519e-09, + -4.66048989768794782956e-08, + +2.76681363944501510342e-07, + -1.83175552271911948767e-06, + +1.39498137188764993662e-05, + -1.28495495816278026384e-04, + +1.56988388573005337491e-03, + -3.14481013119645005427e-02, + +2.44030308206595545468e+00, + }; + + if (x == T(0.0)) { + return std::numeric_limits::infinity(); + } + + if (x < T(0.0)) { + return std::numeric_limits::quiet_NaN(); + } + + T p; + T q = 0.0; + + if (x <= T(2.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 10; index++) { + p = q; + q = a; + a = (x * x - T(2.0)) * q - p + A[index]; + } + + return T(0.5) * (a - p) - std::log(0.5 * x) * modified_bessel_i0_forward(x); + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(8.0) / x - T(2.0)) * q - p + B[index]; + } + + return std::exp(-x) * (T(0.5) * (b - p)) / std::sqrt(x); +} // modified_bessel_k0_forward(T x) + +template +inline C10_HOST_DEVICE T modified_bessel_k1_forward(T x) { + static const T A[] = { + -7.02386347938628759343e-18, + -2.42744985051936593393e-15, + -6.66690169419932900609e-13, + -1.41148839263352776110e-10, + -2.21338763073472585583e-08, + -2.43340614156596823496e-06, + -1.73028895751305206302e-04, + -6.97572385963986435018e-03, + -1.22611180822657148235e-01, + -3.53155960776544875667e-01, + +1.52530022733894777053e+00, + }; + + static const T B[] = { + -5.75674448366501715755e-18, + +1.79405087314755922667e-17, + -5.68946255844285935196e-17, + +1.83809354436663880070e-16, + -6.05704724837331885336e-16, + +2.03870316562433424052e-15, + -7.01983709041831346144e-15, + +2.47715442448130437068e-14, + -8.97670518232499435011e-14, + +3.34841966607842919884e-13, + -1.28917396095102890680e-12, + +5.13963967348173025100e-12, + -2.12996783842756842877e-11, + +9.21831518760500529508e-11, + -4.19035475934189648750e-10, + +2.01504975519703286596e-09, + -1.03457624656780970260e-08, + +5.74108412545004946722e-08, + -3.50196060308781257119e-07, + +2.40648494783721712015e-06, + -1.93619797416608296024e-05, + +1.95215518471351631108e-04, + -2.85781685962277938680e-03, + +1.03923736576817238437e-01, + +2.72062619048444266945e+00, + }; + + if (x == T(0.0)) { + return std::numeric_limits::infinity(); + } + + if (x < T(0.0)) { + return std::numeric_limits::quiet_NaN(); + } + + T p; + T q = 0.0; + + if (x <= T(2.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 11; index++) { + p = q; + q = a; + a = (x * x - T(2.0)) * q - p + A[index]; + } + + return std::log(T(0.5) * x) * modified_bessel_i1_forward(x) + T(0.5) * (a - p) / x; + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(8.0) / x - T(2.0)) * q - p + B[index]; + } + + return std::exp(-x) * (T(0.5) * (b - p)) / std::sqrt(x); +} // modified_bessel_k1_forward(T x) + +template +inline C10_HOST_DEVICE T scaled_modified_bessel_k0_forward(T x) { + static const T A[] = { + +1.37446543561352307156e-16, + +4.25981614279661018399e-14, + +1.03496952576338420167e-11, + +1.90451637722020886025e-09, + +2.53479107902614945675e-07, + +2.28621210311945178607e-05, + +1.26461541144692592338e-03, + +3.59799365153615016266e-02, + +3.44289899924628486886e-01, + -5.35327393233902768720e-01, + }; + + static const T B[] = { + +5.30043377268626276149e-18, + -1.64758043015242134646e-17, + +5.21039150503902756861e-17, + -1.67823109680541210385e-16, + +5.51205597852431940784e-16, + -1.84859337734377901440e-15, + +6.34007647740507060557e-15, + -2.22751332699166985548e-14, + +8.03289077536357521100e-14, + -2.98009692317273043925e-13, + +1.14034058820847496303e-12, + -4.51459788337394416547e-12, + +1.85594911495471785253e-11, + -7.95748924447710747776e-11, + +3.57739728140030116597e-10, + -1.69753450938905987466e-09, + +8.57403401741422608519e-09, + -4.66048989768794782956e-08, + +2.76681363944501510342e-07, + -1.83175552271911948767e-06, + +1.39498137188764993662e-05, + -1.28495495816278026384e-04, + +1.56988388573005337491e-03, + -3.14481013119645005427e-02, + +2.44030308206595545468e+00, + }; + + if (x == T(0.0)) { + return std::numeric_limits::infinity(); + } + + if (x < T(0.0)) { + return std::numeric_limits::quiet_NaN(); + } + + T p; + T q = 0.0; + + if (x <= T(2.0)) { + T a = A[0]; + + for (uint64_t index = 1; index < 10; index++) { + p = q; + q = a; + a = (x * x - T(2.0)) * q - p + A[index]; + } + + return (T(0.5) * (a - p) - std::log(T(0.5) * x) * modified_bessel_i0_forward(x)) * std::exp(x); + } + + T b = B[0]; + + for (uint64_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(8.0) / x - T(2.0)) * q - p + B[index]; + } + + return T(0.5) * (b - p) / std::sqrt(x); +} // T scaled_modified_bessel_k0_forward(T x) + +template +inline C10_HOST_DEVICE T scaled_modified_bessel_k1_forward(T x) { + static const T A[] = { + -7.02386347938628759343e-18, + -2.42744985051936593393e-15, + -6.66690169419932900609e-13, + -1.41148839263352776110e-10, + -2.21338763073472585583e-08, + -2.43340614156596823496e-06, + -1.73028895751305206302e-04, + -6.97572385963986435018e-03, + -1.22611180822657148235e-01, + -3.53155960776544875667e-01, + +1.52530022733894777053e+00, + }; + + static const T B[] = { + -5.75674448366501715755e-18, + +1.79405087314755922667e-17, + -5.68946255844285935196e-17, + +1.83809354436663880070e-16, + -6.05704724837331885336e-16, + +2.03870316562433424052e-15, + -7.01983709041831346144e-15, + +2.47715442448130437068e-14, + -8.97670518232499435011e-14, + +3.34841966607842919884e-13, + -1.28917396095102890680e-12, + +5.13963967348173025100e-12, + -2.12996783842756842877e-11, + +9.21831518760500529508e-11, + -4.19035475934189648750e-10, + +2.01504975519703286596e-09, + -1.03457624656780970260e-08, + +5.74108412545004946722e-08, + -3.50196060308781257119e-07, + +2.40648494783721712015e-06, + -1.93619797416608296024e-05, + +1.95215518471351631108e-04, + -2.85781685962277938680e-03, + +1.03923736576817238437e-01, + +2.72062619048444266945e+00, + }; + + if (x == T(0.0)) { + return std::numeric_limits::infinity(); + } + + if (x < T(0.0)) { + return std::numeric_limits::quiet_NaN(); + } + + T p; + T q = 0.0; + + if (x <= T(2.0)) { + T a = A[0]; + + for (uint64_t index = 1; index < 11; index++) { + p = q; + q = a; + a = (x * x - T(2.0)) * q - p + A[index]; + } + + return (std::log(T(0.5) * x) * modified_bessel_i1_forward(x) + T(0.5) * (a - p) / x) * std::exp(x); + } + + T b = B[0]; + + for (uint64_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(8.0) / x - T(2.0)) * q - p + B[index]; + } + + return (T(0.5) * (b - p) / std::sqrt(x)); +} // T scaled_modified_bessel_k1_forward(T x) + +template +inline C10_HOST_DEVICE T shifted_chebyshev_polynomial_t_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (x == T(1.0)) { + return T(1.0); + } + + if (x == T(0.0)) { + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if ((n > 6) && (std::abs(x + x - T(1.0)) < T(1.0))) { + return std::cos(n * std::acos(x + x - T(1.0))); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0); + } + + T p = T(1.0); + T q = x + x - T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x - T(1.0) + (x + x - T(1.0))) * q - p; + p = q; + q = r; + } + + return r; +} // shifted_chebyshev_polynomial_t_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T shifted_chebyshev_polynomial_t_forward(T x, T n) { + return shifted_chebyshev_polynomial_t_forward(x, static_cast(n)); +} // shifted_chebyshev_polynomial_t_forward(T x, T n) + +template +inline C10_HOST_DEVICE T shifted_chebyshev_polynomial_u_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (x == T(1.0)) { + return n + 1; + } + + if (x == T(0.0)) { + if (n % 2 == 0) { + return n + 1; + } + + return -(n + 1); + } + + if ((n > 6) && (std::abs(x + x - T(1.0)) < T(1.0))) { + if (std::sin(std::acos(x + x - T(1.0))) != T(0.0)) { + return std::sin((n + 1) * std::acos(x + x - T(1.0))) / std::sin(std::acos(x + x - T(1.0))); + } + + return (n + 1) * std::cos((n + 1) * std::acos(x + x - T(1.0))) / (x + x - T(1.0)); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0) + (x + x - T(1.0)); + } + + T p = T(1.0); + T q = x + x - T(1.0) + (x + x - T(1.0)); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x - T(1.0) + (x + x - T(1.0))) * q - p; + p = q; + q = r; + } + + return r; +} // shifted_chebyshev_polynomial_u_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T shifted_chebyshev_polynomial_u_forward(T x, T n) { + return shifted_chebyshev_polynomial_u_forward(x, static_cast(n)); +} // shifted_chebyshev_polynomial_u_forward(T x, T n) + +template +inline C10_HOST_DEVICE T shifted_chebyshev_polynomial_v_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (x == T(1.0)) { + return T(1.0); + } + + if (x == T(0.0)) { + if (n % 2 == 0) { + return (n + n + 1); + } + + return -(n + n + 1); + } + + if ((n > 6) && (std::abs(x + x - T(1.0)) < T(1.0))) { + if (std::sin(std::acos(x + x - T(1.0)) / T(2.0)) != T(1.0)) { + return std::cos(((n) + T(0.5)) * std::acos(x + x - T(1.0))) / std::cos(std::acos(x + x - T(1.0)) / T(2.0)); + } + + if (n % 2 == 0) { + return n + n + 1; + } + + return -(n + n + 1); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0) + (x + x - T(1.0)) - T(1.0); + } + + T p = T(1.0); + T q = x + x - T(1.0) + (x + x - T(1.0)) - T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x - T(1.0) + (x + x - T(1.0))) * q - p; + p = q; + q = r; + } + + return r; +} // shifted_chebyshev_polynomial_v_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T shifted_chebyshev_polynomial_v_forward(T x, T n) { + return shifted_chebyshev_polynomial_v_forward(x, static_cast(n)); +} // shifted_chebyshev_polynomial_v_forward(T x, T n) + +template +inline C10_HOST_DEVICE T shifted_chebyshev_polynomial_w_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (x == T(1.0)) { + return n + n + 1; + } + + if (x == T(0.0)) { + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if ((n > 4) && (std::abs(x + x - T(1.0)) < T(1.0))) { + if (std::cos(std::acos(x + x - T(1.0)) / T(2.0)) != T(1.0)) { + return std::sin((n + T(0.5)) * std::acos(x + x - T(1.0))) / std::sin(std::acos(x + x - T(1.0)) / T(2.0)); + } + + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0) + (x + x - T(1.0)) + T(1.0); + } + + T p = T(1.0); + T q = x + x - T(1.0) + (x + x - T(1.0)) + T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x - T(1.0) + (x + x - T(1.0))) * q - p; + p = q; + q = r; + } + + return r; +} // shifted_chebyshev_polynomial_w_forward(T x, int64_t n) + +template +inline C10_HOST_DEVICE T shifted_chebyshev_polynomial_w_forward(T x, T n) { + return shifted_chebyshev_polynomial_w_forward(x, static_cast(n)); +} // shifted_chebyshev_polynomial_w_forward(T x, T n) + +template +inline C10_HOST_DEVICE T spherical_bessel_j0_forward(T x) { + if (std::isinf(x)) { + return T(0.0); + } + + if (std::abs(x) < T(0.5)) { + return T(1.0) + x * x * (T(-1.0) / T(6.0) + x * x * (T(1.0) / T(120.0) + x * x * (T(-1.0) / T(5040.0) + x * x * (T(1.0) / T(362880.0) + x * x * (T(-1.0) / T(39916800.0) + x * x * (T(1.0) / T(6227020800.0))))))); + } + + return std::sin(x) / x; +} // T spherical_bessel_j0_forward(T x) + +C10_CLANG_DIAGNOSTIC_POP() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/MathBitFallThroughLists.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/MathBitFallThroughLists.h new file mode 100644 index 0000000000000000000000000000000000000000..97b0854d82d0a2fec6bb708db767d81273ec7bcc --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/MathBitFallThroughLists.h @@ -0,0 +1,71 @@ +#pragma once + +namespace at { +// views and their in-place version ops +#define TORCH_VIEW_FNS(m) \ + m.impl("as_strided_", torch::CppFunction::makeFallthrough()); \ + m.impl("detach", torch::CppFunction::makeFallthrough()); \ + m.impl("detach_", torch::CppFunction::makeFallthrough()); \ + m.impl("diagonal", torch::CppFunction::makeFallthrough()); \ + m.impl("expand", torch::CppFunction::makeFallthrough()); \ + m.impl("expand_as", torch::CppFunction::makeFallthrough()); \ + m.impl("movedim.int", torch::CppFunction::makeFallthrough()); \ + m.impl("movedim.intlist", torch::CppFunction::makeFallthrough()); \ + m.impl("narrow", torch::CppFunction::makeFallthrough()); \ + m.impl("permute", torch::CppFunction::makeFallthrough()); \ + m.impl("select.Dimname", torch::CppFunction::makeFallthrough()); \ + m.impl("select.int", torch::CppFunction::makeFallthrough()); \ + m.impl("squeeze", torch::CppFunction::makeFallthrough()); \ + m.impl("squeeze_", torch::CppFunction::makeFallthrough()); \ + m.impl("transpose.int", torch::CppFunction::makeFallthrough()); \ + m.impl("transpose.Dimname", torch::CppFunction::makeFallthrough()); \ + m.impl("transpose_", torch::CppFunction::makeFallthrough()); \ + m.impl("t", torch::CppFunction::makeFallthrough()); \ + m.impl("t_", torch::CppFunction::makeFallthrough()); \ + m.impl("real", torch::CppFunction::makeFallthrough()); \ + m.impl("imag", torch::CppFunction::makeFallthrough()); \ + m.impl("view_as_real", torch::CppFunction::makeFallthrough()); \ + m.impl("unflatten.int", torch::CppFunction::makeFallthrough()); \ + m.impl("unflatten.Dimname", torch::CppFunction::makeFallthrough()); \ + m.impl("unfold", torch::CppFunction::makeFallthrough()); \ + m.impl("unsqueeze", torch::CppFunction::makeFallthrough()); \ + m.impl("unsqueeze_", torch::CppFunction::makeFallthrough()); \ + m.impl("view_as", torch::CppFunction::makeFallthrough()); \ + m.impl("unbind.int", torch::CppFunction::makeFallthrough()); \ + m.impl("unbind.Dimname", torch::CppFunction::makeFallthrough()); \ + m.impl("split.Tensor", torch::CppFunction::makeFallthrough()); \ + m.impl("split_with_sizes", torch::CppFunction::makeFallthrough()); \ + m.impl("swapaxes", torch::CppFunction::makeFallthrough()); \ + m.impl("swapdims", torch::CppFunction::makeFallthrough()); \ + m.impl("chunk", torch::CppFunction::makeFallthrough()); \ + m.impl("reshape", torch::CppFunction::makeFallthrough()); \ + m.impl("alias", torch::CppFunction::makeFallthrough()); \ + m.impl("hsplit.int", torch::CppFunction::makeFallthrough()); \ + m.impl("hsplit.array", torch::CppFunction::makeFallthrough()); \ + m.impl("dsplit.int", torch::CppFunction::makeFallthrough()); \ + m.impl("dsplit.array", torch::CppFunction::makeFallthrough()); \ + m.impl("vsplit.int", torch::CppFunction::makeFallthrough()); \ + m.impl("vsplit.array", torch::CppFunction::makeFallthrough()); \ + m.impl("conj", torch::CppFunction::makeFallthrough()); \ + m.impl("_conj", torch::CppFunction::makeFallthrough()); \ + m.impl("_unsafe_view", torch::CppFunction::makeFallthrough()); \ + m.impl("resize_", torch::CppFunction::makeFallthrough()); + +#define TENSOR_UTILITIES_AND_CONSTRUCTORS(m) \ + m.impl("empty_like", torch::CppFunction::makeFallthrough()); \ + m.impl("empty.memory_format", torch::CppFunction::makeFallthrough()); \ + m.impl("empty.out", torch::CppFunction::makeFallthrough()); \ + m.impl("empty_strided", torch::CppFunction::makeFallthrough()); \ + m.impl("full_like", torch::CppFunction::makeFallthrough()); \ + m.impl("stride.int", torch::CppFunction::makeFallthrough()); \ + m.impl("stride.Dimname", torch::CppFunction::makeFallthrough()); \ + m.impl("size.int", torch::CppFunction::makeFallthrough()); \ + m.impl("size.Dimname", torch::CppFunction::makeFallthrough()); \ + m.impl("is_complex", torch::CppFunction::makeFallthrough()); \ + m.impl("is_floating_point", torch::CppFunction::makeFallthrough()); \ + m.impl("requires_grad_", torch::CppFunction::makeFallthrough()); +} + +#define TORCH_VIEW_FNS_NATIVE_FN_REGISTRATION(m) \ + m.impl("as_strided", torch::CppFunction::makeFallthrough()); \ + m.impl("view", torch::CppFunction::makeFallthrough()); diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/MathBitsFallback.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/MathBitsFallback.h new file mode 100644 index 0000000000000000000000000000000000000000..de2296634e04511497827128c4483c5e75c6a674 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/MathBitsFallback.h @@ -0,0 +1,157 @@ +#include +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include + +#include +#endif + +namespace at::native { +// This fallback should only be used for operations that are self inverse and have a corresponding tensor +// bit (internally implemented using DispatchKey) to maintain the state on tensor using tensor bit. +// Currently there are two tensor bits that trigger this fallback: conjugate bit and negative bit. +// Conjugate bit is set on a tensor when `.conj()` is called and neg bit is set on a tensor when `.conj().imag` is called. + +// NOTE: To use this fallback, `clone` and `copy_` should fully understand and be able to correctly handle the semantic of your math bit. +struct MathOpFallback { + MathOpFallback(DispatchKey key_, string op_name_) : key(key_), op_name(std::move(op_name_)) {} + virtual bool is_bit_set(const Tensor&) = 0; + void fallback_impl(const c10::OperatorHandle& op, DispatchKeySet dispatch_keys, torch::jit::Stack* stack) { + /* + Situations to handle: + 1. Out-of-place operation. Easy: materialize all inputs and + call it a day. + 2. Inplace operation. Desugar x.add_(2) into x.conj_().add_(2).conj_(). + Materialize other inputs as in (1). + 3. out= operation. Desugar add(x, 2, out=y) into y.copy_(add(x, 2)) + Materialize other inputs as in (1). + + It is important to be able to tell if we READ from an argument and if we + WRITE to an argument. Conservative approach is to assume that we always + READ from an argument, but in out= operations you can skip + conjugating inputs on entry that never get used. In the current schema we + can't easily tell if the operation is in in-place or out= operation. + + Note: + 1. Mutable tensorlists containing tensors whose math bit set to true are disallowed. + 2. Mutable tensors with math bit set to true are unconditionally cloned to ensure + correct behavior in the case when the mutable tensor shares memory with non mutable arguments. + + If we were to in-place resolve the math bit for mutable inputs, then the non-mutable inputs sharing partial or full memory + with these mutable inputs would read into wrong values in the following cases: + 1. Non mutable inputs have their math bit set to false. + 2. Math bit for mutable input(s) is resolved before the non mutable inputs (with bit set to true and sharing memory + with one or more mutable arg(s)) are cloned. + At the end, the final value of the mutable arguments from the stack are copied into the original input mutable tensor inputs. + */ + const auto& arguments = op.schema().arguments(); + const auto num_arguments = arguments.size(); + const auto stack_start = stack->size() - num_arguments; + + std::optional is_write; + for (const auto i : c10::irange(num_arguments)) { + // Three possible states: + // 1. alias_info has no value --> out-of-place operation + // 2. alias_info does have a value, alias_info->is_write=True --> in-place or out= operation + // 3. alias_info does have a value, alias_info->is_write=False --> view operation + const AliasInfo* alias_info = arguments[i].alias_info(); + if (alias_info != nullptr) { + if (is_write.has_value()) { + TORCH_CHECK(*is_write == alias_info->isWrite(), + "Unsupported operator for ", op_name, " fallback: ", op.schema().name(), + op_name, " fallback doesn't work for operators with a mix " + "mutable and non-mutable inputs that alias with outputs, " + "this must be implemented manually. " + "If you got this error on a core op, please report a bug to PyTorch."); + } else { + is_write = alias_info->isWrite(); + } + } + } + + if (is_write.has_value() && !*is_write) { + // We assume that view operators automatically handle the math bit + // correctly by propagating the dispatch key in key_set. + // This is not necessarily always right, so you should test these cases. + op.redispatchBoxed(dispatch_keys & c10::DispatchKeySet(DispatchKeySet::FULL_AFTER, key), stack); + return; + } + + // Mutable inputs with math bit set to True and their clones + std::vector> mutable_inputs_with_their_clones; + for (const auto i : c10::irange(num_arguments)) { + auto& ivalue = (*stack)[stack_start + i]; + if (!(ivalue.isTensor() || ivalue.isTensorList())) { + continue; + } + const auto& argument = arguments[i]; + bool mut_arg = false; + if (argument.alias_info()) { + // Was already tested by is_write loop above + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(argument.alias_info()->isWrite()); + mut_arg = true; + } + if (ivalue.isTensor()) { + if (!is_bit_set(ivalue.toTensor())) { + continue; + } + auto tensor = std::move(ivalue).toTensor(); + auto resolved_tensor = at::clone(tensor); + if (mut_arg) { + TORCH_CHECK(mutable_inputs_with_their_clones.empty(), op_name, " fallback does not support operators with more than one mutable tensors with ", + op_name, "bit set to true."); + mutable_inputs_with_their_clones.emplace_back(std::move(tensor), resolved_tensor); + } + (*stack)[stack_start + i] = std::move(resolved_tensor); + } else if (ivalue.isTensorList()) { + auto tensors = std::move(ivalue).toTensorList(); + for(const auto j : c10::irange(tensors.size())) { + const auto& tensor = tensors[j]; + if (!is_bit_set(tensor)) { + continue; + } + TORCH_CHECK(!mut_arg, " fallback doesn't currently support mutable TensorLists with ", + op_name, " inputs. Please materialize all the ", op_name, " input tensor(s) in the mutable TensorList inputs before calling ", + op.schema().name()); + tensors[j] = at::clone(tensor); + } + (*stack)[stack_start + i] = std::move(tensors); + } + } + + op.redispatchBoxed(dispatch_keys & c10::DispatchKeySet(DispatchKeySet::FULL_AFTER, key), stack); + + TORCH_INTERNAL_ASSERT(mutable_inputs_with_their_clones.size() <= 1); + + for (std::pair mut_tensors: mutable_inputs_with_their_clones) { + auto& mutable_input = mut_tensors.first; + auto& cloned_mutable_input = mut_tensors.second; + auto& ivalue = (*stack)[stack_start]; + auto returned_output = std::move(ivalue).toTensor(); + + // sanity check to ensure that the tensor in stack aliases the cloned_mutable_input + TORCH_INTERNAL_ASSERT(cloned_mutable_input.is_same(returned_output)); + + // necessary for out= arg + at::native::resize_output(mutable_input, returned_output.sizes()); + + mutable_input.copy_(returned_output); + (*stack)[stack_start] = std::move(mutable_input); + } + } + + virtual ~MathOpFallback() = default; + + DispatchKey key; + string op_name; +}; + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/MaxPooling.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/MaxPooling.h new file mode 100644 index 0000000000000000000000000000000000000000..50d1205ba3ceffdf5cbd937e983f204ae094152b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/MaxPooling.h @@ -0,0 +1,97 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::native { + +inline void check_max_pool1d( + const Tensor& self, + IntArrayRef kernel_size, + IntArrayRef stride, + IntArrayRef padding, + IntArrayRef dilation, + bool ceil_mode) { + + TORCH_CHECK( + self.dim() == 2 || self.dim() == 3, + "max_pool1d() Expected 2D or 3D input tensor, but got ", self.sym_sizes()); + TORCH_CHECK( + kernel_size.size() == 1, + "max_pool1d() kernel_size must be an int, list of ints or tuple of ints of size 1 but got size ", + kernel_size.size()); + TORCH_CHECK( + stride.empty() || stride.size() == 1, + "max_pool1d() stride must be None, an int, list of ints, or tuple of ints of size 1 but got size ", + stride.size()); + TORCH_CHECK( + padding.size() == 1, + "max_pool1d() padding must be an int, list of ints, or tuple of ints of size 1 but got size ", + padding.size()); + TORCH_CHECK( + dilation.size() == 1, + "max_pool1d() dilation must be an int, list of ints or tuple of ints of size 1 but got size ", + dilation.size()); + + // If stride=None then set it to kernel_size + if (stride.empty()) { + stride = kernel_size; + } + + TORCH_CHECK( + kernel_size[0] > 0, + "max_pool1d() kernel_size must be greater than zero, but got ", + kernel_size[0]); + TORCH_CHECK( + stride[0] > 0, "max_pool1d() stride must be greater than zero, but got ", stride[0]); + TORCH_CHECK( + padding[0] >= 0, "max_pool1d() padding must be non-negative, but got ", padding[0]); + TORCH_CHECK( + padding[0] <= kernel_size[0] / 2, + "max_pool1d() padding should be at most half of kernel size, but got padding=", + padding[0], + " and kernel_size=", + kernel_size[0]); + TORCH_CHECK( + dilation[0] > 0, "max_pool1d() dilation must be greater than zero, but got ", dilation[0]); + + const int64_t OW = pooling_output_shape(self.sym_size(-1).guard_int(__FILE__, __LINE__), kernel_size[0], padding[0], stride[0], dilation[0], ceil_mode); + TORCH_CHECK(OW > 0, "max_pool1d() Invalid computed output size: ", OW); +} + +// TODO(Heitor) Template by dimension +struct PoolingParams1D { + int64_t NB; // Number of batches + int64_t NC; // Number of channels + int64_t IW; // Input width + int64_t OW; // Output width + int64_t KW; // Kernel width + int64_t SJ; // Column stride + int64_t PJ; // Column padding + int64_t DJ; // Column dilation + + // Return index of input element for the given kernel and output index + inline int64_t index(int64_t kj, int64_t oj) const { + return oj * SJ + kj * DJ - PJ; + } + + // Return index of first output within bounds for this kernel index + inline int64_t valid_output_start(int64_t kj) const { + int64_t ij = index(kj, 0);; + return ij < 0 ? at::divup(-ij, SJ) : 0; + } + + // Return index one past last output within bounds for this kernel index + inline int64_t valid_output_end(int64_t kj) const { + int64_t ij = index(kj, OW - 1); + return ij >= IW ? OW - at::divup(ij - (IW - 1), SJ) : OW; + } +}; + +using pooling_fn = void (*)(Tensor&, const Tensor&, const PoolingParams1D&); + +DECLARE_DISPATCH(pooling_fn, max_pool1d_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/NonEmptyUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/NonEmptyUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..3d18bc5e1525bacaf27d97a86024540236ce6220 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/NonEmptyUtils.h @@ -0,0 +1,27 @@ +#include +#include +#include + +namespace at::native { + +inline int64_t ensure_nonempty_dim(int64_t dim) { + return std::max(dim, 1); +} + +inline int64_t ensure_nonempty_size(const TensorBase &t, int64_t dim) { + return t.dim() == 0 ? 1 : t.size(dim); +} + +inline int64_t ensure_nonempty_stride(const TensorBase &t, int64_t dim) { + return t.dim() == 0 ? 1 : t.stride(dim); +} + +using IdxVec = std::vector; +inline IdxVec ensure_nonempty_vec(IdxVec vec) { + if (vec.empty()) { + vec.push_back(1); + } + return vec; +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/NonSymbolicBC.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/NonSymbolicBC.h new file mode 100644 index 0000000000000000000000000000000000000000..fbcfd3a13f9c3c71a5291fdad2e6b95b186cf681 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/NonSymbolicBC.h @@ -0,0 +1,26 @@ +#pragma once +#include +#include +#include + +namespace at::native { +// This file contains non-symbolic signatures for ops that we have sym-intified the signature of. +// However, in certain cases (such as static runtime), we call the native versions of the ops directly. +// In those cases, we will duplicate the signature here with non-symbolic ints, and also duplicate the C++ implementation. +TORCH_API at::Tensor reshape(const at::Tensor& self, at::IntArrayRef proposed_shape); +TORCH_API at::Tensor narrow(const at::Tensor& self, int64_t dim, int64_t start, int64_t length); +TORCH_API at::Tensor _sparse_coo_tensor_unsafe(const at::Tensor & indices, const at::Tensor & values, at::IntArrayRef size, std::optional dtype=std::nullopt, std::optional layout=std::nullopt, std::optional device=std::nullopt, std::optional pin_memory=std::nullopt, std::optional is_coalesced=std::nullopt); +TORCH_API at::Tensor nll_loss(const at::Tensor & self, const at::Tensor & target, const std::optional& weight_opt, int64_t reduction, int64_t ignore_index); +TORCH_API at::Tensor nll_loss2d(const at::Tensor & self, const at::Tensor & target, const std::optional& weight_opt, int64_t reduction, int64_t ignore_index); +// The below ops don't get a duplicated C++ implementation. +// They are backward ops, which make them very unlikely to be called directly +// by external code (at::native::trace_backward). +// They get their own declaration for BC purposes however. +TORCH_API at::Tensor _embedding_bag_backward(const at::Tensor & grad, const at::Tensor & indices, const at::Tensor & offsets, const at::Tensor & offset2bag, const at::Tensor & bag_size, const at::Tensor & maximum_indices, int64_t num_weights, bool scale_grad_by_freq, int64_t mode, bool sparse, const std::optional & per_sample_weights, int64_t padding_idx=-1); +TORCH_API at::Tensor _embedding_bag_sparse_backward(const at::Tensor & grad, const at::Tensor & indices, const at::Tensor & offsets, const at::Tensor & offset2bag, const at::Tensor & bag_size, int64_t num_weights, bool scale_grad_by_freq, int64_t mode, const std::optional & per_sample_weights, int64_t padding_idx=-1); +TORCH_API at::Tensor value_selecting_reduction_backward(const at::Tensor & grad, int64_t dim, const at::Tensor & indices, at::IntArrayRef sizes, bool keepdim); +TORCH_API at::Tensor trace_backward(const at::Tensor & grad, at::IntArrayRef sizes); +TORCH_API at::Tensor index_select_backward(const at::Tensor & grad, at::IntArrayRef self_sizes, int64_t dim, const at::Tensor & index); +TORCH_API at::Tensor select(const at::Tensor& self, int64_t dim, int64_t index); +TORCH_API std::vector tensor_split(const Tensor& self, IntArrayRef indices, int64_t dim); +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Normalization.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Normalization.h new file mode 100644 index 0000000000000000000000000000000000000000..5eebb514a4690338a3ce78f802c6bc2f6540041b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Normalization.h @@ -0,0 +1,19 @@ +#pragma once + +#include +#include + +namespace at::native { + +using renorm_scale_factor_fn = void (*) (TensorIteratorBase& iter, double maxnorm); +DECLARE_DISPATCH(renorm_scale_factor_fn, renorm_scale_factor_stub) + +enum class BatchNormBackend { + Native, + Cudnn, + Miopen, +}; + +TORCH_API BatchNormBackend _select_batch_norm_backend(const Tensor& input, const Tensor& weight, const Tensor& bias, const Tensor& running_mean, const Tensor& running_var, bool training, double eps); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Padding.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Padding.h new file mode 100644 index 0000000000000000000000000000000000000000..bdb24cd2159b05ff6b4b6ca117187b310c16952c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Padding.h @@ -0,0 +1,63 @@ +#pragma once + +#include +#include + +namespace at::native { + +using padding_fn = void (*)(const Tensor&, const Tensor&, IntArrayRef); + +// reflection padding +DECLARE_DISPATCH(padding_fn, reflection_pad1d_kernel) +DECLARE_DISPATCH(padding_fn, reflection_pad1d_backward_kernel) +DECLARE_DISPATCH(padding_fn, reflection_pad2d_kernel) +DECLARE_DISPATCH(padding_fn, reflection_pad2d_backward_kernel) +DECLARE_DISPATCH(padding_fn, reflection_pad3d_kernel) +DECLARE_DISPATCH(padding_fn, reflection_pad3d_backward_kernel) + +// replication padding +DECLARE_DISPATCH(padding_fn, replication_pad1d_kernel) +DECLARE_DISPATCH(padding_fn, replication_pad1d_backward_kernel) +DECLARE_DISPATCH(padding_fn, replication_pad2d_kernel) +DECLARE_DISPATCH(padding_fn, replication_pad2d_backward_kernel) +DECLARE_DISPATCH(padding_fn, replication_pad3d_kernel) +DECLARE_DISPATCH(padding_fn, replication_pad3d_backward_kernel) + +namespace padding { + +template +inline void check_valid_input(const Tensor& input, IntArrayRef padding) { + + TORCH_CHECK(padding.size() == 2 * dim, + "padding size is expected to be ", 2 * dim, + ", but got: ", padding.size()); + + int input_dim = input.dim(); + + bool is_batch_mode = input_dim == (dim + 2); + bool is_non_batch_mode = input_dim == (dim + 1); + + bool valid_batch_mode = is_batch_mode; + bool valid_non_batch_mode = is_non_batch_mode; + + if (is_batch_mode) { + // allow batch size of 0-dim. + for (const auto d : c10::irange(1, input_dim)) { + valid_batch_mode = valid_batch_mode && input.size(d) != 0; + } + } else { + for (const auto d : c10::irange(0, input_dim)) { + valid_non_batch_mode = valid_non_batch_mode && input.size(d) != 0; + } + } + + // allow empty batch size but not other dimensions. + TORCH_CHECK(valid_batch_mode || valid_non_batch_mode, + "Expected ", dim + 1, "D or ", dim + 2, + "D (batch mode) tensor with possibly 0 batch size and other non-zero dimensions for input, but got: ", + input.sizes()); +} + +} // namespace padding + +} // at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/PixelShuffle.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/PixelShuffle.h new file mode 100644 index 0000000000000000000000000000000000000000..49699107d9c4f2ef0341e57b0a233221a13e842e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/PixelShuffle.h @@ -0,0 +1,46 @@ +#include +#include + +namespace at::native { + +inline void check_pixel_shuffle_shapes(const Tensor& self, int64_t upscale_factor) { + TORCH_CHECK(self.dim() >= 3, + "pixel_shuffle expects input to have at least 3 dimensions, but got input with ", + self.dim(), " dimension(s)"); + TORCH_CHECK(upscale_factor > 0, + "pixel_shuffle expects a positive upscale_factor, but got ", + upscale_factor); + int64_t c = self.size(-3); + int64_t upscale_factor_squared = upscale_factor * upscale_factor; + TORCH_CHECK(c % upscale_factor_squared == 0, + "pixel_shuffle expects its input's 'channel' dimension to be divisible by the square of " + "upscale_factor, but input.size(-3)=", c, " is not divisible by ", upscale_factor_squared); +} + +inline void check_pixel_unshuffle_shapes(const Tensor& self, int64_t downscale_factor) { + TORCH_CHECK( + self.dim() >= 3, + "pixel_unshuffle expects input to have at least 3 dimensions, but got input with ", + self.dim(), + " dimension(s)"); + TORCH_CHECK( + downscale_factor > 0, + "pixel_unshuffle expects a positive downscale_factor, but got ", + downscale_factor); + int64_t h = self.size(-2); + int64_t w = self.size(-1); + TORCH_CHECK( + h % downscale_factor == 0, + "pixel_unshuffle expects height to be divisible by downscale_factor, but input.size(-2)=", + h, + " is not divisible by ", + downscale_factor); + TORCH_CHECK( + w % downscale_factor == 0, + "pixel_unshuffle expects width to be divisible by downscale_factor, but input.size(-1)=", + w, + " is not divisible by ", + downscale_factor); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/PointwiseOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/PointwiseOps.h new file mode 100644 index 0000000000000000000000000000000000000000..6a1bd7e4e4e232067cc020cb65f2f77d62709e93 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/PointwiseOps.h @@ -0,0 +1,28 @@ +// Ternary and higher-order pointwise operations +#pragma once + +#include + +namespace c10 { +class Scalar; +} + +namespace at { + +struct TensorIterator; +struct TensorIteratorBase; + +namespace native { + +using pointwise_fn = void (*)(TensorIterator&, const Scalar& scalar); +using structured_pointwise_fn = void (*)(TensorIteratorBase&, const Scalar& scalar); +using pointwise_fn_double = void (*)(TensorIterator&, const Scalar&, double); + +DECLARE_DISPATCH(structured_pointwise_fn, addcmul_stub) +DECLARE_DISPATCH(structured_pointwise_fn, addcdiv_stub) +DECLARE_DISPATCH(pointwise_fn_double, smooth_l1_backward_stub) +DECLARE_DISPATCH(pointwise_fn_double, huber_backward_stub) +DECLARE_DISPATCH(pointwise_fn, mse_backward_stub) + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Pool.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Pool.h new file mode 100644 index 0000000000000000000000000000000000000000..51d19102ad934fea419d61dc872278a0c322fe34 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Pool.h @@ -0,0 +1,361 @@ +#include +#include +#include +#include +#include + +#include + +#pragma once + +namespace at::native { + +using max_pool2d_fn = void(*)(const Tensor& output, const Tensor& indices, const Tensor& input, + int kW, int kH, int dW, int dH, int padW, int padH, int dilationW, int dilationH); +using max_pool2d_backward_fn = void(*)(const Tensor& grad_input, const Tensor& grad_output, const Tensor& indices); + +DECLARE_DISPATCH(max_pool2d_fn, max_pool2d_kernel) +DECLARE_DISPATCH(max_pool2d_backward_fn, max_pool2d_backward_kernel) + +// averge pooling has same signature for forward and backward +using avg_pool2d_fn = void(*)(const Tensor& output, const Tensor& input, int64_t kW, int64_t kH, + int64_t dW, int64_t dH, int64_t padW, int64_t padH, bool count_include_pad, std::optional divisor_override); +using avg_pool2d_backward_fn = void(*)(const Tensor& output, const Tensor& input, int kW, int kH, + int dW, int dH, int padW, int padH, bool count_include_pad, std::optional divisor_override); + +DECLARE_DISPATCH(avg_pool2d_fn, avg_pool2d_kernel) +DECLARE_DISPATCH(avg_pool2d_backward_fn, avg_pool2d_backward_kernel) + +// averge pooling has same signature for forward and backward +using avg_pool3d_fn = void(*)(const Tensor& output, const Tensor& input, + int64_t kW, int64_t kH, int64_t kD, int64_t dW, int64_t dH, int64_t dD, + int64_t padW, int64_t padH, int64_t padD, bool count_include_pad, + std::optional divisor_override); +using avg_pool3d_backward_fn = void(*)(const Tensor& output, const Tensor& input, + int kW, int kH, int kD, int dW, int dH, int dD, + int padW, int padH, int padD, bool count_include_pad, + std::optional divisor_override); + +DECLARE_DISPATCH(avg_pool3d_fn, avg_pool3d_kernel) +DECLARE_DISPATCH(avg_pool3d_backward_fn, avg_pool3d_backward_kernel) + +using max_pool3d_fn = void(*)(Tensor& output, Tensor& indices, const Tensor& input, + int kW, int kH, int kD, int dW, int dH, int dD, int pW, int pH, int pD, int dilationW, int dilationH, int dilationD); +using max_pool3d_backward_fn = void(*)(Tensor& grad_input, const Tensor& grad_output, const Tensor& indices); + +DECLARE_DISPATCH(max_pool3d_fn, max_pool3d_kernel) +DECLARE_DISPATCH(max_pool3d_backward_fn, max_pool3d_backward_kernel) +namespace { + +template +inline dest_t +safe_downcast(src_t v) +{ + TORCH_CHECK(std::numeric_limits::min() <= v && v <= std::numeric_limits::max(), + "integer out of range"); + + return static_cast(v); +} + +template +inline T pooling_output_shape_pad_lr( + T inputSize, T kernelSize, T pad_l, T pad_r, T stride, T dilation, + bool ceil_mode) { + T outputSize = div_rtn( + inputSize + pad_l + pad_r - dilation * (kernelSize - 1) - 1 + + (ceil_mode ? stride - 1 : 0), stride) + 1; + if (ceil_mode) { + // ensure that the last pooling starts inside the image + // needed to avoid problems in ceil mode + if ((outputSize - 1) * stride >= inputSize + pad_l) { + --outputSize; + } + } + return outputSize; +} + +template +inline T pooling_output_shape( + T inputSize, T kernelSize, T pad, T stride, T dilation, bool ceil_mode) { + TORCH_CHECK(stride != 0, "stride should not be zero"); + TORCH_CHECK(pad >= 0, + "pad must be non-negative, but got pad: ", pad); + TORCH_CHECK(pad <= ((kernelSize - 1) * dilation + 1) / 2, + "pad should be at most half of effective kernel size, but got pad=", + pad, ", kernel_size=", kernelSize, " and dilation=", dilation) + return pooling_output_shape_pad_lr( + inputSize, kernelSize, pad, pad, stride, dilation, ceil_mode); +} + +template +std::pair _pooling_same_mode_padding_lr( + T inputSize, T kernelSize, T stride, T dilation) { + // NOTE: with strides, the output shape is ceil(inputSize/stride) + auto total_padding = T(dilation) * (kernelSize - 1); + + // Prefer symmetric padding if possible + if (stride > 2 && (total_padding % 2 == 1)) { + // The floor in the output size calculation gives us a little wiggle room + auto wiggle_room = inputSize % stride - 1; + if (wiggle_room > 0) { + total_padding = total_padding - 1; + } + } + + auto left = total_padding / 2; + return {left, total_padding - left}; +} + +inline std::pair pooling_same_mode_padding_lr( + int64_t inputSize, int64_t kernelSize, int64_t stride, int64_t dilation) { + return _pooling_same_mode_padding_lr(inputSize, kernelSize, stride, dilation); +} + +inline std::pair pooling_same_mode_padding_lr( + c10::SymInt inputSize, c10::SymInt kernelSize, c10::SymInt stride, c10::SymInt dilation) { + return _pooling_same_mode_padding_lr(std::move(inputSize), std::move(kernelSize), std::move(stride), std::move(dilation)); +} + +// AveragePool2d/DilatedMaxPool2d (forward) +inline void +pool2d_shape_check( + const Tensor& input, + int64_t kH, int64_t kW, int64_t dH, int64_t dW, int64_t padH, int64_t padW, int64_t dilationH, int64_t dilationW, + int64_t nInputPlane, + int64_t inputHeight, int64_t inputWidth, + int64_t outputHeight, int64_t outputWidth, MemoryFormat memory_format) +{ + const int64_t ndim = input.ndimension(); +#ifndef STRIP_ERROR_MESSAGES + const int64_t nOutputPlane = nInputPlane; +#endif + + TORCH_CHECK(kW > 0 && kH > 0, + "kernel size should be greater than zero, but got ", + "kH: ", kH, " kW: ", kW); + TORCH_CHECK(dW > 0 && dH > 0, + "stride should be greater than zero, but got " + "dH: ", dH, " dW: ", dW); + TORCH_CHECK(dilationH > 0 && dilationW > 0, + "dilation should be greater than zero, but got ", + "dilationH: ", dilationH, " dilationW: ", dilationW); + + bool valid_dims = input.size(1) != 0 && input.size(2) != 0; + if (memory_format == at::MemoryFormat::ChannelsLast){ + // Expect tensor in NHWC format and allow 0-dim only for N. + TORCH_CHECK((ndim == 4 && valid_dims && input.size(3) != 0), + "Expected 4D (batch mode) tensor expected for input with channels_last layout" + " with optional 0 dim batch size for input, but got: ", input.sizes()); + } else { + TORCH_CHECK((ndim == 3 && input.size(0) != 0 && valid_dims) || + (ndim == 4 && valid_dims && input.size(3) != 0), + "Expected 3D or 4D (batch mode) tensor with optional 0 dim batch size for input, but got:", + input.sizes()); + } + + TORCH_CHECK(kW/2 >= padW && kH/2 >= padH, + "pad should be smaller than or equal to half of kernel size, but got ", + "padW = ", padW, ", padH = ", padH, ", kW = ", kW, ", kH = ", kH); + + TORCH_CHECK(outputWidth >= 1 && outputHeight >= 1, + "Given input size: (", + nInputPlane, "x", inputHeight, "x", inputWidth, "). ", + "Calculated output size: (", + nOutputPlane, "x", outputHeight, "x", outputWidth, "). ", + "Output size is too small"); +} + +// DilatedMaxPool2d (backward) +inline void +max_pool2d_backward_shape_check( + const Tensor& input, + const Tensor& gradOutput, + const Tensor& indices, + int kH, int kW, int dH, int dW, int padH, int padW, int dilationH, int dilationW, + int64_t nInputPlane, + int64_t inputHeight, int64_t inputWidth, + int64_t outputHeight, int64_t outputWidth, MemoryFormat memory_format) +{ + pool2d_shape_check( + input, + kH, kW, dH, dW, padH, padW, dilationH, dilationW, + nInputPlane, inputHeight, inputWidth, outputHeight, outputWidth, memory_format); + + const int64_t ndim = input.ndimension(); + const int64_t nOutputPlane = nInputPlane; + + check_dim_size(gradOutput, ndim, ndim-3, nOutputPlane); + check_dim_size(gradOutput, ndim, ndim-2, outputHeight); + check_dim_size(gradOutput, ndim, ndim-1, outputWidth); + + check_dim_size(indices, ndim, ndim-3, nOutputPlane); + check_dim_size(indices, ndim, ndim-2, outputHeight); + check_dim_size(indices, ndim, ndim-1, outputWidth); + + if (ndim == 4) { + const int64_t batchSize = input.size(0); + check_dim_size(gradOutput, ndim, 0, batchSize); + check_dim_size(indices, ndim, 0, batchSize); + } +} + +// AveragePool2d (backward) +inline void +avg_pool2d_backward_shape_check( + const Tensor& input, + const Tensor& gradOutput, + int64_t /*nbatch*/, + int kH, int kW, int dH, int dW, int padH, int padW, + int64_t nInputPlane, + int64_t inputHeight, int64_t inputWidth, + int64_t outputHeight, int64_t outputWidth, + MemoryFormat memory_format) +{ + pool2d_shape_check( + input, + kH, kW, dH, dW, padH, padW, 1, 1, + nInputPlane, inputHeight, inputWidth, outputHeight, outputWidth, + memory_format); + + const int64_t ndim = input.ndimension(); + const int64_t nOutputPlane = nInputPlane; + + check_dim_size(gradOutput, ndim, ndim-3, nOutputPlane); + check_dim_size(gradOutput, ndim, ndim-2, outputHeight); + check_dim_size(gradOutput, ndim, ndim-1, outputWidth); +} + +// AveragePool3d/DilatedMaxPool3d (forward) +inline void +pool3d_shape_check( + const Tensor& input, + int64_t nslices, + int kT, int kH, int kW, + int dT, int dH, int dW, + int pT, int pH, int pW, + int dilationT, int dilationH, int dilationW, + int64_t itime, int64_t iheight, int64_t iwidth, + int64_t otime, int64_t oheight, int64_t owidth, + const char *fn_name, + bool check_input_size=false) +{ + const int64_t ndim = input.ndimension(); + + TORCH_CHECK(kT > 0 && kW > 0 && kH > 0, + "kernel size should be greater than zero, but got ", + "kT: ", kT, " kH: ", kH, " kW: ", kW); + TORCH_CHECK(dT > 0 && dW > 0 && dH > 0, + "stride should be greater than zero, but got ", + "dT: ", dT, " dH: ", dH, " dW: ", dW); + TORCH_CHECK(dilationT > 0 && dilationW > 0 && dilationH > 0, + "dilation should be greater than zero, but got ", + "dilationT: ", dilationT, " dilationH: ", dilationH, " dilationW: ", dilationW); + + TORCH_CHECK(ndim == 4 || ndim == 5, + fn_name, ": Expected 4D or 5D tensor for input, but got: ", input.sizes()); + + for (const auto i : c10::irange(ndim)) { + if (ndim == 5 && i == 0) { + // size of batch-dim can be 0. + continue; + } + TORCH_CHECK( + input.size(i) > 0, + fn_name, + ": Expected input's non-batch dimensions to have positive length," + " but input has a shape of ", + input.sizes(), + " and non-batch dimension ", + input.size(i), + " has length zero!") + } + + if (check_input_size) { // AveragePool3d + TORCH_CHECK(itime >= kT && iheight >= kH && iwidth >= kW, + "input image ", "(T: ", itime, " H: ", iheight, " W: ", iwidth, ") smaller than ", + "kernel size ", "(kT: ", kT, " kH: ", kH, " kW: ", kW, ")"); + } + + TORCH_CHECK(kT/2 >= pT && kW/2 >= pW && kH/2 >= pH, + "pad should be smaller than or equal to half of kernel size, but got " + "kT: ", kT, " kW: ", kW, " kH: ", kH, " padT: ", pT, " padW: ", pW, " padH: ", pH); + + TORCH_CHECK(otime >= 1 && owidth >= 1 && oheight >= 1, + "Given input size: (", + nslices,"x", itime, "x", iheight, "x", iwidth, "). ", + "Calculated output size: (", + nslices, "x", otime, "x", oheight, "x", owidth, "). ", + "Output size is too small"); +} + +inline void +max_pool3d_backward_shape_check( + const Tensor& input, + const Tensor& gradOutput, + const Tensor& indices, + int64_t nslices, + int kT, int kH, int kW, + int dT, int dH, int dW, + int pT, int pH, int pW, + int dilationT, int dilationH, int dilationW, + int64_t itime, int64_t iheight, int64_t iwidth, + int64_t otime, int64_t oheight, int64_t owidth, + const char* fn_name) +{ + const int64_t ndim = input.ndimension(); + + pool3d_shape_check( + input, + nslices, + kT, kH, kW, + dT, dH, dW, + pT, pH, pW, + dilationT, dilationH, dilationW, + itime, iheight, iwidth, + otime, oheight, owidth, fn_name); + + check_dim_size(gradOutput, ndim, ndim-4, nslices); + check_dim_size(gradOutput, ndim, ndim-3, otime); + check_dim_size(gradOutput, ndim, ndim-2, oheight); + check_dim_size(gradOutput, ndim, ndim-1, owidth); + + check_dim_size(indices, ndim, ndim-4, nslices); + check_dim_size(indices, ndim, ndim-3, otime); + check_dim_size(indices, ndim, ndim-2, oheight); + check_dim_size(indices, ndim, ndim-1, owidth); +} + +inline void +avg_pool3d_backward_shape_check( + const Tensor& input, + const Tensor& gradOutput, + int64_t nslices, + int kT, int kH, int kW, + int dT, int dH, int dW, + int pT, int pH, int pW, + int64_t itime, int64_t iheight, int64_t iwidth, + int64_t otime, int64_t oheight, int64_t owidth, + const char *fn_name) +{ + const int64_t ndim = input.ndimension(); + + pool3d_shape_check( + input, + nslices, + kT, kH, kW, + dT, dH, dW, + pT, pH, pW, + 1, 1, 1, + itime, iheight, iwidth, + otime, oheight, owidth, + fn_name, true); + + check_dim_size(gradOutput, ndim, ndim-4, nslices); + check_dim_size(gradOutput, ndim, ndim-3, otime); + check_dim_size(gradOutput, ndim, ndim-2, oheight); + check_dim_size(gradOutput, ndim, ndim-1, owidth); +} + +} // anonymous namespace + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Pow.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Pow.h new file mode 100644 index 0000000000000000000000000000000000000000..749ee41eb90a4edf69329f941218b7c8ff526e3b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Pow.h @@ -0,0 +1,69 @@ +#pragma once + +#include + +namespace c10 { +class Scalar; +} + +namespace at { + +struct TensorIterator; +struct TensorIteratorBase; + +namespace native { + +#if defined(__CUDACC__) || defined(__HIPCC__) +#define HOST_DEVICE __host__ __device__ +#else +#define HOST_DEVICE +#endif + +// integral power in pytorch allows for negative exponents, giving truncated integral results. +// e.g. since 2**-1==0.5, the truncated integral result is zero. 1**negative_exponent is the +// only non-zero result. +template , T>* = nullptr> +inline HOST_DEVICE __ubsan_ignore_signed_int_overflow__ T powi_impl(T a, T b) { + T result = 1; + while (b) { + if (b & 1) { + result *= a; + } + b /= 2; + a *= a; + } + return result; +} + +template && !std::is_signed_v, T>* = nullptr> +inline HOST_DEVICE T powi(T a, T b) { + return powi_impl(a, b); +} + +template && std::is_signed_v, T>* = nullptr> +inline HOST_DEVICE T powi(T a, T b) { + if ( b < 0 ) { + if ( a == 1 ) { + return 1; + } else if ( a == -1 ) { + auto negative = (-b) % static_cast(2); + return negative ? -1 : 1; + } else { + return 0; + } + } + return powi_impl(a, b); +} + +using pow_tensor_tensor_fn = void (*)(TensorIteratorBase&); +using pow_tensor_scalar_fn = void (*)(TensorIteratorBase&, const c10::Scalar&); + +DECLARE_DISPATCH(pow_tensor_tensor_fn, pow_tensor_tensor_stub) +DECLARE_DISPATCH(pow_tensor_scalar_fn, pow_tensor_scalar_stub) + +} // namespace native + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/RNN.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/RNN.h new file mode 100644 index 0000000000000000000000000000000000000000..afebf06a0fba3cd1c1a2acab0384e3cdcb4967de --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/RNN.h @@ -0,0 +1,53 @@ +#pragma once + +#include +#include + +namespace at::native { + +using lstm_fn = void(*)(Tensor&, Tensor&, Tensor&, const Tensor&, TensorList, TensorList, bool, int64_t, double, bool, bool, bool); +using rnn_fn = void(*)(Tensor&, Tensor&, const Tensor&, const Tensor&, TensorList, bool, int64_t, double, bool, bool, bool); +using lstm_packed_fn = void(*)(Tensor&, Tensor&, Tensor&, const Tensor&, const Tensor&, TensorList, TensorList, bool, int64_t, double, bool, bool); +using rnn_packed_fn = void(*)(Tensor&, Tensor&, const Tensor&, const Tensor&, const Tensor&, TensorList, bool, int64_t, double, bool, bool); + +DECLARE_DISPATCH(lstm_fn, lstm_cudnn_stub) +DECLARE_DISPATCH(lstm_fn, lstm_miopen_stub) +DECLARE_DISPATCH(lstm_fn, lstm_mkldnn_stub) +DECLARE_DISPATCH(rnn_fn, gru_cudnn_stub) +DECLARE_DISPATCH(rnn_fn, gru_miopen_stub) +DECLARE_DISPATCH(rnn_fn, rnn_tanh_cudnn_stub) +DECLARE_DISPATCH(rnn_fn, rnn_tanh_miopen_stub) +DECLARE_DISPATCH(rnn_fn, rnn_relu_cudnn_stub) +DECLARE_DISPATCH(rnn_fn, rnn_relu_miopen_stub) +DECLARE_DISPATCH(lstm_packed_fn, lstm_packed_cudnn_stub) +DECLARE_DISPATCH(lstm_packed_fn, lstm_packed_miopen_stub) +DECLARE_DISPATCH(rnn_packed_fn, gru_packed_cudnn_stub) +DECLARE_DISPATCH(rnn_packed_fn, gru_packed_miopen_stub) +DECLARE_DISPATCH(rnn_packed_fn, rnn_tanh_packed_cudnn_stub) +DECLARE_DISPATCH(rnn_packed_fn, rnn_tanh_packed_miopen_stub) +DECLARE_DISPATCH(rnn_packed_fn, rnn_relu_packed_cudnn_stub) +DECLARE_DISPATCH(rnn_packed_fn, rnn_relu_packed_miopen_stub) + +inline void check_attributes(const Tensor& input, const TensorList& params, const TensorList& hiddens, bool check_dtype=false) { + auto input_device = input.device(); + auto input_dtype = input.scalar_type(); + + auto check_tensors = [&](const std::string& name, const Tensor& t) { + if (!t.defined()) return; + auto t_device = t.device(); + TORCH_CHECK(input_device == t_device, + "Input and ", name, " tensors are not at the same device, found input tensor at ", + input_device, " and ", name, " tensor at ", t_device); + if (check_dtype) { + auto t_dtype = t.scalar_type(); + TORCH_CHECK(input_dtype == t_dtype, + "Input and ", name, " tensors are not the same dtype, found input tensor with ", + input_dtype, " and ", name, " tensor with ", t_dtype); + } + }; + + for (const auto& h : hiddens) check_tensors("hidden", h); + for (const auto& p : params) check_tensors("parameter", p); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/RangeFactories.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/RangeFactories.h new file mode 100644 index 0000000000000000000000000000000000000000..b3a4769d4f411f420086dcbedf533699496f7358 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/RangeFactories.h @@ -0,0 +1,12 @@ +#include +#include + +namespace at { +struct TensorIterator; + +namespace native { + +DECLARE_DISPATCH(void(*)(TensorIterator&, const Scalar&, const Scalar&, const Scalar&), arange_stub) +DECLARE_DISPATCH(void(*)(TensorIterator&, const Scalar&, const Scalar&, int64_t), linspace_stub) + +}} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/RangeUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/RangeUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..d1756db75016d2774c5a4844f9780090a1a149dd --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/RangeUtils.h @@ -0,0 +1,45 @@ +#include +#include +#include + +namespace at { + +namespace native { + +template +int64_t compute_arange_size(const Scalar& start, const Scalar& end, const Scalar& step) { + using accscalar_t = at::acc_type; + auto xstart = start.to(); + auto xend = end.to(); + auto xstep = step.to(); + + TORCH_CHECK(xstep > 0 || xstep < 0, "step must be nonzero"); + TORCH_CHECK(std::isfinite(static_cast(xstart)) && + std::isfinite(static_cast(xend)), + "unsupported range: ", xstart, " -> ", xend); + TORCH_CHECK(((xstep > 0) && (xend >= xstart)) || ((xstep < 0) && (xend <= xstart)), + "upper bound and larger bound inconsistent with step sign"); + + // we use double precision for (start - end) / step + // to compute size_d for consistency across devices. + // The problem with using accscalar_t is that accscalar_t might be float32 on gpu for a float32 scalar_t, + // but double on cpu for the same, + // and the effective output size starts differing on CPU vs GPU because of precision issues, which + // we dont want. + // the corner-case we do want to take into account is int64_t, which has higher precision than double + double size_d; + if constexpr (std::is_same_v) { + int64_t sgn = (xstep > 0) - (xstep < 0); + size_d = std::ceil((xend - xstart + xstep - sgn) / xstep); + } else { + size_d = std::ceil(static_cast(end.to() - start.to()) + / step.to()); + } + + TORCH_CHECK(size_d >= 0 && size_d <= static_cast(std::numeric_limits::max()), + "invalid size, possible overflow?"); + + return static_cast(size_d); +} + +}} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReduceAllOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReduceAllOps.h new file mode 100644 index 0000000000000000000000000000000000000000..a57d138e15511407ca7fa7d117400bf8436fe133 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReduceAllOps.h @@ -0,0 +1,16 @@ +#pragma once + +#include + +namespace at { +class Tensor; +} + +namespace at::native { + +using reduce_all_fn = void (*)(Tensor & result, const Tensor & self); +using reduce_min_max_fn = void (*)(Tensor & max_result, Tensor & min_result, const Tensor & self); +DECLARE_DISPATCH(reduce_all_fn, min_all_stub) +DECLARE_DISPATCH(reduce_all_fn, max_all_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReduceOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReduceOps.h new file mode 100644 index 0000000000000000000000000000000000000000..7b59def19bdd800105dc25b4dfb0f0f4021a11a3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReduceOps.h @@ -0,0 +1,56 @@ +#pragma once + +#include +#include +#include + +namespace c10 { +class Scalar; +} + +namespace at { +struct TensorIterator; +class Tensor; +} + +namespace at::native { + +using reduce_fn = void(*)(TensorIterator &); + +DECLARE_DISPATCH(reduce_fn, sum_stub) +DECLARE_DISPATCH(reduce_fn, nansum_stub) +DECLARE_DISPATCH(reduce_fn, prod_stub) +DECLARE_DISPATCH(reduce_fn, mean_stub) +DECLARE_DISPATCH(reduce_fn, and_stub) +DECLARE_DISPATCH(reduce_fn, or_stub) +DECLARE_DISPATCH(reduce_fn, min_values_stub) +DECLARE_DISPATCH(reduce_fn, max_values_stub) +DECLARE_DISPATCH(reduce_fn, argmax_stub) +DECLARE_DISPATCH(reduce_fn, argmin_stub) + +using reduce_std_var_function = + void (*)(TensorIterator&, double correction, bool take_sqrt); +DECLARE_DISPATCH(reduce_std_var_function, std_var_stub) + +using reduce_norm_fn = + void (*)(Tensor&, const Tensor&, const c10::Scalar&, std::optional); +DECLARE_DISPATCH(reduce_norm_fn, norm_kernel) + +using reduce_fn_flag = void(*)(TensorIterator &, const c10::Scalar&); +DECLARE_DISPATCH(reduce_fn_flag, norm_stub) + +using structured_cum_fn = void (*)(const Tensor&, const Tensor&, int64_t); +using cum_fn = void (*)(Tensor&, const Tensor&, int64_t); +DECLARE_DISPATCH(structured_cum_fn, cumsum_stub) +DECLARE_DISPATCH(structured_cum_fn, cumprod_stub) +DECLARE_DISPATCH(cum_fn, logcumsumexp_stub) + +DECLARE_DISPATCH(void (*)(const Tensor&, int64_t, bool, Tensor&, Tensor&), aminmax_stub) +DECLARE_DISPATCH(void (*)(const Tensor&, Tensor&, Tensor&), aminmax_allreduce_stub) + +// Used in cuda/Normalization.cu +TORCH_API std::tuple var_mean_out( + Tensor &result1, Tensor &result2, const Tensor &self, IntArrayRef dim, + int64_t correction, bool keepdim); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReduceOpsUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReduceOpsUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..d5e49fe7c3f582c990af67ec2fe7cc063e4c4e67 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReduceOpsUtils.h @@ -0,0 +1,468 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#include +#endif + +namespace at::native { + +// Maximum and minimum possible scalar values, including infinities +template +constexpr scalar_t upper_bound() { + using lim = std::numeric_limits; + return lim::has_infinity ? lim::infinity() : lim::max(); +} + +template +constexpr scalar_t lower_bound() { + using lim = std::numeric_limits; + return lim::has_infinity ? -lim::infinity() : lim::lowest(); +} + +inline Tensor restride_dim( + const Tensor& src, int64_t dim, + IntArrayRef replacement_shape +) { + auto strides = ensure_nonempty_vec(src.strides().vec()); + strides[dim] = 0; + return src.as_strided(replacement_shape, strides); +} + +inline void _dimreduce_setup(const Tensor &result, const Tensor &self, + int64_t dim) { + IntArrayRef self_sizes = self.sizes(); + std::vector result_sizes; + result_sizes.insert(result_sizes.end(), self_sizes.begin(), self_sizes.end()); + result_sizes[dim] = 1; + result.resize_(result_sizes); +} + +inline bool _dimreduce_return_trivial(const Tensor &result, const Tensor &self, + const Scalar& ident, int64_t dim, bool keepdim) { + if (self.numel() == 1 && self.ndimension() == 0) { + result.resize_({}); + result.fill_(self); + return true; + } + // Return identity + if (self.numel() == 0) { + _dimreduce_setup(result, self, dim); + result.fill_(ident); + if (!keepdim) result.squeeze_(dim); + return true; + } + return false; +} + +inline bool _dimreduce_return_trivial_no_ident(Tensor &result, const Tensor &self, + int64_t /*dim*/, bool /*keepdim*/, const char* /*fn_name*/) { + if (self.numel() == 1 && self.ndimension() == 0) { + result.resize_({}); + result.fill_(self); + return true; + } + + return false; +} + +inline std::optional _allreduce_return_trivial( + const Tensor& self, + const Scalar& ident) { + // Return identity + if (self.numel() == 0) { + return at::scalar_tensor(ident, self.options()); + } + return std::nullopt; +} + +#define OPTION_TYPE_EQUALITY_CHECK(option, out, self) \ +{ \ + TORCH_CHECK(\ + out.option() == self.option(),\ + "expected ", #option, " ",\ + self.option(),\ + " but found ", out.option())\ +} + +inline void check_scalar_type_device_layout_equal(const Tensor& out, const Tensor& self) { + OPTION_TYPE_EQUALITY_CHECK(scalar_type, out, self); + OPTION_TYPE_EQUALITY_CHECK(device, out.options(), self.options()); + OPTION_TYPE_EQUALITY_CHECK(layout, out.options(), self.options()); +} + +inline Tensor integer_upcast(const Tensor& self, std::optional dtype) { + ScalarType scalarType = self.scalar_type(); + TORCH_CHECK(!isBarebonesUnsignedType(scalarType), "integer upcasting for uint16, uint32 and uint64 is not currently implemented"); + ScalarType upcast_scalarType = dtype.value_or(at::isIntegralType(scalarType, /*includeBool=*/true) ? ScalarType::Long : scalarType); + return self.toType(upcast_scalarType); +} + +using DimMask = TensorIterator::DimMask; + +inline DimVector make_dim_vector(OptionalIntArrayRef opt_dims, int64_t ndim) { + if (opt_dims.has_value()) { + return DimVector(opt_dims.value()); + } else { + std::vector all_dims(ndim); + std::iota(all_dims.begin(), all_dims.end(), 0); + return DimVector(all_dims); + } +} + +inline DimMask make_dim_mask(OptionalIntArrayRef opt_dims, int64_t ndim, bool allow_empty_dims=false) { + DimMask mask; + if (opt_dims.has_value()) { + auto dims = opt_dims.value(); + if (dims.empty() && !allow_empty_dims) { + mask = DimMask().flip(); + } else { + mask = at::dim_list_to_bitset(dims, ndim); + } + } else { + mask = DimMask().flip(); + } + return mask; +} + +inline DimVector shape_from_dim_mask(const Tensor& self, DimMask mask, bool keepdim) { + auto shape = DimVector(self.sizes()); + for (int dim = shape.size() - 1; dim >= 0; dim--) { + if (mask[dim]) { + if (keepdim) { + shape[dim] = 1; + } else { + shape.erase(shape.begin() + dim); + } + } + } + return shape; +} + +inline void resize_reduction_result( + Tensor& result, const Tensor& self, DimMask mask, bool keepdim, + ScalarType /*dtype*/) +{ + auto shape = shape_from_dim_mask(self, mask, keepdim); + TORCH_CHECK(result.defined(), "Cannot create a new tensor inside a reduction op. You likely tried to call an operator with an out argument but the out argument was an undefined tensor."); + at::native::resize_output(result, shape); +} + +inline Tensor create_reduction_result( + const Tensor& self, at::OptionalIntArrayRef dim, bool keepdim, ScalarType dtype +) { + DimMask mask = make_dim_mask(dim, self.dim()); + auto shape = shape_from_dim_mask(self, mask, keepdim); + return at::empty(shape, self.options().dtype(dtype)); +} + +inline Tensor review_reduce_result(const Tensor& result, int ndim, DimMask mask, bool keepdim) { + if (keepdim) { + return result; + } + auto shape = DimVector(result.sizes()); + auto stride = DimVector(result.strides()); + for (const auto dim : c10::irange(ndim)) { + if (mask[dim]) { + shape.insert(shape.begin() + dim, 1); + stride.insert(stride.begin() + dim, 0); + } + } + return result.as_strided(shape, stride); +} + +inline TensorIterator make_reduction( + const char* name, Tensor& result, const Tensor& self, + at::OptionalIntArrayRef dim_opt, + bool keepdim, ScalarType in_dtype, ScalarType out_dtype) { + // check that result type and dtype match if provided + TORCH_CHECK( + !result.defined() || result.scalar_type() == out_dtype, + name, ": provided dtype must match dtype of result. Got ", + toString(result.scalar_type()), + " and ", + toString(out_dtype), + "."); + // dim={} performs an all-reduce, same as dim=None + IntArrayRef dim = dim_opt.value_or(IntArrayRef{}); + int64_t ndim = self.dim(); + auto mask = make_dim_mask(dim, ndim); + resize_reduction_result(result, self, mask, keepdim, out_dtype); + auto viewed_result = review_reduce_result(result, ndim, mask, keepdim); + namedinference::propagate_names_for_reduction(result, self, dim, keepdim); + if (self.scalar_type() == in_dtype) { + return TensorIterator::reduce_op(viewed_result, self); + } + return TensorIterator::reduce_op(viewed_result, self.to(in_dtype)); +} + +[[maybe_unused]] inline TensorIterator make_reduction( + const char* name, + Tensor& result, + const Tensor& self, + at::OptionalIntArrayRef dim, + bool keepdim, + ScalarType out_dtype) { + // special case for type promotion in mixed precision, improves computational + // efficiency. + // not generalize this to common mismatched input/output types to avoid cross + // product of templated kernel launches. + const bool gpu_lowp_to_f32 = ( + (self.is_cuda() || self.is_xpu()) && (self.scalar_type() == kHalf || self.scalar_type() == kBFloat16) && out_dtype == kFloat); + auto in_dtype = gpu_lowp_to_f32 ? self.scalar_type() + : self.is_complex() ? c10::toComplexType(out_dtype) + : out_dtype; + return make_reduction(name, result, self, dim, keepdim, in_dtype, out_dtype); +} + +inline TensorIterator make_reduction( + const char* name, Tensor& result1, Tensor& result2, const Tensor& self, + at::OptionalIntArrayRef dim_opt, bool keepdim, ScalarType dtype1, + ScalarType dtype2) { + // check that result type and dtype match if provided + TORCH_CHECK( + (!result1.defined() || result1.scalar_type() == dtype1) && (!result2.defined() || result2.scalar_type() == dtype2), + name, ": provided dtype must match dtype of result. Got ", + toString(result1.scalar_type()), toString(result2.scalar_type()), + " and ", + toString(dtype1), toString(dtype2), + "."); + + // dim={} performs an all-reduce, same as dim=None + auto dim = dim_opt.value_or(IntArrayRef{}); + int64_t ndim = self.dim(); + DimMask mask = make_dim_mask(dim, ndim); + resize_reduction_result(result1, self, mask, keepdim, dtype1); + auto viewed_result1 = review_reduce_result(result1, ndim, mask, keepdim); + + resize_reduction_result(result2, self, mask, keepdim, dtype2); + auto viewed_result2 = review_reduce_result(result2, ndim, mask, keepdim); + + namedinference::propagate_names_for_reduction(result1, self, dim, keepdim); + namedinference::propagate_names_for_reduction(result2, self, dim, keepdim); + + // special case for type promotion in mixed precision, improves computational + // efficiency. + // We don't generalize this to common mismatched input/output types to avoid cross + // product of templated kernel launches. + if (self.scalar_type() == dtype1 || + (self.is_cuda() && self.scalar_type() == kHalf && dtype1 == kFloat)) { + return TensorIterator::reduce_op(viewed_result1, viewed_result2, self); + } + return TensorIterator::reduce_op(viewed_result1, viewed_result2, self.to(dtype1)); +} + +[[maybe_unused]] inline TensorIterator make_reduction( + const char* name, + Tensor& result1, + Tensor& result2, + const Tensor& self, + at::OptionalIntArrayRef dim, + bool keepdim, + ScalarType dtype) { + return make_reduction(name, result1, result2, self, dim, keepdim, dtype, dtype); +} + +inline void zero_numel_check_dims(const Tensor& self, const int64_t dim, const char *fn_name) { + if (self.ndimension() == 0) { + TORCH_CHECK_INDEX(dim == 0 || dim == -1, fn_name, + ": Expected reduction dim -1 or 0 for scalar but got ", dim); + } + else { + TORCH_CHECK_INDEX(self.size(dim) != 0, fn_name, + ": Expected reduction dim ", dim, " to have non-zero size."); + } +} + +inline void zero_numel_check_dims(const Tensor& self, const IntArrayRef dim, const char *fn_name) { + TORCH_CHECK( + !dim.empty(), + fn_name, ": Expected reduction dim to be specified for input.numel() == 0. ", + "Specify the reduction dim with the 'dim' argument."); + for (const int64_t d : dim) { + zero_numel_check_dims(self, d, fn_name); + } +} + +inline std::vector get_zero_numel_tensor_size( + const Tensor& self, + const int64_t dim, + const bool keepdim, + const char* fn_name) { + TORCH_INTERNAL_ASSERT(self.numel() == 0, fn_name, ": Expected self.numel() == 0."); + zero_numel_check_dims(self, dim, fn_name); + std::vector sizes; + if (keepdim) { + sizes = self.sizes().vec(); + sizes[dim] = 1; + } + else { + for (const auto d : c10::irange(self.dim())) { + if (d != dim) { + sizes.push_back(self.sizes()[d]); + } + } + } + return sizes; +} + +// Resize the result tensor and indices when result.numel() == 0 depending on values of +// dim and keepdim for returning tensors containing reduction results. +// This function should be called when you are reducing a zero-numel tensor and want to +// resize the output and return it. This function exists for resizing zero-numel +// tensors when the size of the reduction dimension is non-zero. +[[maybe_unused]] inline void zero_numel_tensor_resize( + Tensor& result, + Tensor& result_indices, + const Tensor& self, + const int64_t dim, + const bool keepdim, + const char* fn_name) { + auto sizes = get_zero_numel_tensor_size(self, dim, keepdim, fn_name); + at::native::resize_output(result, sizes); + at::native::resize_output(result_indices, sizes); +} + +inline ScalarType get_dtype_from_self( + const Tensor& self, + const std::optional& dtype, + bool promote_integers) { + if (dtype.has_value()) { + return dtype.value(); + } + ScalarType src_type = self.scalar_type(); + if (promote_integers && at::isIntegralType(src_type, /*includeBool=*/true)) { + return kLong; + } + return src_type; +} + +inline ScalarType get_dtype_from_result(Tensor& result, std::optional dtype) { + TORCH_CHECK(result.defined(), "Cannot create a new tensor inside a reduction op. You likely tried to call an operator with an out argument but the out argument was an undefined tensor."); + if (dtype.has_value()) { + return dtype.value(); + } else { + return result.scalar_type(); + } +} + + +} // namespace at::native + +namespace at::meta { + +[[maybe_unused]] inline DimVector get_reduction_shape( + const Tensor& self, + IntArrayRef dims, + bool keepdim, + bool allow_empty_dims = false) { + auto mask = native::make_dim_mask(dims, self.dim(), allow_empty_dims); + return native::shape_from_dim_mask(self, mask, keepdim); +} + +inline void resize_reduction( + impl::MetaBase& meta, + const Tensor& self, + OptionalIntArrayRef opt_dims, + bool keepdim, + ScalarType out_dtype, + bool allow_empty_dims=false) { + DimVector dims_ = at::native::make_dim_vector(opt_dims, self.dim()); + maybe_wrap_dims(dims_, self.dim()); + auto shape = get_reduction_shape(self, dims_, keepdim, allow_empty_dims); + if (self.layout() == kStrided) { + meta.set_output_raw_strided(0, shape, {}, self.options().dtype(out_dtype)); + } else if (shape.empty()) { + meta.set_output_raw_strided(0, shape, {}, self.options().dtype(out_dtype).layout(kStrided)); + } else { + TORCH_CHECK(false, "resize_reduction: support for output with ", self.layout(), " layout is not implemented yet"); + } + namedinference::propagate_names_for_reduction( + meta.maybe_get_output(), self, dims_, keepdim); +} + +inline void resize_reduction_with_indices( + impl::MetaBase& meta, + const Tensor& self, + IntArrayRef dims, + bool keepdim, + ScalarType out_dtype) { + DimVector dims_(dims); + maybe_wrap_dims(dims_, self.dim()); + auto shape = get_reduction_shape(self, dims_, keepdim); + meta.set_output_raw_strided(0, shape, {}, self.options().dtype(out_dtype)); + meta.set_output_raw_strided(1, shape, {}, self.options().dtype(kLong)); + namedinference::propagate_names_for_reduction( + meta.maybe_get_output(0), self, dims_, keepdim); + namedinference::propagate_names_for_reduction( + meta.maybe_get_output(1), self, dims_, keepdim); +} + +inline TensorIterator make_reduction( + const Tensor& self, + const Tensor& result, + OptionalIntArrayRef opt_dims, + bool keepdim, + ScalarType in_dtype) { + int64_t ndim = self.dim(); + auto mask = at::native::make_dim_mask(opt_dims, ndim); + auto viewed_result = + at::native::review_reduce_result(result, ndim, mask, keepdim); + if (self.scalar_type() == in_dtype) { + return TensorIterator::reduce_op(viewed_result, self); + } + return TensorIterator::reduce_op(viewed_result, self.to(in_dtype)); +} + +inline TensorIterator make_reduction( + const Tensor& self, + const Tensor& result1, + const Tensor& result2, + IntArrayRef dims, + bool keepdim, + ScalarType dtype1, + ScalarType /*dtype2*/) { + int64_t ndim = self.dim(); + auto mask = at::native::make_dim_mask(dims, ndim); + auto viewed_result1 = at::native::review_reduce_result(result1, ndim, mask, keepdim); + auto viewed_result2 = at::native::review_reduce_result(result2, ndim, mask, keepdim); + // special case for type promotion in mixed precision, improves computational efficiency. + // We don't generalize this to common mismatched input/output types to avoid cross product + // of templated kernel launches. + if (self.scalar_type() == dtype1 || + (self.is_cuda() && self.scalar_type() == kHalf && dtype1 == kFloat)) { + return TensorIterator::reduce_op(viewed_result1, viewed_result2, self); + } + return TensorIterator::reduce_op(viewed_result1, viewed_result2, self.to(dtype1)); +} + +[[maybe_unused]] inline TensorIterator make_reduction_from_out_ty( + const Tensor& self, + const Tensor& result, + OptionalIntArrayRef opt_dims, + bool keepdim, + ScalarType out_dtype) { + // special case for type promotion in mixed precision, improves computational + // efficiency. + // not generalize this to common mismatched input/output types to avoid cross + // product of templated kernel launches. + const bool gpu_lowp_to_f32 = + (self.is_cuda() && + (self.scalar_type() == kHalf || self.scalar_type() == kBFloat16) && + out_dtype == kFloat); + auto in_dtype = gpu_lowp_to_f32 ? self.scalar_type() : out_dtype; + return make_reduction(self, result, opt_dims, keepdim, in_dtype); +} + +} // namespace at::meta diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReductionType.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReductionType.h new file mode 100644 index 0000000000000000000000000000000000000000..48ecf5e83d4ead792de475964e306627149826b5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ReductionType.h @@ -0,0 +1,40 @@ +#pragma once + +#include + +namespace at::native { + +enum class ReductionType {MAX, MEAN, MIN, SUM, PROD}; + +inline ReductionType get_reduction_enum(const std::string_view& reduce) { + if (reduce == "max" || reduce == "amax") { + return ReductionType::MAX; + } else if (reduce == "mean") { + return ReductionType::MEAN; + } else if (reduce == "min" || reduce == "amin") { + return ReductionType::MIN; + } else if (reduce == "sum") { + return ReductionType::SUM; + } else if (reduce == "prod") { + return ReductionType::PROD; + } else { + TORCH_CHECK(false, "reduce argument must be either sum, prod, mean, amax or amin, got ", reduce); + } +} + +// used for `scatter_reduce`, old options for BC. +inline ReductionType get_operator_enum(const std::string_view reduce, bool use_new_options) { + if (use_new_options) { + return get_reduction_enum(reduce); + } else { + if (reduce == "add") { + return ReductionType::SUM; + } else if (reduce == "multiply") { + return ReductionType::PROD; + } else { + TORCH_CHECK(false, "reduce argument must be either add or multiply.") + } + } +} + +} // at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Repeat.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Repeat.h new file mode 100644 index 0000000000000000000000000000000000000000..b8d6f92553a4c9bde2f90574a23108fd9667a26c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Repeat.h @@ -0,0 +1,48 @@ +#pragma once + +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#include +#endif + +namespace at::native { + +template < + typename index_t, + void compute(const index_t*, const int64_t*, index_t*, int64_t, int64_t)> +static inline Tensor repeat_interleave_common( + const Tensor& repeats, + std::optional output_size) { + TORCH_CHECK( + repeats.dim() == 1, "repeat_interleave only accept 1D vector as repeat"); + TORCH_CHECK( + repeats.scalar_type() == at::kLong || repeats.scalar_type() == at::kInt, + "repeats has to be Long or Int tensor"); + if (repeats.size(0) == 0) { + return at::empty_like(repeats, LEGACY_CONTIGUOUS_MEMORY_FORMAT); + } + Tensor repeats_ = repeats.contiguous(); + Tensor cumsum = repeats.cumsum(0); + int64_t total = 0; + if (output_size.has_value()) { + total = output_size.value(); + } else { + total = cumsum[-1].item(); + TORCH_CHECK( + (repeats >= 0).all().item(), "repeats can not be negative"); + } + + Tensor result = at::empty({total}, repeats.options()); + const index_t* repeat_ptr = repeats_.const_data_ptr(); + const int64_t* cumsum_ptr = cumsum.const_data_ptr(); + index_t* result_ptr = result.data_ptr(); + compute(repeat_ptr, cumsum_ptr, result_ptr, repeats.size(0), total); + return result; +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Resize.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Resize.h new file mode 100644 index 0000000000000000000000000000000000000000..9111e4a080073719dd94952757629df6ff4356ba --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Resize.h @@ -0,0 +1,205 @@ +#pragma once + +#include +#include +#include +#include + +#include +#include + +#include + + +namespace at::native { + +// TODO: make all operations that resize given outputs use this function +// for consistency and maintainability. +// Some operations like `cat` might not be able to make the use of +// resize_output directly. For more details to understand how it works in `cat`, +// see https://github.com/pytorch/pytorch/pull/62560#discussion_r687363362 +// Resizes outputs +// Functions accepting output tensors, like with the "out" kwarg, should +// call this function to handle resizing their output tensor. +// Issues a warning if the output tensor has one or more elements and +// needs resizing +// NOTE: In the future the warning will become an error +// Returns a bool saying whether or not the resize actually happened or not +TORCH_API bool resize_output(const Tensor& output, IntArrayRef shape); +// WARNING: Do NOT call this directly. If you are resizing an output and want +// to support dynamic shapes call at::resize__symint and resize_output_check_symint. +// For more details, see: https://github.com/pytorch/pytorch/pull/111530/files#r1365845272 +TORCH_API bool resize_output_symint(const Tensor& output, SymIntArrayRef shape); + +// Utility for resize_output +// Returns a bool saying resize should happen or not and +// raises a warning if resizing for one or more elements +TORCH_API bool resize_output_check(const Tensor& output, IntArrayRef shape); +TORCH_API bool resize_output_check_symint(const Tensor& output, SymIntArrayRef shape); + +TORCH_API void resize_bytes_cpu(StorageImpl* storage, size_t size_bytes); +TORCH_API void resize_bytes_meta(StorageImpl* storage, c10::SymInt size_bytes); +TORCH_API void resize_bytes_nocuda(const Storage& storage, const c10::SymInt& size_bytes); + +inline void maybe_resize_storage_cpu(TensorImpl* self, size_t new_size_bytes) { + // It does not make sense to try to resize a storage + // to hold 0 elements, and this can break + // if storage_offset is positive but + // new_size is 0, so just bail in that case + // (same comment is in cuda/Resize.h) + if (self->numel() == 0) { + return; + } + + const Storage& storage = self->unsafe_storage(); + if (!storage) { + auto new_storage = c10::make_intrusive( + StorageImpl::use_byte_size_t(), + new_size_bytes, + c10::GetCPUAllocator(), + true); + self->set_storage_keep_dtype(std::move(new_storage)); + } else if (new_size_bytes > storage.nbytes()) { + resize_bytes_cpu(storage.unsafeGetStorageImpl(), new_size_bytes); + } +} + +TORCH_API TensorImpl* resize_impl_cpu_( + TensorImpl* self, + IntArrayRef size, + at::OptionalIntArrayRef stride, + bool resize_storage = true); + +template +T maybe_convert_symint(c10::SymInt) = delete; + +template <> +inline c10::SymInt maybe_convert_symint(c10::SymInt x) { return x; } + +template <> +inline int64_t maybe_convert_symint(c10::SymInt x) { return x.guard_int(__FILE__, __LINE__); } + +template +inline void checkInBoundsForStorage( + ArrayRef size, + ArrayRef stride, + T storage_offset, + const caffe2::TypeMeta& data_type, + const Storage& new_storage) { + T storage_size_bytes, storage_size_plus_offset_bytes; + if (stride.data()) { + storage_size_bytes = + at::detail::computeStorageNbytes(size, stride, data_type.itemsize()); + storage_size_plus_offset_bytes = at::detail::computeStorageNbytes( + size, stride, data_type.itemsize(), storage_offset); + } else { + storage_size_bytes = + at::detail::computeStorageNbytesContiguous(size, data_type.itemsize()); + storage_size_plus_offset_bytes = at::detail::computeStorageNbytesContiguous( + size, data_type.itemsize(), storage_offset); + } + // It's ok to always evaluate to False for this early return for SymInts because + // (1) maybe_convert_symint below only installs guard for int64_t case + // (2) we check for this condition in the TORCH_MAYBE_SYM_CHECK below + if (TORCH_GUARD_SIZE_OBLIVIOUS(sym_eq(storage_size_bytes, 0))) { + // NB: (a tensor with arbitrary 0 dims)'s storage can have any numel. + return; + } + T new_storage_size_bytes = maybe_convert_symint(new_storage.sym_nbytes()); + TORCH_MAYBE_SYM_CHECK( + sym_eq(storage_size_bytes, 0) || sym_le(storage_size_plus_offset_bytes, new_storage_size_bytes), + "setStorage: sizes ", + size, + ", strides ", + stride, + "," + " storage offset ", + storage_offset, + ", and itemsize ", + data_type.itemsize(), + " requiring a storage size of ", + storage_size_plus_offset_bytes, + " are out of bounds for storage of size ", + new_storage_size_bytes); +} + +template +inline void checkSetStorage(Tensor& result, Storage storage, T storage_offset, + ArrayRef size, ArrayRef stride, bool check_offset_in_bounds = true) { + // FIXME: stride should be optional + if (stride.data()) { + TORCH_CHECK(size.size() == stride.size(), "unequal size length (", size.size(), + ") and stride length (", stride.size(), ")"); + } + +#ifdef DEBUG + TORCH_CHECK(size.size() <= INT_MAX, "size length (", size.size(), ") greater than INT_MAX"); +#endif + + // storageOffset + TORCH_CHECK( + storage_offset >= 0, "Tensor: invalid storage offset ", storage_offset); + + // set_storage_{device} (except set_storage_meta__symint) + // will (unsafely) set the storage offset and then call resize_impl that + // handles resizing the storage However, resize_impl will only resize the + // storage if the sizes/strides changed. For the case that the sizes/strides + // remain unchanged, the storage offset is not properly validated, so we do + // that here. + if (check_offset_in_bounds) { + auto result_tensor_impl = result.unsafeGetTensorImpl(); + bool size_unchanged = result_tensor_impl->generic_sizes() == size; + bool stride_unchanged = stride.data() + ? result_tensor_impl->generic_strides() == stride + : true; + if (size_unchanged && stride_unchanged) { + checkInBoundsForStorage( + size, stride, storage_offset, result.dtype(), storage); + } + } + + // storage: note this can't be replaced with result.set_(storage) as the semantics of that + // function is to set the tensor size to be equal to the size of the storage. + if (!result.storage().is_alias_of(storage)) { + // Caffe2 might have tensors whose storages are null, but we + // don't allow it in PyTorch. + TORCH_INTERNAL_ASSERT(storage); + TORCH_INTERNAL_ASSERT(result.storage()); + + // We used to allow this, but this breaks device caching. + // Let's put an actual error message for this one. + TORCH_CHECK(result.storage().device() == storage.device(), + "Attempted to set the storage of a tensor on device \"", result.storage().device(), + "\" to a storage on different device \"", storage.device(), + "\". This is no longer allowed; the devices must match."); + result.unsafeGetTensorImpl()->set_storage_keep_dtype(std::move(storage)); + } +} + +/** + * Set self's sizes, strides, and storage_offset. + * (size, stride, storage_offset) must be in bounds for self's storage. + */ +template +inline void setStrided( + const Tensor& self, + ArrayRef size, + ArrayRef stride, + T storage_offset) { + TORCH_CHECK(size.size() == stride.size(), "mismatch in length of strides and shape"); + for (const auto& val : stride) { + TORCH_CHECK(val >= 0, + "as_strided: Negative strides are not supported at the moment, " + "got strides: ", stride); + } + + auto* self_ = self.unsafeGetTensorImpl(); + checkInBoundsForStorage( + size, stride, storage_offset, self_->dtype(), self_->storage()); + + /* storage offset */ + TORCH_CHECK(storage_offset >= 0, "Tensor: invalid storage offset ", storage_offset); + self_->set_sizes_and_strides(size, stride, storage_offset); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ResizeCommon.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ResizeCommon.h new file mode 100644 index 0000000000000000000000000000000000000000..cea2612a22127d00532da761cf8e773164db5ca4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ResizeCommon.h @@ -0,0 +1,75 @@ +#pragma once + +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + +namespace at::native { + +template +inline T storage_size_for(ArrayRef size, ArrayRef stride) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(size.size() == stride.size(), + "storage_size_for(size, stride) requires that size and stride ", + "have the same size as a precondition."); + T storage_size = 1; + for (const auto dim : c10::irange(size.size())) { + if (size[dim] == 0) { + storage_size = 0; + break; + } + storage_size += (size[dim] - 1) * stride[dim]; + } + return storage_size; +} + +inline const Tensor& resize_named_tensor_( + const Tensor& self, + IntArrayRef size, + std::optional optional_memory_format) { + TORCH_INTERNAL_ASSERT(self.has_names()); + TORCH_CHECK( + self.sizes() == size, + "Cannot resize named tensor with resize_ or resize_as_ (tried to resize " + "Tensor", + self.names(), + " with size ", + self.sizes(), + " to ", + size, + "). This may be caused by passing a named tensor ", + "as an `out=` argument; please ensure that the sizes are the same. "); + TORCH_CHECK( + !optional_memory_format.has_value(), + "Unsupported memory format for named tensor resize ", + optional_memory_format.value()); + return self; +} + +// For deterministic output, fill new elements that were added after a storage +// resize with NaN or MAX_INT. `old_storage_nbytes` is the size of the storage +// before the resize happened. +inline const Tensor& fill_resize_deterministic_(const Tensor& tensor, int64_t old_storage_nbytes) { + const at::Storage& storage = tensor.unsafeGetTensorImpl()->unsafe_storage(); + int64_t new_storage_nbytes = storage.nbytes(); + int64_t old_storage_numel = old_storage_nbytes / tensor.itemsize(); + int64_t new_storage_numel = new_storage_nbytes / tensor.itemsize(); + if (new_storage_numel > old_storage_numel) { + at::Tensor tensor_view = at::empty({}, at::TensorOptions().dtype(tensor.scalar_type()).device(tensor.device())); + tensor_view.set_( + storage, + /*storage_offset=*/old_storage_numel, + /*size=*/{new_storage_numel - old_storage_numel}, + /*stride=*/{1}); + at::native::fill_empty_deterministic_(tensor_view); + } + return tensor; +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ScatterGatherChecks.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ScatterGatherChecks.h new file mode 100644 index 0000000000000000000000000000000000000000..3a826a7a1b93006cc077e11ff582dddac4b64bdf --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/ScatterGatherChecks.h @@ -0,0 +1,128 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::native { + +namespace { + +// checks whether index.dtype == int64 +// and self.dtype == src.dtype if src is a Tensor +inline void scatter_gather_dtype_check( + const std::string& method_name, + const Tensor& self, + const Tensor& index, + const std::optional& src_opt = std::nullopt +) { + if (index.numel() != 0) { + TORCH_CHECK( + index.scalar_type() == at::ScalarType::Long, + method_name, "(): Expected dtype int64 for index" + ); + } + + if (src_opt.has_value()) { + const auto& src = src_opt.value(); + TORCH_CHECK( + self.scalar_type() == src.scalar_type(), + method_name, "(): Expected self.dtype to be equal to src.dtype" + ); + } +} + +// Used for `gather`-like methods +// Note: self means the input tensor here +// Test: +// 1. index.size(d) <= self.size(d) for all d != dim +// 2. index.dim() == self.dim() +inline void gather_shape_check(const Tensor& self, int64_t dim, + const Tensor& index +) { + auto self_dims = ensure_nonempty_dim(self.dim()); + TORCH_CHECK(self_dims == ensure_nonempty_dim(index.dim()), + "Index tensor must have the same number of dimensions as input tensor" + ); + + for (const auto i : c10::irange(self_dims)) { + if (i != dim) { + TORCH_CHECK( + ensure_nonempty_size(index, i) <= ensure_nonempty_size(self, i), + "Size does not match at dimension ", i, + " expected index ", index.sizes(), + " to be no larger than self ", self.sizes(), + " apart from dimension ", dim + ); + } + } +} + +// Used for `scatter` and `scatter_add` +// Tests: +// 1. index.size(d) <= self.size(d) for all d != dim +// 2. index.size(d) <= src.size(d) for all d if src is a Tensor +// 3. index.dim() == self.dim() == src.dim() +inline void scatter_shape_check( + const Tensor& self, int64_t dim, const Tensor& index, + const std::optional& src_opt = std::nullopt +) { + if (index.numel() == 0) return; + TORCH_CHECK( + ensure_nonempty_dim(self.dim()) == ensure_nonempty_dim(index.dim()), + "Index tensor must have the same number of dimensions as self tensor" + ); + + bool is_wrong_shape = false; + int64_t self_dims = ensure_nonempty_dim(self.dim()); + + // Check: index.size(d) <= self.size(d) for all d != dim + for (const auto d : c10::irange(self_dims)) { + int64_t index_d_size = ensure_nonempty_size(index, d); + if (d == dim) continue; + if (index_d_size > ensure_nonempty_size(self, d)) { + is_wrong_shape = true; + break; + } + } + + // Check: index.size(d) <= src.size(d) for all d if src is Tensor + if (!is_wrong_shape && src_opt.has_value()) { + const auto& src = src_opt.value(); + for (const auto d : c10::irange(self_dims)) { + int64_t index_d_size = ensure_nonempty_size(index, d); + if (index_d_size > ensure_nonempty_size(src, d)) { + is_wrong_shape = true; + break; + } + } + } + + if (src_opt.has_value()) { + const auto& src = src_opt.value(); + + TORCH_CHECK( + ensure_nonempty_dim(src.dim()) == ensure_nonempty_dim(index.dim()), + "Index tensor must have the same number of dimensions as src tensor" + ); + + TORCH_CHECK(!is_wrong_shape, + "Expected index ", index.sizes(), + " to be no larger than self ", self.sizes(), + " apart from dimension ", dim, + " and to be no larger size than src ", src.sizes() + ); + } + else { + TORCH_CHECK(!is_wrong_shape, + "Expected index ", index.sizes(), + " to be no larger than self ", self.sizes(), + " apart from dimension ", dim + ); + } +} + +} // anonymous namespace + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SegmentReduce.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SegmentReduce.h new file mode 100644 index 0000000000000000000000000000000000000000..03c09a7f8d3f892ecb6b6da537058e3f69060693 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SegmentReduce.h @@ -0,0 +1,50 @@ +#pragma once + +#include +#include +#include +#include + +namespace at { +class Tensor; + +namespace native { + +using segment_reduce_lengths_fn = Tensor (*)( + ReductionType, + const Tensor&, + const Tensor&, + int64_t, + const std::optional&); +DECLARE_DISPATCH(segment_reduce_lengths_fn, _segment_reduce_lengths_stub) + +using segment_reduce_offsets_fn = Tensor (*)( + ReductionType, + const Tensor&, + const Tensor&, + int64_t, + const std::optional&); +DECLARE_DISPATCH(segment_reduce_offsets_fn, _segment_reduce_offsets_stub) + +using segment_reduce_lengths_backward_fn = Tensor (*)( + const Tensor&, + const Tensor&, + const Tensor&, + ReductionType, + const Tensor&, + int64_t, + const std::optional&); +DECLARE_DISPATCH(segment_reduce_lengths_backward_fn, _segment_reduce_lengths_backward_stub) + +using segment_reduce_offsets_backward_fn = Tensor (*)( + const Tensor&, + const Tensor&, + const Tensor&, + ReductionType, + const Tensor&, + int64_t, + const std::optional&); +DECLARE_DISPATCH(segment_reduce_offsets_backward_fn, _segment_reduce_offsets_backward_stub) + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SharedReduceOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SharedReduceOps.h new file mode 100644 index 0000000000000000000000000000000000000000..edaa106fc83c1a37e45fc86d32b58ecc6f44b613 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SharedReduceOps.h @@ -0,0 +1,545 @@ +#pragma once +// Please note that this file is +// used across both CPU and GPU. + +#include +#include +#include +#include +#include +#include +#if defined(__CUDACC__) +#include +#include +#elif defined(__HIPCC__) +#include +#include +#endif +#if defined(__CUDACC__) || defined(__HIPCC__) +#include +#else +#include +#define device_sqrt std::sqrt +#endif +#if defined(__CUDACC__) || defined(__HIPCC__) +template +inline C10_DEVICE scalar_t max_propagate_nan(scalar_t a, scalar_t b) { +#if defined(__HIPCC__) + // TODO: remove this special case for HIP when issue is fixed: + // https://github.com/ROCm-Developer-Tools/HIP/issues/2209 + scalar_t max = at::_isnan(a) ? a : (at::_isnan(b) ? b : std::max(a, b)); +#else + scalar_t max = at::_isnan(b) ? b : std::max(a, b); +#endif + return max; +} +template +inline C10_DEVICE scalar_t min_propagate_nan(scalar_t a, scalar_t b) { +#if defined(__HIPCC__) + // TODO: remove this special case for HIP when issue is fixed: + // https://github.com/ROCm-Developer-Tools/HIP/issues/2209 + scalar_t min = at::_isnan(a) ? a : (at::_isnan(b) ? b : std::min(a, b)); +#else + scalar_t min = at::_isnan(b) ? b : std::min(a, b); +#endif + return min; +} +#define MAX(X, Y) max_propagate_nan(X,Y) +#define MIN(X, Y) min_propagate_nan(X,Y) +#else +#include +#define MAX(X, Y) max_impl(X,Y) +#define MIN(X, Y) min_impl(X,Y) +#endif + +// ROCM hcc doesn't work well with using std:: in kernel functions +#if defined(__CUDA_ARCH__) +#include +#define compat_pow c10::cuda::compat::pow +#elif defined(__HIPCC__) +#include +#define compat_pow c10::hip::compat::pow +#else +#define compat_pow std::pow +#endif + +namespace at::native { + +namespace detail { + +#if defined(__CUDACC__) || defined(__HIPCC__) +template using pair = thrust::pair; +#else +template using pair = std::pair; +#endif + +} // namespace detail + +template +struct WelfordData { + scalar_t mean; + scalar_t m2; + index_t n; + scalar_t nf; + + C10_HOST_DEVICE WelfordData() : mean(0), m2(0), n(0), nf(0) {} + + C10_HOST_DEVICE WelfordData( + scalar_t mean, + scalar_t m2, + index_t n, + scalar_t nf) + : mean(mean), m2(m2), n(n), nf(nf) {} +}; + + +template +struct WelfordOps { + acc_scalar_t correction; + bool take_sqrt; + public: + using acc_t = WelfordData; + inline C10_DEVICE acc_t reduce(acc_t acc, scalar_t data, index_t /*idx*/) const { + // We accumulate n in index_t to avoid cumulative rounding error, but still + // need nf for use in combine where int32 may overflow. + index_t new_n = acc.n + 1; + acc_scalar_t new_nf = static_cast(new_n); + acc_scalar_t delta = data - acc.mean; + acc_scalar_t new_mean = acc.mean + delta / new_nf; + acc_scalar_t new_delta = data - new_mean; + return { + new_mean, + acc.m2 + delta * new_delta, + new_n, + new_nf, + }; + } + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + if (a.nf == 0) { + return b; + } + if (b.nf == 0) { + return a; + } + acc_scalar_t delta = b.mean - a.mean; + acc_scalar_t new_count = a.nf + b.nf; + acc_scalar_t nb_over_n = b.nf / new_count; + return { + a.mean + delta * nb_over_n, + a.m2 + b.m2 + delta * delta * a.nf * nb_over_n, + // setting acc.n as -1 since acc.n might not be able to represent the count + // correctly within its range, setting it to -1 to avoid confusion + -1, + new_count + }; + } + inline C10_DEVICE res_t project(acc_t acc) const __ubsan_ignore_float_divide_by_zero__ { + const auto mean = static_cast(acc.mean); + const auto divisor = acc.nf > correction ? acc.nf - correction : 0; + const auto var = acc.m2 / divisor; + res_t results(take_sqrt ? device_sqrt(var) : var, mean); + return results; + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline __device__ acc_t warp_shfl_down(acc_t acc, int offset) const { + return { + WARP_SHFL_DOWN(acc.mean, offset) + , WARP_SHFL_DOWN(acc.m2, offset) + , WARP_SHFL_DOWN(acc.n, offset) + , WARP_SHFL_DOWN(acc.nf, offset) + }; + } +#endif + C10_HOST_DEVICE WelfordOps(acc_scalar_t correction, bool take_sqrt) + : correction(correction), take_sqrt(take_sqrt) {} +}; + +template +struct MeanOps { + factor_t factor; + + inline C10_DEVICE acc_t reduce(acc_t a, scalar_t b, int64_t /*idx*/) const { + return combine(a, static_cast(b)); + } + + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + return a + b; + } + + inline C10_DEVICE out_t project(acc_t a) const { + return a * factor; + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline C10_DEVICE acc_t warp_shfl_down(acc_t data, int offset) const { + return WARP_SHFL_DOWN(data, offset); + } +#endif + + MeanOps(factor_t factor): factor(factor) { + } +}; + +// This accumulator template is used to calculate the minimum absolute value of +// a set of numbers. +// `scalar_t` is the type of the input and `acc_t` is the type of the accumulated +// value. These types differ for complex number input support. +template +struct AbsMinOps { + + inline C10_DEVICE acc_t reduce(acc_t acc, scalar_t data, int64_t /*idx*/) const { + return MIN(acc, static_cast(std::abs(at::opmath_type(data)))); + } + + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + return MIN(a, b); + } + + inline C10_DEVICE out_t project(acc_t a) const { + return a; + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline C10_DEVICE acc_t warp_shfl_down(acc_t acc, int offset) const { + return WARP_SHFL_DOWN(acc, offset); + } +#endif +}; + +// This accumulator template is used to calculate the maximum absolute value of +// a set of numbers. +// `scalar_t` is the type of the input and `acc_t` is the type of the accumulated +// value. These types differ for complex number input support. +template +struct AbsMaxOps { + inline C10_DEVICE acc_t reduce(acc_t acc, scalar_t data, int64_t /*idx*/) const { + return MAX(acc, static_cast(std::abs(at::opmath_type(data)))); + } + + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + return MAX(a, b); + } + + inline C10_DEVICE out_t project(acc_t a) const { + return a; + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline C10_DEVICE acc_t warp_shfl_down(acc_t acc, int offset) const { + return WARP_SHFL_DOWN(acc, offset); + } +#endif +}; + +// This accumulator template is used to calculate the norm of the absolute value +// of a set of numbers. +// `scalar_t` is the type of the input and `acc_t` is the type of the accumulated +// value. These types differ for complex number input support. +template +struct NormOps { + acc_t norm_; + + inline C10_DEVICE acc_t reduce(acc_t acc, scalar_t data, int64_t /*idx*/) const { + return acc + compat_pow(static_cast(std::abs(at::opmath_type(data))), norm_); + } + + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + return a + b; + } + + inline C10_DEVICE out_t project(acc_t a) const { + return compat_pow(a, static_cast(1.0) / norm_); + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline C10_DEVICE acc_t warp_shfl_down(acc_t acc, int offset) const { + return WARP_SHFL_DOWN(acc, offset); + } +#endif + + NormOps(acc_t norm_): norm_(norm_) { + } +}; + +// This accumulator template is used to calculate the order zero norm of the +// absolute value of a set of numbers. +// `scalar_t` is the type of the input and `acc_t` is the type of the accumulated +// value. These types differ for complex number input support. +template +struct NormZeroOps { + inline C10_DEVICE acc_t reduce(acc_t acc, scalar_t data, int64_t /*idx*/) const { + return acc + (data == static_cast(0) ? static_cast(0) : static_cast(1)); + } + + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + return a + b; + } + + inline C10_DEVICE out_t project(acc_t a) const { + return a; + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline C10_DEVICE acc_t warp_shfl_down(acc_t acc, int offset) const { + return WARP_SHFL_DOWN(acc, offset); + } +#endif +}; + +// This accumulator template is used to calculate the order one norm of the +// absolute value of a set of numbers. +// `scalar_t` is the type of the input and `acc_t` is the type of the accumulated +// value. These types differ for complex number input support. +template +struct NormOneOps { + inline C10_DEVICE acc_t reduce(acc_t acc, scalar_t data, int64_t /*idx*/) const { + return acc + static_cast(std::abs(at::opmath_type(data))); + } + + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + return a + b; + } + + inline C10_DEVICE out_t project(acc_t a) const { + return a; + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline C10_DEVICE acc_t warp_shfl_down(acc_t acc, int offset) const { + return WARP_SHFL_DOWN(acc, offset); + } +#endif +}; + + +template +struct AbsSwitch {}; + +template +inline C10_DEVICE acc_t abs_if_complex(scalar_t data, AbsSwitch) { + return static_cast(data); +} + +template +inline C10_DEVICE acc_t abs_if_complex(std::complex data, AbsSwitch) { + return static_cast(std::abs(data)); +} + +template +inline C10_DEVICE acc_t abs_if_complex(c10::complex data, AbsSwitch) { + return static_cast(std::abs(at::opmath_type>(data))); +} + +// This accumulator template is used to calculate the order two norm of the +// absolute value of a set of numbers. +// `scalar_t` is the type of the input and `acc_t` is the type of the accumulated +// value. These types differ for complex number input support. +template +struct NormTwoOps { + inline C10_DEVICE acc_t reduce(acc_t acc, scalar_t data, int64_t /*idx*/) const { + acc_t data_ = abs_if_complex(data, AbsSwitch()); + return acc + data_ * data_; + } + + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + return a + b; + } + + inline C10_DEVICE out_t project(acc_t a) const { + return device_sqrt(a); + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline C10_DEVICE acc_t warp_shfl_down(acc_t acc, int offset) const { + return WARP_SHFL_DOWN(acc, offset); + } +#endif +}; + +template +struct NanSumOps { + inline C10_DEVICE acc_t reduce(acc_t a, data_t b, int64_t /*idx*/) const { + return a + (at::_isnan(b) ? acc_t{0.} : acc_t{b}); + } + + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + return a + b; + } + + inline C10_DEVICE data_t project(acc_t a) const { + return data_t{a}; + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline C10_DEVICE acc_t warp_shfl_down(acc_t data, int offset) const { + return WARP_SHFL_DOWN(data, offset); + } +#endif +}; + +namespace detail { + +template +struct LessOrNan { + C10_DEVICE bool operator () (scalar_t a, scalar_t b, int64_t idx_a, int64_t idx_b) const { + // If (a == b), then choose the one with lower idx, else min(a, b) + if (at::_isnan(a)) { + if (at::_isnan(b)) { + return idx_a < idx_b; + } + return true; + } + return (a == b) ? idx_a < idx_b : (a < b); + } +}; + +template +struct GreaterOrNan { + C10_DEVICE bool operator () (scalar_t a, scalar_t b, int64_t idx_a, int64_t idx_b) const { + // If (a == b), then choose the one with lower idx, else max(a, b) + if (at::_isnan(a)) { + if (at::_isnan(b)) { + return idx_a < idx_b; + } + return true; + } + return (a == b) ? idx_a < idx_b : (a > b); + } +}; + +template +struct MinMaxReductionOps { + using scalar_t = typename binary_function_traits::arg1_t; + using index_t = int64_t; + using arg_t = detail::pair; + + static C10_DEVICE arg_t project(arg_t arg) { + return arg; + } + + static C10_DEVICE arg_t reduce(arg_t arg, scalar_t val, int64_t idx) { + return comp_t{}(arg.first, val, arg.second, idx) ? arg : arg_t(val, idx); + } + + static C10_DEVICE arg_t combine(arg_t a, arg_t b) { + return comp_t{}(a.first, b.first, a.second, b.second) ? a : b; + } + + static C10_DEVICE arg_t translate_idx(arg_t a, int64_t base_idx) { + return {a.first, a.second + base_idx}; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + static C10_DEVICE arg_t warp_shfl_down(arg_t arg, int offset) { + return arg_t(WARP_SHFL_DOWN(arg.first, offset), + WARP_SHFL_DOWN(arg.second, offset)); + } +#endif +}; + +template +struct ArgReductionOps : public MinMaxReductionOps { + using typename MinMaxReductionOps::scalar_t; + using typename MinMaxReductionOps::index_t; + using typename MinMaxReductionOps::arg_t; + + static C10_DEVICE index_t project(arg_t arg) { + return arg.second; + } +}; + +} // namespace detail + +template +struct ArgMaxOps : + public detail::ArgReductionOps> { +}; + +template +struct ArgMinOps : + public detail::ArgReductionOps> { +}; + +template +struct MinOps : + public detail::MinMaxReductionOps> { +}; + +template +struct MaxOps : + public detail::MinMaxReductionOps> { +}; + +template +struct MinMaxOps { + using acc_t = detail::pair; + inline C10_DEVICE acc_t reduce(acc_t acc, scalar_t data, index_t /*idx*/) const { + return combine(acc, {data, data}); + } + + inline C10_DEVICE acc_t combine(acc_t a, acc_t b) const { + auto min_val = (at::_isnan(a.first) || a.first < b.first) ? a.first : b.first; + auto max_val = (at::_isnan(a.second) || a.second > b.second) ? a.second : b.second; + + return {min_val, max_val}; + } + + inline C10_DEVICE acc_t project(acc_t acc) const { + return acc; + } + + static C10_DEVICE acc_t translate_idx(acc_t acc, int64_t /*base_idx*/) { + return acc; + } + +#if defined(__CUDACC__) || defined(__HIPCC__) + inline C10_DEVICE acc_t warp_shfl_down(acc_t acc, int offset) const { + return { + WARP_SHFL_DOWN(acc.first, offset), WARP_SHFL_DOWN(acc.second, offset) + }; + } +#endif +}; + +} // namespace at::native + +#undef MAX +#undef MIN diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SobolEngineOpsUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SobolEngineOpsUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..17e42ebe84a0e8b0906a76ba9c937c6c46027caa --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SobolEngineOpsUtils.h @@ -0,0 +1,55 @@ +/// This file contains some tensor-agnostic operations to be used in the +/// core functions of the `SobolEngine` +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#include +#include +#endif + +namespace at::native::sobol_utils { + +/// Function to return the minimum of number of bits to represent the integer `n` +inline int64_t bit_length(const int64_t n) { + int64_t nbits, nloc; + for (nloc = n, nbits = 0; nloc > 0; nloc /= 2, nbits++); + return nbits; +} + +/// Function to get the position of the rightmost zero in the bit representation of an integer +/// This value is the zero-indexed position +inline int64_t rightmost_zero(const int64_t n) { + int64_t z, i; + for (z = n, i = 0; z % 2 == 1; z /= 2, i++); + return i; +} + +/// Function to get a subsequence of bits in the representation of an integer starting from +/// `pos` and of length `length` +inline int64_t bitsubseq(const int64_t n, const int64_t pos, const int64_t length) { + return (n >> pos) & ((1 << length) - 1); +} + +/// Function to perform the inner product between a batched square matrix and a power of 2 vector +inline at::Tensor cdot_pow2(const at::Tensor& bmat) { + at::Tensor inter = at::arange(bmat.size(-1) - 1, -1, -1, bmat.options()); + inter = at::pow(2, inter).expand_as(bmat); + return at::mul(inter, bmat).sum(-1); +} + +/// All definitions below this point are data. These are constant, and should not be modified +/// without notice + +constexpr int64_t MAXDIM = 21201; +constexpr int64_t MAXDEG = 18; +constexpr int64_t MAXBIT = 30; +constexpr int64_t LARGEST_NUMBER = 1 << MAXBIT; +constexpr float RECIPD = 1.0 / LARGEST_NUMBER; + +extern const int64_t poly[MAXDIM]; +extern const int64_t initsobolstate[MAXDIM][MAXDEG]; + +} // namespace at::native::sobol_utils diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Sorting.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Sorting.h new file mode 100644 index 0000000000000000000000000000000000000000..9dd28c39a141263e6bb6d92184a4b17576476096 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Sorting.h @@ -0,0 +1,28 @@ +#pragma once + +#include +#include + +namespace at { +class TensorBase; +} + +namespace at::native { + +enum class QUANTILE_INTERPOLATION_MODE : uint8_t { + LINEAR, + LOWER, + HIGHER, + MIDPOINT, + NEAREST +}; + +using sort_fn = void(*)(const TensorBase&, const TensorBase&, const TensorBase&, int64_t, bool, bool); +using topk_fn = void(*)(const TensorBase&, const TensorBase&, const TensorBase&, int64_t, int64_t, bool, bool); + +DECLARE_DISPATCH(sort_fn, sort_stub) +DECLARE_DISPATCH(topk_fn, topk_stub) + +void _fill_indices(const TensorBase &indices, int64_t dim); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SortingUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SortingUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..a0f9cfa8bf0ce554d198b7e55079ed13e1798175 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SortingUtils.h @@ -0,0 +1,88 @@ +#pragma once + +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + +namespace at::native { + +// ensure we get good values and indices for kthvalue, mode +// this will always be with the reducing dim as 1-d +inline void _reduction_with_indices_allocate_or_resize_output( + Tensor& values, + Tensor& indices, + const Tensor& self, + int64_t dim_, + bool keepdim) { + int64_t dim = maybe_wrap_dim(dim_, self.dim(), /*wrap_scalar=*/true); + auto result_sizes = self.sizes().vec(); + if (!result_sizes.empty()) { + result_sizes[dim] = 1; + } + if (values.defined()) { + TORCH_CHECK( + self.options().type_equal(values.options()), + "output values must be of same type as input"); + if (!keepdim && values.dim() == self.dim() - 1) { + // unsqueeze to preserve passed in noncontiguous tensor in resize + values.unsqueeze_(dim); + } + resize_output(values, result_sizes); + } else { + values = at::empty(result_sizes, self.options()); + } + if (indices.defined()) { + TORCH_CHECK( + indices.dtype() == kLong, "output indices must be of scalar type Long"); + TORCH_CHECK( + indices.device() == self.device(), + "output indices must be on same device as input"); + if (!keepdim && indices.dim() == self.dim() - 1) { + // unsqueeze to preserve passed in noncontiguous tensor in resize + indices.unsqueeze_(dim); + } + resize_output(indices, result_sizes); + } else { + indices = at::empty(result_sizes, self.options().dtype(kLong)); + } +} + +// ensure we get good values and indices for topk +inline void _allocate_or_resize_output_with_indices( + Tensor& values, + Tensor& indices, + const Tensor& self, + int64_t dim_, + int64_t k) { + int64_t dim = maybe_wrap_dim(dim_, self.dim(), /*wrap_scalar=*/true); + auto result_sizes = self.sizes().vec(); + if (!result_sizes.empty()) { + result_sizes[dim] = k; + } + if (values.defined()) { + TORCH_CHECK( + self.options().type_equal(values.options()), + "output values must be of same type as input"); + values.resize_(result_sizes); + } else { + values = at::empty(result_sizes, self.options()); + } + if (indices.defined()) { + TORCH_CHECK( + indices.dtype() == kLong, "output indices must be of scalar type Long"); + TORCH_CHECK( + indices.device() == self.device(), + "output indices must be on same device as input"); + indices.resize_(result_sizes); + } else { + indices = at::empty(result_sizes, self.options().dtype(kLong)); + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SparseTensorUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SparseTensorUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..3953ca0d17b57f2547bafd2d08bec577b83b713e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SparseTensorUtils.h @@ -0,0 +1,190 @@ +#pragma once + +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#include +#endif + +namespace at::sparse { + +// Just for documentary purposes +using SparseTensor = Tensor; +using SparseType = Type; + +// This is an internal utility function for getting at the SparseTensorImpl, +// so that we can write sparse tensor specific accessors for special fields +// in SparseTensor. You should only use this for writing low level +// setters/getters for SparseTensorImpl fields; otherwise, you should use +// the low level setters/getters that were implemented using this. +// +// This may be called repeatedly, so make sure it's pretty cheap. +inline SparseTensorImpl* get_sparse_impl(const SparseTensor& self) { + TORCH_INTERNAL_ASSERT( + self.is_sparse(), "_internal_get_SparseTensorImpl: not a sparse tensor"); + return static_cast(self.unsafeGetTensorImpl()); +} + +// Takes indices and values and directly puts them into the sparse tensor, no +// copy. This used to be called THSTensor_(_move) +inline void alias_into_sparse( + const SparseTensor& self, + const Tensor& indices, + const Tensor& values) { + get_sparse_impl(self)->set_indices_and_values_unsafe(indices, values); +} + +// Take indices and values and makes a (data) copy of them to put into the +// sparse indices/values. This used to be called THSTensor_(_set) +inline void copy_into_sparse( + const SparseTensor& self, + const Tensor& indices, + const Tensor& values, + bool non_blocking) { + alias_into_sparse( + self, + indices.to(self._indices().options(), non_blocking, /*copy=*/true), + values.to(self._values().options(), non_blocking, /*copy=*/true)); +} + +// TODO: put this into the public API +inline bool is_same_tensor(const Tensor& lhs, const Tensor& rhs) { + return lhs.unsafeGetTensorImpl() == rhs.unsafeGetTensorImpl(); +} + +inline bool is_same_density(const SparseTensor& self, const SparseTensor& src) { + return self.sparse_dim() == src.sparse_dim() && + self.dense_dim() == src.dense_dim(); +} + +// Give us a new values tensor, with the same dimensionality +// as 'values' but with a new number of non-zero elements. +// TODO: Expose this for real in ATen, some day? +// NB: Doesn't preserve data. +inline Tensor new_values_with_size_of(const Tensor& values, int64_t nnz) { + std::vector size = values.sizes().vec(); + size[0] = nnz; + return at::empty(size, values.options()); +} + +// NOTE [ Flatten Sparse Indices ] +// This helper function flattens a sparse indices tensor (a Tensor) into a 1D +// indices tensor. E.g., +// input = [[2, 4, 0], +// [3, 1, 10]] +// full_size = [2, 12] +// output = [ 2 * 12 + 3, 4 * 12 + 1, 0 * 12 + 10 ] = [27, 49, 10] +// +// In other words, assuming that each `indices[i, :]` is a valid index to a +// tensor `t` of shape `full_size`. This returns the corresponding indices to +// the flattened tensor `t.reshape( prod(full_size[:indices.size(0)]), -1 )`. +// if forceClone is true, the result will forced to be a clone of self. +// if force_clone is true, the result will forced to be a clone of self. +TORCH_API Tensor flatten_indices( + const Tensor& indices, + IntArrayRef full_size, + bool force_clone = false); + +// Flatten sparse tensor's indices from nD to 1D, similar to NOTE [ Flatten +// Sparse Indices ], except this one allows partial flatten: only flatten on +// specified dims. Note that the flatten indices might be uncoalesced if +// dims_to_flatten.size() < sparse_dim. Also if input indices is already +// coalesced, the flattened indices will also be sorted. +// +// args: +// indices: sparse tensor indices +// sizes: sparse tensor sizes +// dims_to_flatten: a list of dim index to flatten +// +// Ex1: +// indices = [[2, 4, 0], +// [3, 1, 3]] +// sizes = [2, 12] +// dims_to_flatten = [0, 1] +// new_indices = [ 2 * 12 + 3, 4 * 12 + 1, 0 * 12 + 3 ] = [27, 49, 3] +// +// Ex2: +// dims_to_flatten = [1] +// new_indices = [ 3, 1, 3 ] # uncoalesced +TORCH_API Tensor flatten_indices_by_dims( + const Tensor& indices, + const IntArrayRef& sizes, + const IntArrayRef& dims_to_flatten); + +// Find the CSR representation for a row `indices` from the COO format +TORCH_API Tensor coo_to_csr(const int64_t* indices, int64_t dim, int64_t nnz); + +TORCH_API Tensor zeros_like_with_indices(const Tensor& t); + +template +class TensorGeometryHolder { + using geometry_holder_t = std::array; + + public: + explicit TensorGeometryHolder( + IntArrayRef sizes, + IntArrayRef strides, + TensorOptions options = {}) { + std::copy(sizes.begin(), sizes.end(), t_sizes.begin()); + std::copy(strides.begin(), strides.end(), t_strides.begin()); + } + + explicit TensorGeometryHolder(const Tensor& t) + : TensorGeometryHolder(t.sizes(), t.strides()) {} + + auto operator*() const { + return std::make_tuple(t_sizes, t_strides); + } + + private: + geometry_holder_t t_sizes; + geometry_holder_t t_strides; +}; + +template <> +class TensorGeometryHolder<0> { + using geometry_holder_t = Tensor; + + public: + explicit TensorGeometryHolder( + IntArrayRef sizes, + IntArrayRef strides, + TensorOptions options) { + const int64_t t_ndims = sizes.size(); + const auto cpu_options = TensorOptions(options).dtype(kLong).device(kCPU); + Tensor t_sizes_and_strides_cpu = at::empty({2, t_ndims}, cpu_options); + t_sizes_and_strides_cpu.select(0, 0).copy_(at::tensor(sizes, cpu_options)); + t_sizes_and_strides_cpu.select(0, 1).copy_( + at::tensor(strides, cpu_options)); + const Tensor t_sizes_and_strides = + t_sizes_and_strides_cpu.to(options.device()); + t_sizes = t_sizes_and_strides.select(0, 0); + t_strides = t_sizes_and_strides.select(0, 1); + } + + explicit TensorGeometryHolder(const Tensor& t) + : TensorGeometryHolder(t.sizes(), t.strides(), t.options()) {} + + auto operator*() const { + return std::make_tuple( + t_sizes.template data_ptr(), + t_strides.template data_ptr()); + } + + private: + geometry_holder_t t_sizes; + geometry_holder_t t_strides; +}; + +// Return all indices of a tensor with the given shape. +// +// full_coo_indices(shape) is equivalent to +// torch.ones(shape).nonzero().transpose(-2, -1) but much faster. +TORCH_API Tensor full_coo_indices(IntArrayRef sizes, TensorOptions options); + +} // namespace at::sparse diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SpectralOpsUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SpectralOpsUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..6bc2cca3928a9359573cd43e7bf09cd330513eb1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/SpectralOpsUtils.h @@ -0,0 +1,84 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at::native { + +// Normalization types used in _fft_with_size +enum class fft_norm_mode { + none, // No normalization + by_root_n, // Divide by sqrt(signal_size) + by_n, // Divide by signal_size +}; + +// NOTE [ Fourier Transform Conjugate Symmetry ] +// +// Real-to-complex Fourier transform satisfies the conjugate symmetry. That is, +// assuming X is the transformed K-dimensionsal signal, we have +// +// X[i_1, ..., i_K] = X[j_i, ..., j_K]*, +// +// where j_k = (N_k - i_k) mod N_k, N_k being the signal size at dim k, +// * is the conjugate operator. +// +// Therefore, in such cases, FFT libraries return only roughly half of the +// values to avoid redundancy: +// +// X[:, :, ..., :floor(N / 2) + 1] +// +// This is also the assumption in cuFFT and MKL. In ATen SpectralOps, such +// halved signal will also be returned by default (flag onesided=True). +// The following infer_ft_real_to_complex_onesided_size function calculates the +// onesided size from the twosided size. +// +// Note that this loses some information about the size of signal at last +// dimension. E.g., both 11 and 10 maps to 6. Hence, the following +// infer_ft_complex_to_real_onesided_size function takes in optional parameter +// to infer the twosided size from given onesided size. +// +// cuFFT doc: http://docs.nvidia.com/cuda/cufft/index.html#multi-dimensional +// MKL doc: https://software.intel.com/en-us/mkl-developer-reference-c-dfti-complex-storage-dfti-real-storage-dfti-conjugate-even-storage#CONJUGATE_EVEN_STORAGE + +inline int64_t infer_ft_real_to_complex_onesided_size(int64_t real_size) { + return (real_size / 2) + 1; +} + +inline int64_t infer_ft_complex_to_real_onesided_size(int64_t complex_size, + int64_t expected_size=-1) { + int64_t base = (complex_size - 1) * 2; + if (expected_size < 0) { + return base + 1; + } else if (base == expected_size) { + return base; + } else if (base + 1 == expected_size) { + return base + 1; + } else { + std::ostringstream ss; + ss << "expected real signal size " << expected_size << " is incompatible " + << "with onesided complex frequency size " << complex_size; + TORCH_CHECK(false, ss.str()); + } +} + +using fft_fill_with_conjugate_symmetry_fn = + void (*)(ScalarType dtype, IntArrayRef mirror_dims, IntArrayRef half_sizes, + IntArrayRef in_strides, const void* in_data, + IntArrayRef out_strides, void* out_data); +DECLARE_DISPATCH(fft_fill_with_conjugate_symmetry_fn, fft_fill_with_conjugate_symmetry_stub) + +// In real-to-complex transform, cuFFT and MKL only fill half of the values +// due to conjugate symmetry. This function fills in the other half of the full +// fft by using the Hermitian symmetry in the signal. +// self should be the shape of the full signal and dims.back() should be the +// one-sided dimension. +// See NOTE [ Fourier Transform Conjugate Symmetry ] +TORCH_API void _fft_fill_with_conjugate_symmetry_(const Tensor& self, IntArrayRef dims); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/StridedRandomAccessor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/StridedRandomAccessor.h new file mode 100644 index 0000000000000000000000000000000000000000..ad8f6d7b8830f10575e75c65758cc846cc800ae6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/StridedRandomAccessor.h @@ -0,0 +1,301 @@ +#pragma once + +namespace at::native { + +// (Const)StridedRandomAccessor is a +// (const) random access iterator defined over +// a strided array. + +// The traits below are to introduce __restrict__ +// modifier on different platforms. + +template +struct DefaultPtrTraits { + using PtrType = T*; +}; + +#if (defined(_WIN32) || defined(_WIN64)) +#define RESTRICT __restrict +#else +#define RESTRICT __restrict__ +#endif + +template +struct RestrictPtrTraits { + using PtrType = T* RESTRICT; +}; + +template < + typename T, + typename index_t = int64_t, + template class PtrTraits = DefaultPtrTraits +> +class ConstStridedRandomAccessor { +public: + using difference_type = index_t; + using value_type = const T; + using pointer = const typename PtrTraits::PtrType; + using reference = const value_type&; + using iterator_category = std::random_access_iterator_tag; + + using PtrType = typename PtrTraits::PtrType; + using index_type = index_t; + + // Constructors { + C10_HOST_DEVICE + ConstStridedRandomAccessor(PtrType ptr, index_t stride) + : ptr{ptr}, stride{stride} + {} + + C10_HOST_DEVICE + explicit ConstStridedRandomAccessor(PtrType ptr) + : ptr{ptr}, stride{static_cast(1)} + {} + + C10_HOST_DEVICE + ConstStridedRandomAccessor() + : ptr{nullptr}, stride{static_cast(1)} + {} + // } + + // Pointer-like operations { + C10_HOST_DEVICE + reference operator*() const { + return *ptr; + } + + C10_HOST_DEVICE + const value_type* operator->() const { + return reinterpret_cast(ptr); + } + + C10_HOST_DEVICE + reference operator[](index_t idx) const { + return ptr[idx * stride]; + } + // } + + // Prefix/postfix increment/decrement { + C10_HOST_DEVICE + ConstStridedRandomAccessor& operator++() { + ptr += stride; + return *this; + } + + C10_HOST_DEVICE + ConstStridedRandomAccessor operator++(int) { + ConstStridedRandomAccessor copy(*this); + ++*this; + return copy; + } + + C10_HOST_DEVICE + ConstStridedRandomAccessor& operator--() { + ptr -= stride; + return *this; + } + + C10_HOST_DEVICE + ConstStridedRandomAccessor operator--(int) { + ConstStridedRandomAccessor copy(*this); + --*this; + return copy; + } + // } + + // Arithmetic operations { + C10_HOST_DEVICE + ConstStridedRandomAccessor& operator+=(index_t offset) { + ptr += offset * stride; + return *this; + } + + C10_HOST_DEVICE + ConstStridedRandomAccessor operator+(index_t offset) const { + return ConstStridedRandomAccessor(ptr + offset * stride, stride); + } + + C10_HOST_DEVICE + friend ConstStridedRandomAccessor operator+( + index_t offset, + const ConstStridedRandomAccessor& accessor + ) { + return accessor + offset; + } + + C10_HOST_DEVICE + ConstStridedRandomAccessor& operator-=(index_t offset) { + ptr -= offset * stride; + return *this; + } + + C10_HOST_DEVICE + ConstStridedRandomAccessor operator-(index_t offset) const { + return ConstStridedRandomAccessor(ptr - offset * stride, stride); + } + + // Note that this operator is well-defined when `this` and `other` + // represent the same sequences, i.e. when + // 1. this.stride == other.stride, + // 2. |other - this| / this.stride is an Integer. + C10_HOST_DEVICE + difference_type operator-(const ConstStridedRandomAccessor& other) const { + return (ptr - other.ptr) / stride; + } + // } + + // Comparison operators { + C10_HOST_DEVICE + bool operator==(const ConstStridedRandomAccessor& other) const { + return (ptr == other.ptr) && (stride == other.stride); + } + + C10_HOST_DEVICE + bool operator!=(const ConstStridedRandomAccessor& other) const { + return !(*this == other); + } + + C10_HOST_DEVICE + bool operator<(const ConstStridedRandomAccessor& other) const { + return ptr < other.ptr; + } + + C10_HOST_DEVICE + bool operator<=(const ConstStridedRandomAccessor& other) const { + return (*this < other) || (*this == other); + } + + C10_HOST_DEVICE + bool operator>(const ConstStridedRandomAccessor& other) const { + return !(*this <= other); + } + + C10_HOST_DEVICE + bool operator>=(const ConstStridedRandomAccessor& other) const { + return !(*this < other); + } + // } + +protected: + PtrType ptr; + index_t stride; +}; + +template < + typename T, + typename index_t = int64_t, + template class PtrTraits = DefaultPtrTraits +> +class StridedRandomAccessor + : public ConstStridedRandomAccessor { +public: + using difference_type = index_t; + using value_type = T; + using pointer = typename PtrTraits::PtrType; + using reference = value_type&; + + using BaseType = ConstStridedRandomAccessor; + using PtrType = typename PtrTraits::PtrType; + + // Constructors { + C10_HOST_DEVICE + StridedRandomAccessor(PtrType ptr, index_t stride) + : BaseType(ptr, stride) + {} + + C10_HOST_DEVICE + explicit StridedRandomAccessor(PtrType ptr) + : BaseType(ptr) + {} + + C10_HOST_DEVICE + StridedRandomAccessor() + : BaseType() + {} + // } + + // Pointer-like operations { + C10_HOST_DEVICE + reference operator*() const { + return *this->ptr; + } + + C10_HOST_DEVICE + value_type* operator->() const { + return reinterpret_cast(this->ptr); + } + + C10_HOST_DEVICE + reference operator[](index_t idx) const { + return this->ptr[idx * this->stride]; + } + // } + + // Prefix/postfix increment/decrement { + C10_HOST_DEVICE + StridedRandomAccessor& operator++() { + this->ptr += this->stride; + return *this; + } + + C10_HOST_DEVICE + StridedRandomAccessor operator++(int) { + StridedRandomAccessor copy(*this); + ++*this; + return copy; + } + + C10_HOST_DEVICE + StridedRandomAccessor& operator--() { + this->ptr -= this->stride; + return *this; + } + + C10_HOST_DEVICE + StridedRandomAccessor operator--(int) { + StridedRandomAccessor copy(*this); + --*this; + return copy; + } + // } + + // Arithmetic operations { + C10_HOST_DEVICE + StridedRandomAccessor& operator+=(index_t offset) { + this->ptr += offset * this->stride; + return *this; + } + + C10_HOST_DEVICE + StridedRandomAccessor operator+(index_t offset) const { + return StridedRandomAccessor(this->ptr + offset * this->stride, this->stride); + } + + C10_HOST_DEVICE + friend StridedRandomAccessor operator+( + index_t offset, + const StridedRandomAccessor& accessor + ) { + return accessor + offset; + } + + C10_HOST_DEVICE + StridedRandomAccessor& operator-=(index_t offset) { + this->ptr -= offset * this->stride; + return *this; + } + + C10_HOST_DEVICE + StridedRandomAccessor operator-(index_t offset) const { + return StridedRandomAccessor(this->ptr - offset * this->stride, this->stride); + } + + // Note that here we call BaseType::operator- version + C10_HOST_DEVICE + difference_type operator-(const BaseType& other) const { + return (static_cast(*this) - other); + } + // } +}; + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorAdvancedIndexing.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorAdvancedIndexing.h new file mode 100644 index 0000000000000000000000000000000000000000..6cb6ce353b8c5b64361b4f6de3fdf0a3819053d8 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorAdvancedIndexing.h @@ -0,0 +1,102 @@ +#pragma once + +// Indexing tensors by tensors + +#include +#include +#include +#include + +namespace at { +struct TensorIterator; +} + +namespace at::native { + +using index_put_with_sort_fn = void (*)( + Tensor&, + const c10::List>&, + const Tensor&, + bool accumulate, + bool unsafe); +using index_put_with_sort_quantized_fn = void (*)( + Tensor& self, + const c10::List>& indices, + const Tensor& value, + double scale, + int zero_point, + bool unsafe); +using gather_fn = void (*)( + const Tensor& result, + const Tensor& self, + int64_t dim, + const Tensor& index); +using scatter_fn = void (*)( + const Tensor& self, + int64_t dim, + const Tensor& index, + const Tensor& src); +using scatter_fill_fn = void (*)( + const Tensor& self, + int64_t dim, + const Tensor& index, + const Scalar& src); +using scatter_add_fn = void (*)( + const Tensor& self, + int64_t dim, + const Tensor& index, + const Tensor& src); +using scatter_reduce_fn = void (*)( + const Tensor& self, + const int64_t dim, + const Tensor& index, + const Tensor& src, + const ReductionType& reduce); +using scatter_scalar_reduce_fn = void (*)( + const Tensor& self, + const int64_t dim, + const Tensor& index, + const Scalar& value, + const ReductionType& reduce); +using scatter_reduce_two_fn = void (*)( + const Tensor& self, + const int64_t dim, + const Tensor& index, + const Tensor& src, + const ReductionType& reduce); + +DECLARE_DISPATCH(index_put_with_sort_fn, index_put_with_sort_stub) +DECLARE_DISPATCH( + index_put_with_sort_quantized_fn, + index_put_with_sort_quantized_stub) +DECLARE_DISPATCH(gather_fn, gather_stub) +DECLARE_DISPATCH(scatter_fn, scatter_stub) +DECLARE_DISPATCH(scatter_fill_fn, scatter_fill_stub) +DECLARE_DISPATCH(scatter_add_fn, scatter_add_stub) +DECLARE_DISPATCH(scatter_reduce_fn, scatter_reduce_stub) +DECLARE_DISPATCH(scatter_scalar_reduce_fn, scatter_scalar_reduce_stub) +DECLARE_DISPATCH(scatter_reduce_two_fn, scatter_reduce_two_stub) + +TORCH_API Tensor& index_out( + Tensor& result, + const Tensor& self, + const c10::List>& indices); + +using scatter_add_expanded_index_fn = + void (*)(const Tensor&, const Tensor&, const Tensor&); +using scatter_reduce_expanded_index_fn = void (*)( + const Tensor&, + const Tensor&, + const Tensor&, + const ReductionType& reduce, + bool); +using gather_expanded_index_fn = + void (*)(const Tensor&, const Tensor&, const Tensor&); + +DECLARE_DISPATCH(scatter_add_expanded_index_fn, scatter_add_expanded_index_stub) +DECLARE_DISPATCH( + scatter_reduce_expanded_index_fn, + scatter_reduce_expanded_index_stub) +DECLARE_DISPATCH(gather_expanded_index_fn, gather_expanded_index_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorAdvancedIndexingUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorAdvancedIndexingUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..05009e96a7c4a9c5b4d1e46721e8266c942fa51e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorAdvancedIndexingUtils.h @@ -0,0 +1,109 @@ +#pragma once +#include +#include +#include + +namespace at::native { +namespace { +#ifndef STRIP_ERROR_MESSAGES +inline std::string shapes_as_str(TensorList tensors) { + std::ostringstream os; + bool first = true; + for (auto& tensor : tensors) { + if (tensor.defined()) { + if (!first) { + os << ", "; + } + os << tensor.sizes(); + first = false; + } + } + return os.str(); +} +#endif +} // anonymous namespace + +inline std::tuple canDispatchToMaskedFill( + const Tensor& self, + const torch::List>& indices, + const Tensor& value) { + if (!(value.numel() == 1 && value.device().is_cpu())) { + return std::make_tuple(false, Tensor()); + } + int64_t num_ind = 0; + Tensor mask; + auto self_device = self.device(); + for (const std::optional& i : indices) { + if (!i.has_value() || !(*i).defined()) { + num_ind++; + } else { + const Tensor& index = *i; + if ((index.scalar_type() != kByte && index.scalar_type() != kBool) || + index.device() != self_device || mask.defined()) { + return std::make_tuple(false, Tensor()); + } else { + mask = index; + for (const auto j : c10::irange(index.dim())) { + int64_t srcIdx = num_ind + j; + TORCH_CHECK_INDEX( + index.size(j) == self.size(srcIdx), + "The shape of the mask ", + index.sizes(), + " at index ", + j, + " does not match the shape of the indexed tensor ", + self.sizes(), + " at index ", + srcIdx); + } + num_ind += mask.ndimension(); + } + } + } + for ([[maybe_unused]] const auto i : + c10::irange(num_ind, self.ndimension())) { + mask = mask.unsqueeze(-1); + } + return std::make_tuple(true, mask); +} + +inline AdvancedIndex make_info(Tensor self, IOptTensorListRef orig) { + checkIndexTensorTypes(orig, /*allow_int*/ true); + // first expand BoolTensor (masks) or ByteTensor (masks) into 1 or more + // LongTensors + auto indices = expandTensors(self, orig); + // next broadcast all index tensors together + try { + indices = expand_outplace(indices); + } catch (std::exception& e) { + TORCH_CHECK_INDEX( + false, + "shape mismatch: indexing tensors could not be broadcast together" + " with shapes ", + shapes_as_str(indices)); + } + // add missing null Tensors so that it matches self.dim() + while (indices.size() < (size_t)self.dim()) { + indices.emplace_back(); + } + // if the non-null indices are not all adjacent, transpose self and indices + // together so that they're adjacent at the front + if (!hasContiguousSubspace(indices)) { + std::tie(self, indices) = transposeToFront(self, indices); + } + // Ensure indices are on the same device as self + for (auto& indice : indices) { + if (indice.defined() && indice.device() != self.device()) { + indice = indice.to(self.device()); + } + } + for (auto& indice : indices) { + if (indice.defined() && indice.dtype() == at::kInt) { + indice = indice.to(at::kLong); + } + } + + return AdvancedIndex(self, indices); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorCompare.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorCompare.h new file mode 100644 index 0000000000000000000000000000000000000000..9fa6dd280536e96db36213f5a83cdfcd6f5914e6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorCompare.h @@ -0,0 +1,56 @@ +#pragma once + +#include + +namespace c10 { +class Scalar; +} + +namespace at { +class Tensor; +struct TensorIterator; +struct TensorIteratorBase; +} // namespace at + +namespace at::native { + +using reduce_minmax_fn = + void (*)(Tensor&, Tensor&, const Tensor&, int64_t, bool); +using structured_reduce_minmax_fn = + void (*)(const Tensor&, const Tensor&, const Tensor&, int64_t, bool); + +DECLARE_DISPATCH(structured_reduce_minmax_fn, max_stub) +DECLARE_DISPATCH(structured_reduce_minmax_fn, min_stub) + +using where_fn = void (*)(TensorIterator&); +DECLARE_DISPATCH(where_fn, where_kernel) + +using is_infinity_op_fn = void (*)(TensorIteratorBase&); +DECLARE_DISPATCH(is_infinity_op_fn, isposinf_stub) +DECLARE_DISPATCH(is_infinity_op_fn, isneginf_stub) + +using mode_fn = void (*)(Tensor&, Tensor&, const Tensor&, int64_t, bool); +DECLARE_DISPATCH(mode_fn, mode_stub) + +using clamp_tensor_fn = void (*)(TensorIteratorBase&); +DECLARE_DISPATCH(clamp_tensor_fn, clamp_stub) + +namespace detail { +enum class ClampLimits { Min, Max, MinMax }; +} + +DECLARE_DISPATCH( + void (*)(TensorIteratorBase&, const c10::Scalar&, const c10::Scalar&), + clamp_scalar_stub) +DECLARE_DISPATCH( + void (*)(TensorIteratorBase&, c10::Scalar), + clamp_min_scalar_stub) +DECLARE_DISPATCH( + void (*)(TensorIteratorBase&, c10::Scalar), + clamp_max_scalar_stub) + +using isin_default_fn = + void (*)(const Tensor&, const Tensor&, bool, const Tensor&); +DECLARE_DISPATCH(isin_default_fn, isin_default_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorConversions.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorConversions.h new file mode 100644 index 0000000000000000000000000000000000000000..da5125a9d9b0ec39121f53a9264201f24dca5610 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorConversions.h @@ -0,0 +1,31 @@ +#pragma once + +#include +#include +#include +#include +#include + +namespace at { +class Tensor; +namespace native { +bool to_will_alias( + const Tensor& self, + std::optional dtype, + std::optional layout, + std::optional device, + bool copy, + std::optional optional_memory_format); + +Tensor to_meta(const Tensor& tensor); +std::optional to_meta(const std::optional& tensor); +std::vector to_meta(at::ITensorListRef t_list); +Tensor dense_to_sparse_with_mask( + const Tensor& self, + const Tensor& mask, + std::optional layout, + OptionalIntArrayRef blocksize, + std::optional dense_dim_opt); + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorDimApply.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorDimApply.h new file mode 100644 index 0000000000000000000000000000000000000000..b67dd2085041c552de91d062a9e1381635edb73d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorDimApply.h @@ -0,0 +1,67 @@ +#pragma once +#include +#include + +namespace at::native { +// input tensors are non-zero dim and non-empty +template + +void tensor_dim_apply3( + const Tensor& self, + Tensor& values, + Tensor& indices, + int64_t dim, + Function func) { + int ndims = self.dim(); + int tensor_dim_apply_has_finished = 0; + std::vector counter(ndims, 0); + const T1* self_data = self.const_data_ptr(); + T1* values_data = values.data_ptr(); + T2* indices_data = indices.data_ptr(); + int64_t self_stride = self.stride(dim); + int64_t values_stride = values.stride(dim); + int64_t indices_stride = indices.stride(dim); + int self_dim_size = self.size(dim); + + while (!tensor_dim_apply_has_finished) { + func( + self_data, + values_data, + indices_data, + self_dim_size, + self_stride, + values_stride, + indices_stride); + if (ndims == 1) { + break; + } + for (const auto dim_i : c10::irange(ndims)) { + if (dim_i == dim) { + if (dim_i == (ndims - 1)) { + tensor_dim_apply_has_finished = 1; + break; + } + continue; + } + counter[dim_i]++; + self_data += self.stride(dim_i); + values_data += values.stride(dim_i); + indices_data += indices.stride(dim_i); + + if (counter[dim_i] == self.size(dim_i)) { + if (dim_i == ndims - 1) { + tensor_dim_apply_has_finished = 1; + break; + } else { + self_data -= counter[dim_i] * self.stride(dim_i); + values_data -= counter[dim_i] * values.stride(dim_i); + indices_data -= counter[dim_i] * indices.stride(dim_i); + counter[dim_i] = 0; + } + } else { + break; + } + } + } +} +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorFactories.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorFactories.h new file mode 100644 index 0000000000000000000000000000000000000000..2d0fb908dc726ee0de78a1fa60e58e2168873d4b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorFactories.h @@ -0,0 +1,169 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + +namespace at::native { +// Different combinations of row, col, and offset can lead to two cases: +// +// Case 1 - Trapezoid (Triangle as a special case): row + offset <= col +// Example A: offset > 0 +// 1 1 0 0 0 +// 1 1 1 0 0 +// 1 1 1 1 0 +// Example B: offset <= 0 +// 0 0 0 +// 1 0 0 +// 1 1 0 +// In this case, we calculate the number of elements in the first row and +// last row of the tril respectively, and then compute the tril size. +// +// Case 2 - Trapezoid + Rectangle: row + offset > col +// Example: +// 1 1 0 +// 1 1 1 +// 1 1 1 +// In this case, we first calculate the size of top trapezoid, and then +// calculate the size of the bottom rectangle. +inline int64_t get_tril_size(int64_t row, int64_t col, int64_t offset) { + // If either dimension is 0 then the there is no tril + if (row == 0 || col == 0) { + return 0; + } + // number of elements in the first row of the tril + auto m_first_row = offset > 0 ? std::min(col, 1 + offset) + : // upper bounded by col + row + offset > 0; // either 0 or 1 + // number of elements in the last row of the tril, bounded by [0, col] + auto m_last_row = std::max(0, std::min(col, row + offset)); + // number of rows, bounded by [0, row] + auto n_row_all = std::max(0, std::min(row, row + offset)); + auto n_row_trapezoid = (m_last_row - m_first_row + 1); + + // calculate # of elements in the top trapezoid + auto tril_size = (m_first_row + m_last_row) * n_row_trapezoid >> 1; + + // calculate # of elements in the bottom rectangle if there is any + auto diff_row = n_row_all - n_row_trapezoid; + if (diff_row > 0) { + tril_size += diff_row * col; + } + + return tril_size; +} + +inline void check_args( + int64_t row, + int64_t col, + std::optional layout_opt) { + TORCH_CHECK(row >= 0, "row must be non-negative, got", row); + TORCH_CHECK(col >= 0, "col must be non-negative, got", col); + if (layout_opt.has_value()) { + TORCH_CHECK( + *layout_opt == at::kStrided, + "only support layout=torch.strided, got", + *layout_opt) + } +} + +using at::check_size_nonnegative; + +// assumes maximum value in created tensor is n-1 (e.g., torch.randperm(n)) +inline void check_supported_max_int_with_precision( + int64_t n, + const Tensor& tensor) { + // match defined() to behavior of checks below + TORCH_CHECK( + at::scalar_tensor(n > 0 ? n - 1 : n, tensor.options()).defined(), + "n is too large for result tensor type: '", + tensor.toString(), + "'"); + + // Ensure sufficient precision for floating point representation. + switch (tensor.scalar_type()) { + case at::ScalarType::Half: + TORCH_CHECK( + n <= (int64_t(1) << 11) + 1, + "n cannot be greater than 2049 for Half type."); + break; + case at::ScalarType::Float: + TORCH_CHECK( + n <= (int64_t(1) << 24) + 1, + "n cannot be greater than 2^24+1 for Float type."); + break; + case at::ScalarType::Double: // Unlikely to happen, but doesn't hurt to + // check + TORCH_CHECK( + n <= (int64_t(1) << 53) + 1, + "n cannot be greater than 2^53+1 for Double type."); + break; + default: + break; + } +} + +// Called by `empty*` functions when deterministic algorithms are enabled to +// fill the tensor with NaN if it is floating point or complex type, or fill +// with max value if it is integer type +inline Tensor& fill_empty_deterministic_(Tensor& tensor) { + if (tensor.is_floating_point() || tensor.is_complex()) { + AT_DISPATCH_V2( + tensor.scalar_type(), + "fill_empty_deterministic_", + AT_WRAP([&]() { + tensor.fill_(std::numeric_limits::quiet_NaN()); + }), + AT_EXPAND(AT_FLOATING_TYPES), + AT_EXPAND(AT_COMPLEX_TYPES), + AT_EXPAND(AT_FLOAT8_TYPES), + kBFloat16, + kHalf, + kComplexHalf); + } else { + AT_DISPATCH_V2( + tensor.scalar_type(), + "fill_empty_deterministic_", + AT_WRAP([&]() { tensor.fill_(std::numeric_limits::max()); }), + kBool, + AT_EXPAND(AT_INTEGRAL_TYPES_V2)); + } + return tensor; +} + +// The ZeroTensor allocator ignores whatever allocation is requested and always +// gives you nullptr +struct ZeroTensorAllocator final : public at::Allocator { + ZeroTensorAllocator(at::Device device) : device_(device) {} + ~ZeroTensorAllocator() override = default; + static void deleter(void* const pointer) { + TORCH_INTERNAL_ASSERT(!pointer); + } + DataPtr allocate(const size_t /*nbytes*/) override { + return {nullptr, nullptr, &deleter, device_}; + } + DeleterFnPtr raw_deleter() const override { + return deleter; + } + void copy_data( + void* dest [[maybe_unused]], + const void* src [[maybe_unused]], + std::size_t count [[maybe_unused]]) const final {} + at::Device device_; +}; + +using binary_fn = void (*)(TensorIterator&); + +DECLARE_DISPATCH(binary_fn, complex_stub) +DECLARE_DISPATCH(binary_fn, polar_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorIterator.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorIterator.h new file mode 100644 index 0000000000000000000000000000000000000000..e55d2a58d709926a24467a0056323096e0890fa9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorIterator.h @@ -0,0 +1,2 @@ +#pragma once +#include diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorIteratorDynamicCasting.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorIteratorDynamicCasting.h new file mode 100644 index 0000000000000000000000000000000000000000..69146580ff499e8baec6c1b3f6f04bd13693a449 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorIteratorDynamicCasting.h @@ -0,0 +1,52 @@ +#pragma once + +#include +#include +#include +#include +#include + +// This file includes utilities for dynamic_casting done by TensorIterator, see +// CUDALoops.cuh and Loops.h. + +// dynamic_casting handles when the types expected by the iterator do not match +// the types of the arguments to the function that is being called. On CUDA, the +// cast is currently pushed down into the kernel (for performance reasons). On +// CPU, there is currently an internal assert that a dynamic_cast is not needed. + +namespace at::native { + +// `needs_dynamic_casting` compares the types expected by iterator +// (i.e. dtypes of the operands) with the actual type of the arguments +// (and returns) of func_t +template ::arity> +struct needs_dynamic_casting { + static bool check(TensorIteratorBase& iter) { + using traits = function_traits; + using cpp_type = typename traits::template arg::type; + using cpp_map = c10::CppTypeToScalarType; + + if (iter.input_dtype(nargs - 1) != cpp_map::value) { + return true; + } + return needs_dynamic_casting::check(iter); + } +}; + +template +struct needs_dynamic_casting { + static bool check(TensorIteratorBase& iter) { + using traits = function_traits; + using cpp_type = typename traits::result_type; + + // we could assert output numbers are correct here, but checks + // (including arity) are currently pushed outside of this struct. + if constexpr (std::is_void_v) { + return false; + } else { + return iter.dtype(0) != c10::CppTypeToScalarType::value; + } + } +}; + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorProperties.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorProperties.h new file mode 100644 index 0000000000000000000000000000000000000000..87aca85fb3af1da0db523300a8cb3b310a0a88ad --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorProperties.h @@ -0,0 +1,12 @@ +#pragma once + +// See NOTE: [Tensor vs. TensorBase] +namespace at { +class TensorBase; +} + +namespace at::native { + +TORCH_API bool cudnn_is_acceptable(const TensorBase& self); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorShape.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorShape.h new file mode 100644 index 0000000000000000000000000000000000000000..22c37d2241accdb3a99809abee158721b76b9c50 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorShape.h @@ -0,0 +1,145 @@ +#pragma once +#include +#include +#include + +namespace at::native { + +TORCH_API at::Tensor clone_preserve_strides(const at::Tensor& self); + +inline bool cat_should_skip_tensor(const Tensor& t) { + return t.sym_numel() == 0 && t.dim() == 1; +} + +// Check to see if the shape of tensors is compatible +// for being concatenated along a given dimension. +inline void check_cat_shape_except_dim( + const Tensor& first, + const Tensor& second, + int64_t dimension, + int64_t index) { + int64_t first_dims = first.dim(); + int64_t second_dims = second.dim(); + TORCH_CHECK( + first_dims == second_dims, + "Tensors must have same number of dimensions: got ", + first_dims, + " and ", + second_dims); + for (const auto dim : c10::irange(first_dims)) { + if (dim == dimension) { + continue; + } + int64_t first_dim_size = first.sizes()[dim]; + int64_t second_dim_size = second.sizes()[dim]; + TORCH_CHECK( + first_dim_size == second_dim_size, + "Sizes of tensors must match except in dimension ", + dimension, + ". Expected size ", + static_cast(first_dim_size), + " but got size ", + static_cast(second_dim_size), + " for tensor number ", + index, + " in the list."); + } +} + +inline void check_cat_no_zero_dim(const MaterializedITensorListRef& tensors) { + [[maybe_unused]] int64_t i = 0; + for (const Tensor& t : tensors) { + TORCH_CHECK( + t.dim() > 0, + "zero-dimensional tensor (at position ", + i, + ") cannot be concatenated"); + i++; + } +} + +inline int64_t get_num_splits( + const Tensor& self, + int64_t split_size, + int64_t dim) { + TORCH_CHECK(self.dim() != 0, "split expects at least a 1-dimensional tensor"); + TORCH_CHECK( + split_size >= 0, + "split expects split_size be non-negative, but got split_size=", + split_size); + int64_t dim_size = self.size(dim); + TORCH_CHECK( + split_size > 0 || dim_size == 0, + "split_size can only be 0 if dimension size is 0, " + "but got dimension size of ", + dim_size); + // if split_size is 0 and dimension size is 0, there is 1 split. + int64_t num_splits = 1; + if (split_size != 0) { + // ensuring num_splits is at least 1 makes consistent the case where + // split_size > dim_size (returns a single split). We might want to error + // here, but keep it for BC. + num_splits = std::max((dim_size + split_size - 1) / split_size, 1); + } + return num_splits; +} + +inline bool have_same_ndims(TensorList tensors) { + auto ndim = tensors[0].dim(); + for (const auto tensor_idx : c10::irange(tensors.size())) { + if (tensors[tensor_idx].dim() != ndim) { + return false; + } + } + return true; +} + +inline void leading_dimension_matches(TensorList tensors, int64_t dim) { + auto tensor_zero_size = tensors[0].sizes(); + std::vector leading_dim_sizes( + tensor_zero_size.begin(), tensor_zero_size.begin() + dim); + for (const auto i : c10::irange(tensors.size())) { + at::Tensor tensor = tensors[i]; + for (const auto j : c10::irange(dim)) { + TORCH_CHECK( + tensor.size(j) == leading_dim_sizes[j], + "_chunk_cat expects same sizes of 0,...,dim-1 dimensions for all tensors"); + } + } +} + +inline int64_t preprocess_chunk_cat_inputs( + TensorList tensors, + int64_t dim, + int64_t num_chunks) { + TORCH_CHECK(num_chunks >= 1, "_chunk_cat expects positive num_chunks"); + TORCH_CHECK( + !tensors.empty(), "_chunk_cat expects a non-empty input tensor list"); + auto expected_dtype = tensors[0].dtype(); + auto expected_device = tensors[0].device(); + for (const auto i : c10::irange(tensors.size())) { + TORCH_CHECK(tensors[i].numel() > 0, "_chunk_cat expects non-empty tensor"); + TORCH_CHECK( + tensors[i].dtype() == expected_dtype, + "_chunk_cat expects all input tensors with the same dtype"); + TORCH_CHECK( + tensors[i].device() == expected_device, + "_chunk_cat expects all inputs tensors on the same device"); + } + if (have_same_ndims(tensors)) { + dim = maybe_wrap_dim(dim, tensors[0].dim()); + } else { + TORCH_CHECK( + dim >= 0, + "_chunk_cat expects non-negative dim when input tensors have different ndims") + for (const auto i : c10::irange(tensors.size())) { + TORCH_CHECK( + dim < tensors[i].ndimension(), + "_chunk_cat expects dim < ndim for all input tensors"); + } + } + leading_dimension_matches(tensors, dim); + return dim; +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorTransformations.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorTransformations.h new file mode 100644 index 0000000000000000000000000000000000000000..5876cac5c7742fc2df75aab19b8f226e90d0c7e3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TensorTransformations.h @@ -0,0 +1,35 @@ +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + +#include + +namespace at::native { + +static inline Tensor roll_common( + const Tensor& self, + IntArrayRef shifts, + IntArrayRef dims) { + TORCH_CHECK(!shifts.empty(), "`shifts` required"); + if (dims.empty() && shifts.size() == 1) { + auto flattened = self.contiguous().view(self.numel()); + return roll(flattened, shifts[0], 0).view(self.sizes()); + } + TORCH_CHECK( + shifts.size() == dims.size(), + "shifts and dimensions must align. shifts: ", + shifts.size(), + ", dims:", + dims.size()); + AT_ASSERT(dims.size() > 1); + auto tail_shifts = shifts.slice(1); + auto tail_dims = dims.slice(1); + auto first_dim_rolled = roll(self, shifts[0], dims[0]); + return at::roll(first_dim_rolled, tail_shifts, tail_dims); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TopKImpl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TopKImpl.h new file mode 100644 index 0000000000000000000000000000000000000000..0a11f5f4087536c928c6294e92ce6cae03bd1378 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TopKImpl.h @@ -0,0 +1,98 @@ +#pragma once +#include +#include + +namespace at::native { + +#ifdef CPU_CAPABILITY +inline namespace CPU_CAPABILITY { +#else +inline namespace DEFAULT { +#endif + +// Core topk loop, shared between CPU and QuantizedCPU +template +void topk_impl_loop( + const int64_t mode_values_stride, + const int64_t mode_indices_stride, + const int64_t tmp_values_stride, + const int64_t k, + const int64_t dim_size, + const bool largest, + const bool sorted, + char** data, const int64_t* strides, const int64_t n) { + + // If k is zero, then output values and indices are empty tensors + // So iterating over other dims is pointless + if (k == 0) { + return; + } + using elem_t = std::pair; + std::vector queue(dim_size); + for (const auto i : c10::irange(n)) { + TensorAccessor mode_values( + reinterpret_cast(data[0] + i * strides[0]), + &k, &mode_values_stride); + TensorAccessor mode_indices( + reinterpret_cast(data[1] + i * strides[1]), + &k, &mode_indices_stride); + TensorAccessor tmp_values( + reinterpret_cast(data[2] + i * strides[2]), + &dim_size, &tmp_values_stride); + + auto n_2 = dim_size; + auto use_partial_sort = k * 64 <= n_2; + + for (const auto j : c10::irange(n_2)) { + queue[j].first = tmp_values[j]; + queue[j].second = j; + } + + // we want nan to be sorted as top for numpy compatibility + if (use_partial_sort) { + if (largest) { + std::partial_sort(queue.begin(), queue.begin() + k, queue.end(), + [](const elem_t& x, const elem_t& y) -> bool { + return ((_isnan(x.first) && !_isnan(y.first)) || (x.first > y.first)); + }); + } else { + std::partial_sort(queue.begin(), queue.begin() + k, queue.end(), + [](const elem_t& x, const elem_t& y) -> bool { + return ((!_isnan(x.first) && _isnan(y.first)) || (x.first < y.first)); + }); + } + } else { + if (largest) { + std::nth_element(queue.begin(), queue.begin() + k - 1, queue.end(), + [](const elem_t& x, const elem_t& y) -> bool { + return ((_isnan(x.first) && !_isnan(y.first)) || (x.first > y.first)); + }); + if (sorted) { + std::sort(queue.begin(), queue.begin() + k - 1, + [](const elem_t& x, const elem_t& y) -> bool { + return ((_isnan(x.first) && !_isnan(y.first)) || (x.first > y.first)); + }); + } + } else { + std::nth_element(queue.begin(), queue.begin() + k -1, queue.end(), + [](const elem_t& x, const elem_t& y) -> bool { + return ((!_isnan(x.first) && _isnan(y.first)) || (x.first < y.first)); + }); + if (sorted) { + std::sort(queue.begin(), queue.begin() + k -1, + [](const elem_t& x, const elem_t& y) -> bool { + return ((!_isnan(x.first) && _isnan(y.first)) || (x.first < y.first)); + }); + } + } + } + + for (const auto j : c10::irange(k)) { + mode_values[j] = queue[j].first; + mode_indices[j] = queue[j].second; + } + } +} + +} // namespace CPU_CAPABILITY +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TransposeType.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TransposeType.h new file mode 100644 index 0000000000000000000000000000000000000000..603bf6fee60aa2bc1850fae3eb0dac73345d7fb9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TransposeType.h @@ -0,0 +1,23 @@ +#pragma once +#include + +namespace at::native { + +// Used as an interface between the different BLAS-like libraries +enum class TransposeType { + NoTranspose, + Transpose, + ConjTranspose, +}; + +// Transforms TransposeType into the BLAS / LAPACK format +static inline char to_blas(TransposeType trans) { + switch (trans) { + case TransposeType::Transpose: return 'T'; + case TransposeType::NoTranspose: return 'N'; + case TransposeType::ConjTranspose: return 'C'; + } + TORCH_INTERNAL_ASSERT(false, "Invalid transpose type"); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TriangularOpsUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TriangularOpsUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..cc56fa6457e75bc980747afc9d2d72257d6c093b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TriangularOpsUtils.h @@ -0,0 +1,57 @@ +#include +#include + +namespace at::native { + +/* + * Given batches of matrices with arbitrary batch dim, + * computes the number of batches for Triu and Tril. This ignores stride 0 dimension + */ +static inline int64_t batchCountTrilTriu(const Tensor& batched_matrices) { + int64_t result = 1; + for (int64_t i = 0; i < batched_matrices.ndimension() - 2; i++) { + if (batched_matrices.stride(i) != 0) { + result *= batched_matrices.size(i); + } + } + return result; +} + +/* Checks a necessary property for the triu and tril implementations, hence the name. + * Here batch contiguity is checked for tensors with greater than 4 dimensions. + * Contiguous tensors and tensors with less than 3 dimensions pass this check + */ +static inline std::tuple checkTrilTriuBatchContiguous(const Tensor& tensor, bool allow_zero_stride) { + // Complete contiguity is the most desired property, which is why + // we return true if the tensor is contiguous + if (tensor.is_contiguous()) { + auto default_strides_for_size = batched_matrix_contiguous_strides(tensor.sizes()); + if (tensor.strides() == default_strides_for_size) { + return std::make_tuple(true, tensor); + } else { + return std::make_tuple(false, tensor.as_strided(tensor.sizes(), default_strides_for_size)); + } + } + + int64_t dims = tensor.dim(); + + // Tensors with dimension less than 4 are handled by default + if (allow_zero_stride && dims <= 3) { + return std::make_tuple(true, tensor); + } + + int64_t expected_stride = tensor.size(-1) * tensor.size(-2); + for (int64_t i = dims - 3; i >= 0; i--) { + // Skip trivial dimension; + if (allow_zero_stride && i == 0 && (tensor.stride(i) == 0 || tensor.size(i) == 1)) { + continue; + } + if (expected_stride != tensor.stride(i)) { + return std::make_tuple(false, tensor.contiguous()); + } + expected_stride *= tensor.size(i); + } + return std::make_tuple(true, tensor); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TypeProperties.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TypeProperties.h new file mode 100644 index 0000000000000000000000000000000000000000..2d4845c758461c3435c83eaf7cafa3ddd6c9d784 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/TypeProperties.h @@ -0,0 +1,20 @@ +#pragma once + +#include +#include + +namespace at::native { + +struct ResultTypeState { + c10::ScalarType dimResult = ScalarType::Undefined; + c10::ScalarType wrappedResult = ScalarType::Undefined; + c10::ScalarType zeroResult = ScalarType::Undefined; +}; + +TORCH_API ResultTypeState update_result_type_state(const Tensor& tensor, const ResultTypeState& in_state); +TORCH_API ResultTypeState update_result_type_state(const Scalar& scalar, const ResultTypeState& in_state); +TORCH_API ScalarType result_type(const ResultTypeState& state); + +TORCH_API ScalarType result_type(ITensorListRef tensors); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/UnaryOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/UnaryOps.h new file mode 100644 index 0000000000000000000000000000000000000000..ffa0b6c4f2b41e196f31780cbd4d75e79cc6225a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/UnaryOps.h @@ -0,0 +1,129 @@ +#pragma once + +#include +#include +#include + +namespace at { +class Tensor; +class TensorBase; +struct TensorIteratorBase; +} + +namespace at::native { + +using unary_fn = void(*)(TensorIteratorBase&); +using unary_fn_with_scalar = void(*)(TensorIteratorBase&, const Scalar& a); + +inline namespace CPU_CAPABILITY { +void conj_kernel(TensorIteratorBase &iter); +void neg_kernel(TensorIteratorBase &iter); +void reciprocal_kernel(TensorIteratorBase &iter); +void rsqrt_kernel(TensorIteratorBase& iter); +void sqrt_kernel(TensorIteratorBase& iter); +} // namespace CPU_CAPABILITY + +DECLARE_DISPATCH(unary_fn, abs_stub) +DECLARE_DISPATCH(unary_fn, angle_stub) +DECLARE_DISPATCH(unary_fn, conj_physical_stub) +DECLARE_DISPATCH(unary_fn, acos_stub) +DECLARE_DISPATCH(unary_fn, acosh_stub) +DECLARE_DISPATCH(unary_fn, asinh_stub) +DECLARE_DISPATCH(unary_fn, atanh_stub) +DECLARE_DISPATCH(unary_fn, asin_stub) +DECLARE_DISPATCH(unary_fn, atan_stub) +DECLARE_DISPATCH(unary_fn, bitwise_not_stub) +DECLARE_DISPATCH(unary_fn, logical_not_stub) +DECLARE_DISPATCH(unary_fn, ceil_stub) +DECLARE_DISPATCH(unary_fn, cos_stub) +DECLARE_DISPATCH(unary_fn, cosh_stub) +DECLARE_DISPATCH(unary_fn, digamma_stub) +DECLARE_DISPATCH(unary_fn, special_entr_stub) +DECLARE_DISPATCH(unary_fn, special_erfcx_stub) +DECLARE_DISPATCH(unary_fn, erf_stub) +DECLARE_DISPATCH(unary_fn, erfc_stub) +DECLARE_DISPATCH(unary_fn, erfinv_stub) +DECLARE_DISPATCH(unary_fn, exp_stub) +DECLARE_DISPATCH(unary_fn, exp2_stub) +DECLARE_DISPATCH(unary_fn, expm1_stub) +DECLARE_DISPATCH(unary_fn, floor_stub) +DECLARE_DISPATCH(unary_fn, frac_stub) +DECLARE_DISPATCH(unary_fn, frexp_stub) +DECLARE_DISPATCH(unary_fn, i0_stub) +DECLARE_DISPATCH(unary_fn, special_i0e_stub) +DECLARE_DISPATCH(unary_fn, special_i1_stub) +DECLARE_DISPATCH(unary_fn, special_i1e_stub) +DECLARE_DISPATCH(unary_fn, log_stub) +DECLARE_DISPATCH(unary_fn, log10_stub) +DECLARE_DISPATCH(unary_fn, log1p_stub) +DECLARE_DISPATCH(unary_fn, log2_stub) +DECLARE_DISPATCH(unary_fn, special_ndtri_stub) +DECLARE_DISPATCH(unary_fn, special_log_ndtr_stub) +DECLARE_DISPATCH(unary_fn, neg_stub) + +DECLARE_DISPATCH(unary_fn, reciprocal_stub) +DECLARE_DISPATCH(unary_fn, round_stub) +DECLARE_DISPATCH(unary_fn, rsqrt_stub) +DECLARE_DISPATCH(unary_fn, sigmoid_stub) +DECLARE_DISPATCH(unary_fn_with_scalar, logit_stub) +DECLARE_DISPATCH(unary_fn, sign_stub) +DECLARE_DISPATCH(unary_fn, signbit_stub) +DECLARE_DISPATCH(unary_fn, sgn_stub) +DECLARE_DISPATCH(unary_fn, sin_stub) +DECLARE_DISPATCH(unary_fn, sinc_stub) +DECLARE_DISPATCH(unary_fn, sinh_stub) +DECLARE_DISPATCH(unary_fn, sqrt_stub) +DECLARE_DISPATCH(unary_fn, tan_stub) +DECLARE_DISPATCH(unary_fn, tanh_stub) +DECLARE_DISPATCH(unary_fn, trigamma_stub) +DECLARE_DISPATCH(unary_fn, trunc_stub) +DECLARE_DISPATCH(unary_fn, lgamma_stub) +DECLARE_DISPATCH(unary_fn, special_airy_ai_stub) +DECLARE_DISPATCH(unary_fn, special_bessel_j0_stub) +DECLARE_DISPATCH(unary_fn, special_bessel_j1_stub) +DECLARE_DISPATCH(unary_fn, special_bessel_y0_stub) +DECLARE_DISPATCH(unary_fn, special_bessel_y1_stub) +DECLARE_DISPATCH(unary_fn, special_modified_bessel_i0_stub) +DECLARE_DISPATCH(unary_fn, special_modified_bessel_i1_stub) +DECLARE_DISPATCH(unary_fn, special_modified_bessel_k0_stub) +DECLARE_DISPATCH(unary_fn, special_modified_bessel_k1_stub) +DECLARE_DISPATCH(unary_fn, special_scaled_modified_bessel_k0_stub) +DECLARE_DISPATCH(unary_fn, special_scaled_modified_bessel_k1_stub) +DECLARE_DISPATCH(unary_fn, special_spherical_bessel_j0_stub) + +// NB: these are actually defined in Distribution +DECLARE_DISPATCH(void(*)(const TensorBase&, const TensorBase&, std::optional), bernoulli_tensor_stub) +DECLARE_DISPATCH(void(*)(const TensorBase&, const double, std::optional), bernoulli_scalar_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, const double, const double, std::optional), cauchy_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, const double, std::optional), exponential_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, const double, std::optional), geometric_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, const double, const double, std::optional), log_normal_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, const double, const double, std::optional), uniform_stub) +DECLARE_DISPATCH(void(*)(const TensorBase&, const double, const double, std::optional), normal_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, const uint64_t, const int64_t, std::optional), random_from_to_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, std::optional), random_full_64_bits_range_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, std::optional), random_stub) + +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, const int64_t, const double), kaiser_window_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, const int64_t), polygamma_stub) +DECLARE_DISPATCH(void(*)(TensorIteratorBase&, const Scalar& a, const Scalar& b), clamp_stub) +DECLARE_DISPATCH( + void (*)(Tensor&, const Tensor&, int64_t, std::optional), + multinomial_with_replacement_stub) +DECLARE_DISPATCH( + void (*)( + TensorIteratorBase&, + std::optional, + std::optional, + std::optional), + nan_to_num_stub) +DECLARE_DISPATCH(void (*)(TensorIteratorBase&, int64_t), round_decimals_stub) + +// Missing unary functions +// digamma +// lgamma +// erfinv +// clone +// contiguous +// zero +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Unfold2d.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Unfold2d.h new file mode 100644 index 0000000000000000000000000000000000000000..73ea7dc28235d515ac543344d6f4884c795c6ea0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Unfold2d.h @@ -0,0 +1,48 @@ +#pragma once + +#include +#include +#include + +namespace at::native { + +using unfold2d_copy_fn = void (*)( + ScalarType dtype, + void *finput, + const void *input, + int64_t kH, + int64_t kW, + int64_t dH, + int64_t dW, + int64_t padH, + int64_t padW, + int64_t n_input_plane, + int64_t input_height, + int64_t input_width, + int64_t output_height, + int64_t output_width, + bool is_channels_last +); + +using unfold2d_acc_fn = void (*)( + ScalarType dtype, + void *finput, + void *input, + int64_t kH, + int64_t kW, + int64_t dH, + int64_t dW, + int64_t padH, + int64_t padW, + int64_t n_input_plane, + int64_t input_height, + int64_t input_width, + int64_t output_height, + int64_t output_width, + bool is_channels_last +); + +DECLARE_DISPATCH(unfold2d_copy_fn, unfolded2d_copy_stub) +DECLARE_DISPATCH(unfold2d_acc_fn, unfolded2d_acc_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Unfold3d.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Unfold3d.h new file mode 100644 index 0000000000000000000000000000000000000000..90ead9d1f7ad48187b8c0a28af2fd59915887d17 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/Unfold3d.h @@ -0,0 +1,49 @@ +#pragma once + +#include + +namespace at::native { + +void Unfold3dCopyCPU( + ScalarType dtype, + const void *src, + int64_t C, + int64_t X_D, + int64_t X_H, + int64_t X_W, + int64_t Y_D, + int64_t Y_H, + int64_t Y_W, + int64_t kernel_d, + int64_t kernel_h, + int64_t kernel_w, + int64_t stride_d, + int64_t stride_h, + int64_t stride_w, + int64_t pad_d, + int64_t pad_h, + int64_t pad_w, + void* dst); + +void Unfold3dAccCPU( + ScalarType dtype, + const void *src, + int64_t C, + int64_t X_D, + int64_t X_H, + int64_t X_W, + int64_t Y_D, + int64_t Y_H, + int64_t Y_W, + int64_t kernel_d, + int64_t kernel_h, + int64_t kernel_w, + int64_t stride_d, + int64_t stride_h, + int64_t stride_w, + int64_t pad_d, + int64_t pad_h, + int64_t pad_w, + void *dst); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/UnfoldBackward.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/UnfoldBackward.h new file mode 100644 index 0000000000000000000000000000000000000000..3030cb54aea677029904b84238802d3bf00e062f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/UnfoldBackward.h @@ -0,0 +1,110 @@ +#pragma once + +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + +namespace at::native { + +using unfold_backward_fn = void (*)( + Tensor& grad_in, + const Tensor& grad, + int64_t dim, + int64_t size, + int64_t step +); + +DECLARE_DISPATCH(unfold_backward_fn, unfold_backward_stub) + +namespace { + +// Note on naming: it is unconventional. +// grad_in does not mean that it is a gradient wrt to input, +// grad_in/grad_out is just an input/output of unfold_backward kernel. + +[[maybe_unused]] static TensorIterator _make_unfold_backward_iter_over_grad_out( + Tensor& grad_out, + const Tensor& grad_in, + int64_t dim, + int64_t size, + int64_t step) { + dim = maybe_wrap_dim(dim, grad_out.dim()); + // last dim stores the folds + + auto grad_out_dim_size = ensure_nonempty_size(grad_out, dim); + auto grad_in_dim_size = ensure_nonempty_size(grad_in, dim); + // dictates the number of elements to iterate over + // in dimension `dim` + auto iter_dim_size = std::min( + grad_out_dim_size, + (grad_in_dim_size - 1) * step + size + ); + + /* prepare grad_out for TensorIterator { */ + auto grad_out_strides = ensure_nonempty_vec(grad_out.strides().vec()); + auto grad_out_sizes = ensure_nonempty_vec(grad_out.sizes().vec()); + grad_out_sizes[dim] = iter_dim_size; + auto grad_out_restrided = grad_out.as_strided( + grad_out_sizes, grad_out_strides + ); + /* } */ + + /* prepare grad_in for TensorIterator { */ + auto grad_in_strides = ensure_nonempty_vec(grad_in.strides().vec()); + auto grad_in_sizes = ensure_nonempty_vec(grad_in.sizes().vec()); + + // set strides for dim to 0 + // and size to 1 because + // this dimension is indexed inside the kernel + grad_in_strides[dim] = 0; + grad_in_sizes[dim] = 1; + + grad_in_strides.pop_back(); + grad_in_sizes.pop_back(); + + auto grad_in_restrided = grad_in.squeeze(-1).as_strided( + grad_in_sizes, grad_in_strides + ); + /* } */ + + // During the TensorIterator iteration we have to know + // i_dim in grad_out[i_1,...,i_dim,...i_n], + // idx_dim stores this information + /* prepare idx_dim for TensorIterator { */ + auto idx_dim = at::arange( + 0, iter_dim_size, grad_in.options().dtype(at::kLong) + ); + + auto grad_out_dim = ensure_nonempty_dim(grad_out.dim()); + + auto idx_dim_strides = std::vector(grad_out_dim, 0); + auto idx_dim_sizes = std::vector(grad_out_dim, 1); + + idx_dim_strides[dim] = 1; + idx_dim_sizes[dim] = iter_dim_size; + + // idx_dim size will broadcast over determined by grad_out sizes in TensorIterator + auto idx_dim_restrided = idx_dim.as_strided(idx_dim_sizes, idx_dim_strides); + /* } */ + + auto iter = TensorIteratorConfig() + .set_check_mem_overlap(false) + .check_all_same_dtype(false) + .resize_outputs(false) + .add_owned_output(grad_out_restrided) + .add_owned_const_input(grad_in_restrided) + .add_owned_const_input(idx_dim_restrided) + .build(); + + return iter; +} +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/UpSample.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/UpSample.h new file mode 100644 index 0000000000000000000000000000000000000000..541207a537a0eb362994391bb5df4567230349b2 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/UpSample.h @@ -0,0 +1,510 @@ +#pragma once + +#include + +#include +#include +#include +#include +#include +#include +#include +#include + +/** + * Note [compute_scales_value] + * Note [area_pixel_compute_scale] + * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + * Interpolate with scale_factor can have different behaviors + * depending on the value of recompute_scale_factor: + * + * - With recompute_scale_factor = True (current default behavior): + * the scale_factor, when provided by the user, are used to calculate + * the output size. The input size and the computed output_size + * are then used to infer new values for the scales which are + * used in the interpolation. Because floating-point math is not exact, + * this may be a different value from the user-supplied scales. + * + * - With recompute_scale_factor = False (which will be the default + * behavior starting 1.5.0): + * the behavior follows opencv logic, and the scales provided by + * the user are the ones used in the interpolation calculations. + * + * If the scales are not provided or if they are provided but + * recompute_scale_factor is set to True (default behavior), the scales + * are computed from the input and the output size; + * + * + * When the scales are inferred from the input and output sizes, + * we view each pixel as an area, idx + 0.5 as its center index. + * Here is an example formula in 1D case. + * if align_corners: center of two corner pixel areas are preserved, + * (0.5, 0.5) -> (0.5, 0.5), + * (input_size - 0.5, 0.5) -> (output_size - 0.5) + * scale = (input_size - 0.5 - 0.5) / (output_size - 0.5 - 0.5) + * src_index + 0.5 - 0.5 = scale * (dst_index + 0.5 - 0.5) + * if not align_corners: the whole range is scaled accordingly + * scale = input_size / output_size + * src_idx + 0.5 = scale * (dst_index + 0.5) + */ + +namespace at::native { + +namespace upsample { + +TORCH_API c10::SmallVector compute_output_size( + c10::IntArrayRef input_size, // Full input tensor size. + at::OptionalIntArrayRef output_size, + std::optional> scale_factors); + +inline std::optional get_scale_value(std::optional> scales, int idx) { + if (!scales) { + return std::nullopt; + } + return scales->at(idx); +} + +} // namespace upsample + +using scale_t = std::optional; +using upsampling_nearest1d = void(*)(const Tensor& output, const Tensor& input, scale_t scales_w); +using _upsampling_nearest_exact1d = void(*)(const Tensor& output, const Tensor& input, scale_t scales_w); +using upsampling_nearest2d = void(*)(const Tensor& output, const Tensor& input, scale_t scales_h, scale_t scales_w); +using _upsampling_nearest_exact2d = void(*)(const Tensor& output, const Tensor& input, scale_t scales_h, scale_t scales_w); +using upsampling_nearest3d = void(*)(const Tensor& output, const Tensor& input, scale_t scales_d, scale_t scales_h, scale_t scales_w); +using _upsampling_nearest_exact3d = void(*)(const Tensor& output, const Tensor& input, scale_t scales_d, scale_t scales_h, scale_t scales_w); +using upsampling_linear1d = void(*)(const Tensor& output, const Tensor& input, bool align_corners, scale_t scales_w); +using upsampling_bilinear2d = void(*)(const Tensor& output, const Tensor& input, bool align_corners, scale_t scales_h, scale_t scales_w); +using _upsampling_bilinear2d_aa = void(*)(const Tensor& output, const Tensor& input, bool align_corners, scale_t scales_h, scale_t scales_w); +using upsampling_trilinear3d = void(*)(const Tensor& output, const Tensor& input, bool align_corners, scale_t scales_d, scale_t scales_h, scale_t scales_w); +using upsampling_bicubic2d = void(*)(const Tensor& output, const Tensor& input, bool align_corners, scale_t scales_h, scale_t scales_w); +using _upsampling_bicubic2d_aa = void(*)(const Tensor& output, const Tensor& input, bool align_corners, scale_t scales_h, scale_t scales_w); +DECLARE_DISPATCH(upsampling_nearest1d, upsample_nearest1d_kernel) +DECLARE_DISPATCH(_upsampling_nearest_exact1d, _upsample_nearest_exact1d_kernel) +DECLARE_DISPATCH(upsampling_nearest2d, upsample_nearest2d_kernel) +DECLARE_DISPATCH(_upsampling_nearest_exact2d, _upsample_nearest_exact2d_kernel) +DECLARE_DISPATCH(upsampling_nearest3d, upsample_nearest3d_kernel) +DECLARE_DISPATCH(_upsampling_nearest_exact3d, _upsample_nearest_exact3d_kernel) +DECLARE_DISPATCH(upsampling_nearest1d, upsample_nearest1d_backward_kernel) +DECLARE_DISPATCH(_upsampling_nearest_exact1d, _upsample_nearest_exact1d_backward_kernel) +DECLARE_DISPATCH(upsampling_nearest2d, upsample_nearest2d_backward_kernel) +DECLARE_DISPATCH(_upsampling_nearest_exact2d, _upsample_nearest_exact2d_backward_kernel) +DECLARE_DISPATCH(upsampling_nearest3d, upsample_nearest3d_backward_kernel) +DECLARE_DISPATCH(_upsampling_nearest_exact3d, _upsample_nearest_exact3d_backward_kernel) +DECLARE_DISPATCH(upsampling_linear1d, upsample_linear1d_kernel) +DECLARE_DISPATCH(upsampling_bilinear2d, upsample_bilinear2d_kernel) +DECLARE_DISPATCH(_upsampling_bilinear2d_aa, _upsample_bilinear2d_aa_kernel) +DECLARE_DISPATCH(upsampling_trilinear3d, upsample_trilinear3d_kernel) +DECLARE_DISPATCH(upsampling_linear1d, upsample_linear1d_backward_kernel) +DECLARE_DISPATCH(upsampling_bilinear2d, upsample_bilinear2d_backward_kernel) +DECLARE_DISPATCH(_upsampling_bilinear2d_aa, _upsample_bilinear2d_aa_backward_kernel) +DECLARE_DISPATCH(upsampling_trilinear3d, upsample_trilinear3d_backward_kernel) +DECLARE_DISPATCH(upsampling_bicubic2d, upsample_bicubic2d_kernel) +DECLARE_DISPATCH(_upsampling_bicubic2d_aa, _upsample_bicubic2d_aa_kernel) +DECLARE_DISPATCH(_upsampling_bicubic2d_aa, _upsample_bicubic2d_aa_backward_kernel) + +[[maybe_unused]] inline std::array upsample_1d_common_check( + IntArrayRef input_size, + IntArrayRef output_size) { + TORCH_CHECK( + output_size.size() == 1, + "It is expected output_size equals to 1, but got size ", + output_size.size()); + + TORCH_CHECK( + input_size.size() == 3, + "It is expected input_size equals to 3, but got size ", + input_size.size()); + + int64_t output_width = output_size[0]; + + int64_t nbatch = input_size[0]; + int64_t channels = input_size[1]; + int64_t input_width = input_size[2]; + + TORCH_CHECK( + input_width > 0 && output_width > 0, + "Input and output sizes should be greater than 0, but got input (W: ", + input_width, + ") and output (W: ", + output_width, + ")"); + + return {nbatch, channels, output_width}; +} + +[[maybe_unused]] inline std::array upsample_2d_common_check( + IntArrayRef input_size, + IntArrayRef output_size) { + TORCH_CHECK( + output_size.size() == 2, + "It is expected output_size equals to 2, but got size ", + output_size.size()); + + TORCH_CHECK( + input_size.size() == 4, + "It is expected input_size equals to 4, but got size ", + input_size.size()); + + int64_t output_height = output_size[0]; + int64_t output_width = output_size[1]; + + int64_t nbatch = input_size[0]; + int64_t channels = input_size[1]; + int64_t input_height = input_size[2]; + int64_t input_width = input_size[3]; + + TORCH_CHECK( + input_height > 0 && input_width > 0 && output_height > 0 && + output_width > 0, + "Input and output sizes should be greater than 0," + " but got input (H: ", + input_height, + ", W: ", + input_width, + ") output (H: ", + output_height, + ", W: ", + output_width, + ")"); + + return {nbatch, channels, output_height, output_width}; +} + +[[maybe_unused]] inline std::array upsample_3d_common_check( + IntArrayRef input_size, + IntArrayRef output_size) { + TORCH_CHECK( + output_size.size() == 3, + "It is expected output_size equals to 3, but got size ", + output_size.size()); + + TORCH_CHECK( + input_size.size() == 5, + "It is expected input_size equals to 5, but got size ", + input_size.size()); + + int64_t output_depth = output_size[0]; + int64_t output_height = output_size[1]; + int64_t output_width = output_size[2]; + + int64_t nbatch = input_size[0]; + int64_t channels = input_size[1]; + int64_t input_depth = input_size[2]; + int64_t input_height = input_size[3]; + int64_t input_width = input_size[4]; + + TORCH_CHECK( + input_depth > 0 && input_height > 0 && input_width > 0 && + output_depth > 0 && output_height > 0 && output_width > 0, + "Input and output sizes should be greater than 0, but got input (D: ", + input_depth, + ", H: ", + input_height, + ", W: ", + input_width, + ") output (D: ", + output_depth, + ", H: ", + output_height, + ", W: ", + output_width, + ")"); + + + return {nbatch, channels, output_depth, output_height, output_width}; +} + +inline void upsample_2d_shape_check( + const Tensor& input, + const Tensor& grad_output, + int64_t nbatch, + int64_t nchannels, + int64_t input_height, + int64_t input_width, + int64_t output_height, + int64_t output_width) { + TORCH_CHECK( + input_height > 0 && input_width > 0 && output_height > 0 && + output_width > 0, + "Input and output sizes should be greater than 0," + " but got input (H: ", + input_height, + ", W: ", + input_width, + ") output (H: ", + output_height, + ", W: ", + output_width, + ")"); + + if (input.defined()) { + // Allow for empty batch size but not other dimensions + TORCH_CHECK( + (input.numel() != 0 || + (input.size(1) != 0 && input.size(2) != 0 && input.size(3) != 0) + ) && + input.dim() == 4, + "Non-empty 4D data tensor expected but got a tensor with sizes ", + input.sizes()); + } else if (grad_output.defined()) { + check_dim_size(grad_output, 4, 0, nbatch); + check_dim_size(grad_output, 4, 1, nchannels); + check_dim_size(grad_output, 4, 2, output_height); + check_dim_size(grad_output, 4, 3, output_width); + } +} + +template +inline scalar_t compute_scales_value( + const std::optional scale, + int64_t input_size, + int64_t output_size) { + // see Note [compute_scales_value] + // FIXME: remove magic > 0 after we ensure no models were serialized with -1 defaults. + return (scale.has_value() && scale.value() > 0.) + ? static_cast(1.0 / scale.value()) + : (static_cast(input_size) / output_size); +} + +template +inline scalar_t area_pixel_compute_scale( + int64_t input_size, + int64_t output_size, + bool align_corners, + const std::optional scale) { + // see Note [area_pixel_compute_scale] + if(align_corners) { + if(output_size > 1) { + return static_cast(input_size - 1) / (output_size - 1); + } else { + return static_cast(0); + } + } else { + return compute_scales_value(scale, input_size, output_size); + } +} + +template +inline scalar_t area_pixel_compute_source_index( + scalar_t scale, + int64_t dst_index, + bool align_corners, + bool cubic) { + if (align_corners) { + return scale * dst_index; + } else { + scalar_t src_idx = scale * (dst_index + static_cast(0.5)) - + static_cast(0.5); + // [Note] Follow Opencv resize logic: + // We allow negative src_idx here and later will use + // dx = src_idx - floorf(src_idx) + // to compute the "distance"(which affects weights). + // For linear modes, weight distribution doesn't matter + // for negative indices as they use 2 pixels to interpolate. + // For example, [-1, 0], they both use pixel 0 value so it + // doesn't affect if we bound the src_idx to 0 or not. + // TODO: Our current linear mode impls use unbound indices + // where we should and then remove this cubic flag. + // This matters in cubic mode, as we might need [-1, 0, 1, 2] + // to interpolate and the weights can be affected. + return (!cubic && src_idx < static_cast(0)) ? scalar_t(0) + : src_idx; + } +} + +inline int64_t nearest_neighbor_compute_source_index( + const float scale, + int64_t dst_index, + int64_t input_size) { + // Index computation matching OpenCV INTER_NEAREST + // which is buggy and kept for BC + const int64_t src_index = + std::min(static_cast(floorf(dst_index * scale)), input_size - 1); + return src_index; +} + +inline int64_t nearest_neighbor_exact_compute_source_index( + const float scale, + int64_t dst_index, + int64_t input_size) { + // index_f32 = (output_index + 0.5) * scale - 0.5 + // input_index = round(index_f32) + // Same as Pillow and Scikit-Image/Scipy ndi.zoom + const int64_t src_index = + std::min(static_cast(floorf((dst_index + 0.5) * scale)), input_size - 1); + return src_index; +} + +inline int64_t nearest_idx( + int64_t output_index, + int64_t input_size, + int64_t output_size, + std::optional scales) { + // This method specificly treats cases: output_size == input_size or + // output_size == 2 * input_size, that we would like to get rid of + // We keep this method for BC and consider as deprecated. + // See nearest_exact_idx as replacement + if (output_size == input_size) { + // scale_factor = 1, simply copy + return output_index; + } else if (output_size == 2 * input_size) { + // scale_factor = 2, shift input index + return output_index >> 1; + } else { + float scale = compute_scales_value(scales, input_size, output_size); + return nearest_neighbor_compute_source_index(scale, output_index, input_size); + } +} + +inline int64_t nearest_exact_idx( + int64_t output_index, + int64_t input_size, + int64_t output_size, + std::optional scales) { + float scale = compute_scales_value(scales, input_size, output_size); + return nearest_neighbor_exact_compute_source_index(scale, output_index, input_size); +} + +// Define a typedef to dispatch to nearest_idx or nearest_exact_idx +typedef int64_t (*nearest_idx_fn_t)(int64_t, int64_t, int64_t, std::optional); + +template +scalar_t upsample_get_value_bounded( + scalar_t* data, + int64_t width, + int64_t height, + int64_t x, + int64_t y) { + int64_t access_x = std::max(std::min(x, width - 1), static_cast(0)); + int64_t access_y = std::max(std::min(y, height - 1), static_cast(0)); + return data[access_y * width + access_x]; +} + +template +void upsample_increment_value_bounded( + scalar_t* data, + int64_t width, + int64_t height, + int64_t x, + int64_t y, + scalar_t value) { + int64_t access_x = std::max(std::min(x, width - 1), static_cast(0)); + int64_t access_y = std::max(std::min(y, height - 1), static_cast(0)); + data[access_y * width + access_x] += value; +} + +// Based on +// https://en.wikipedia.org/wiki/Bicubic_interpolation#Bicubic_convolution_algorithm +template +scalar_t cubic_convolution1(scalar_t x, scalar_t A) { + return ((A + 2) * x - (A + 3)) * x * x + 1; +} + +template +scalar_t cubic_convolution2(scalar_t x, scalar_t A) { + return ((A * x - 5 * A) * x + 8 * A) * x - 4 * A; +} + +template +void get_cubic_upsample_coefficients( + scalar_t coeffs[4], + scalar_t t) { + scalar_t A = -0.75; + + scalar_t x1 = t; + coeffs[0] = cubic_convolution2(x1 + 1.0, A); + coeffs[1] = cubic_convolution1(x1, A); + + // opposite coefficients + scalar_t x2 = 1.0 - t; + coeffs[2] = cubic_convolution1(x2, A); + coeffs[3] = cubic_convolution2(x2 + 1.0, A); +} + +template +inline scalar_t cubic_interp1d( + scalar_t x0, + scalar_t x1, + scalar_t x2, + scalar_t x3, + scalar_t t) { + scalar_t coeffs[4]; + get_cubic_upsample_coefficients(coeffs, t); + + return x0 * coeffs[0] + x1 * coeffs[1] + x2 * coeffs[2] + x3 * coeffs[3]; +} + +// when `real_input_index` becomes larger than the range the floating point +// type can accurately represent, the type casting to `int64_t` might exceed +// `input_size`, causing overflow. So we guard it with `std::min` below. +template +inline void guard_index_and_lambda(const opmath_t& real_input_index, const int64_t& input_size, int64_t& input_index, scalar_t& lambda) { + input_index = std::min(static_cast(floorf(real_input_index)), input_size - 1); + lambda = std::min( + std::max(real_input_index - input_index, static_cast(0)), + static_cast(1) + ); +} + +template +inline void compute_source_index_and_lambda( + int64_t& input_index0, + int64_t& input_index1, + scalar_t& lambda0, + scalar_t& lambda1, + opmath_t ratio, + int64_t output_index, + int64_t input_size, + int64_t output_size, + bool align_corners) { + if (output_size == input_size) { + // scale_factor = 1, simply copy + input_index0 = output_index; + input_index1 = output_index; + lambda0 = static_cast(1); + lambda1 = static_cast(0); + } else { + const auto real_input_index = + area_pixel_compute_source_index( + ratio, output_index, align_corners, /*cubic=*/false); + guard_index_and_lambda(real_input_index, input_size, input_index0, lambda1); + int64_t offset = (input_index0 < input_size - 1) ? 1 : 0; + input_index1 = input_index0 + offset; + lambda0 = static_cast(1.) - lambda1; + } +} + +// It will not be used by data types other than BFloat16 and Half. +template || !std::is_same_v, int> = 0> +void inline apply_grad_input(scalar_in* buffer_ptr, scalar_out* gin, int64_t size) { + TORCH_CHECK((is_reduced_floating_point_v), + "Upsample backward only support BFloat16 and Half in the lower precision data types on CPU.") + TORCH_CHECK((std::is_same_v), + "Upsample backward should use float as acc buffer for BFloat16 and Half grad input on CPU.") + return; +} + +template && std::is_same_v, int> = 0> +void inline apply_grad_input(scalar_in* buffer_ptr, scalar_out* gin, int64_t size) { + using bVec = Vectorized; + using fVec = Vectorized; + int64_t d = 0; + for (; d < size - (size % bVec::size()); d += bVec::size()) { + bVec gin_bvec = bVec::loadu(gin + d); + auto [gin_fvec0, gin_fvec1] = convert_to_float(gin_bvec); + gin_fvec0 += fVec::loadu(buffer_ptr + d); + gin_fvec1 += fVec::loadu(buffer_ptr + d + fVec::size()); + fVec(0).store(buffer_ptr + d); + fVec(0).store(buffer_ptr + d + fVec::size()); + convert_from_float(gin_fvec0, gin_fvec1).store(gin + d); + } + for (; d < size; d++) { + gin[d] += buffer_ptr[d]; + buffer_ptr[d] = 0; + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/batch_norm.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/batch_norm.h new file mode 100644 index 0000000000000000000000000000000000000000..9564594511e937f561b64062f6f127cbe3bf023e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/batch_norm.h @@ -0,0 +1,38 @@ +#pragma once + +#include +#include + +namespace at::native { + +using batch_norm_fn = void (*)(Tensor&, const Tensor&, const Tensor&, + const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, bool, double); +using batch_norm_collect_stats_fn = void (*)(Tensor&, Tensor&, const Tensor&); +using batch_norm_backward_fn = void(*)(Tensor&, Tensor&, Tensor&, const Tensor&, + const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, bool, double); + +DECLARE_DISPATCH(batch_norm_fn, batch_norm_cpu_stub) +DECLARE_DISPATCH(batch_norm_collect_stats_fn, batch_norm_cpu_collect_stats_stub) +DECLARE_DISPATCH(batch_norm_backward_fn, batch_norm_cpu_backward_stub) + +// TensorAccessor when it is defined to work around undefined... +template +static TensorAccessor conditional_accessor_1d(const Tensor& t) { + if (! t.defined()) { + return TensorAccessor(nullptr, nullptr, nullptr); + } + return t.accessor(); +} + +template +static scalar_t* conditional_data_ptr(const Tensor& t) { + if constexpr (std::is_const_v) { + return t.defined() ? t.contiguous().const_data_ptr() + : nullptr; + } else { + return t.defined() ? t.contiguous().data_ptr() + : nullptr; + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/AtomicAddFloat.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/AtomicAddFloat.h new file mode 100644 index 0000000000000000000000000000000000000000..5b24ee4821c45baab25f37a3bfa3399eff8a1716 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/AtomicAddFloat.h @@ -0,0 +1,37 @@ +#ifndef ATOMIC_ADD_FLOAT +#define ATOMIC_ADD_FLOAT + +#if (defined(__x86_64__) || defined(__i386__) || defined(__aarch64__)) +#include +#else +#define _mm_pause() +#endif + +#include + +static inline void cpu_atomic_add_float(float* dst, float fvalue) +{ + typedef union { + unsigned intV; + float floatV; + } uf32_t; + + uf32_t new_value, old_value; + std::atomic* dst_intV = (std::atomic*)(dst); + + old_value.floatV = *dst; + new_value.floatV = old_value.floatV + fvalue; + + unsigned* old_intV = (unsigned*)(&old_value.intV); + while (!std::atomic_compare_exchange_strong(dst_intV, old_intV, new_value.intV)) { +#ifdef __aarch64__ + __asm__ __volatile__("yield;" : : : "memory"); +#else + _mm_pause(); +#endif + old_value.floatV = *dst; + new_value.floatV = old_value.floatV + fvalue; + } +} + +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/CatKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/CatKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..29fc21eb1ccf9ef432026feac82f013070637194 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/CatKernel.h @@ -0,0 +1,12 @@ +#pragma once + +#include +#include +#include + +namespace at::native { + +using cat_serial_fn = void(*)(const Tensor &, const MaterializedITensorListRef&, int64_t); +DECLARE_DISPATCH(cat_serial_fn, cat_serial_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/ChannelShuffleKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/ChannelShuffleKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..c3d8990220831ec61b22cf221ad26478dcaf0b64 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/ChannelShuffleKernel.h @@ -0,0 +1,14 @@ +#pragma once +#include +#include + +namespace at { +class TensorBase; +} + +namespace at::native { + +using channel_shuffle_fn = void(*)(TensorBase&, const TensorBase&, int64_t); +DECLARE_DISPATCH(channel_shuffle_fn, channel_shuffle_kernel) + +} // at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/CopyKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/CopyKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..3378e16f93d23e6c317b98f4469e660086b0082a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/CopyKernel.h @@ -0,0 +1,14 @@ +#pragma once + +#include + +namespace at { +struct TensorIteratorBase; + +namespace native { +inline namespace CPU_CAPABILITY { + +void direct_copy_kernel(TensorIteratorBase &iter); +void copy_kernel(TensorIterator& iter, bool /*non_blocking*/); + +}}} // namespace at::native::CPU_CAPABILITY diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/DepthwiseConvKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/DepthwiseConvKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..ac2a0423af113dbc583597d12993d4402d682194 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/DepthwiseConvKernel.h @@ -0,0 +1,21 @@ +#pragma once + +#include +#include + +/* + Depthwise 3x3 Winograd convolution operator +*/ + +namespace at { +class Tensor; + +namespace native { + +using convolution_depthwise3x3_winograd_fn = + Tensor (*)(const Tensor &, const Tensor &, const Tensor &, IntArrayRef, IntArrayRef, int64_t); + +DECLARE_DISPATCH(convolution_depthwise3x3_winograd_fn, convolution_depthwise3x3_winograd_stub) + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/DistributionTemplates.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/DistributionTemplates.h new file mode 100644 index 0000000000000000000000000000000000000000..8171ae8e79ad2a1311f4a8600decd202c66649d5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/DistributionTemplates.h @@ -0,0 +1,425 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include + +#ifdef CPU_CAPABILITY_AVX2 +#include +#include +#endif + + + + +namespace at::native::templates::cpu { +namespace { + +// ==================================================== Random ======================================================== + +template +void random_from_to_kernel(TensorIteratorBase& iter, uint64_t range, int64_t base, RNG generator) { + AT_DISPATCH_V2(iter.dtype(), "random_from_to_kernel_cpu", AT_WRAP([&] { + std::lock_guard lock(generator->mutex_); + cpu_serial_kernel(iter, [range, base, generator]() -> scalar_t { + uniform_int_from_to_distribution random(range, base); + return random(generator); + }); + }), kBool, kHalf, kBFloat16, AT_EXPAND(AT_ALL_TYPES), AT_EXPAND(AT_BAREBONES_UNSIGNED_TYPES)); +} + +// This is the special kernel to handle single specific case: +// from(inclusive) = std::numeric_limits::lowest() +// to(exclusive) = None (= std::numeric_limits::max() + 1) +template +void random_full_64_bits_range_kernel(TensorIteratorBase& iter, RNG generator) { + AT_DISPATCH_ALL_TYPES_AND(at::ScalarType::BFloat16, iter.dtype(), "random_full_64_bits_range_kernel_cpu", [&] { + if constexpr (std::is_same_v || + std::is_same_v || + std::is_same_v || + std::is_same_v) { + std::lock_guard lock(generator->mutex_); + cpu_serial_kernel(iter, [generator]() -> scalar_t { + uniform_int_full_range_distribution random; + return random(generator); + }); + } else { + TORCH_CHECK(false, "random_full_64_bits_range_kernel_cpu handles only int64, double, float and bfloat16"); + } + }); +} + +template +struct RandomFromToKernel { + void operator()(TensorIteratorBase& iter, uint64_t range, int64_t base, std::optional gen) { + random_from_to_kernel(iter, range, base, check_generator(gen)); + } + void operator()(TensorIteratorBase& iter, std::optional gen) { + random_full_64_bits_range_kernel(iter, check_generator(gen)); + } +}; + +template +void random_kernel(TensorIteratorBase& iter, RNG generator) { + std::lock_guard lock(generator->mutex_); + AT_DISPATCH_ALL_TYPES_AND3(at::ScalarType::Half, at::ScalarType::BFloat16, at::ScalarType::Bool, iter.dtype(), "random_kernel_cpu", [&] { + cpu_serial_kernel(iter, [generator]() -> scalar_t { + uniform_int_distribution random; + return random(generator); + }); + }); +} + +template +struct RandomKernel { + void operator()(TensorIteratorBase& iter, std::optional gen) { + random_kernel(iter, check_generator(gen)); + } +}; + +// ==================================================== Normal ======================================================== + +#ifdef CPU_CAPABILITY_AVX2 +static void normal_fill_16_AVX2(float *data, + const __m256* two_pi, + const __m256* one, + const __m256* minus_two, + const __m256* mean, + const __m256* std_v) { + const __m256 u1 = _mm256_sub_ps(*one, _mm256_loadu_ps(data)); + const __m256 u2 = _mm256_loadu_ps(data + 8); + // sincos256_ps and log256_ps are from avx_mathfun.h + const __m256 radius = _mm256_sqrt_ps(_mm256_mul_ps(*minus_two, log256_ps(u1))); + const __m256 theta = _mm256_mul_ps(*two_pi, u2); + __m256 sintheta, costheta; + sincos256_ps(theta, &sintheta, &costheta); + const __m256 n1 = _mm256_mul_ps(radius, costheta); + const __m256 n2 = _mm256_mul_ps(radius, sintheta); + _mm256_storeu_ps(data, _mm256_fmadd_ps(n1, *std_v, *mean)); + _mm256_storeu_ps(data + 8, _mm256_fmadd_ps(n2, *std_v, *mean)); +} + +template +void normal_fill_AVX2(const TensorBase &self, const float mean, const float std, RNG generator) { + float *data = self.data_ptr(); + auto size = self.numel(); + std::lock_guard lock(generator->mutex_); + for (const auto i : c10::irange(size)) { + at::uniform_real_distribution uniform(0, 1); + data[i] = uniform(generator); + } + const __m256 two_pi = _mm256_set1_ps(2.0f * c10::pi); + const __m256 one = _mm256_set1_ps(1.0f); + const __m256 minus_two = _mm256_set1_ps(-2.0f); + const __m256 mean_v = _mm256_set1_ps(mean); + const __m256 std_v = _mm256_set1_ps(std); + + for (int64_t i = 0; i < size - 15; i += 16) { + normal_fill_16_AVX2(data + i, &two_pi, &one, &minus_two, &mean_v, &std_v); + } + + if (size % 16 != 0) { + // Recompute the last 16 values. + data = data + size - 16; + for (const auto i : c10::irange(16)) { + at::uniform_real_distribution uniform(0, 1); + data[i] = uniform(generator); + } + normal_fill_16_AVX2(data, &two_pi, &one, &minus_two, &mean_v, &std_v); + } +} +#endif + +template +static void normal_fill_16(scalar_t *data, const scalar_t mean, const scalar_t std) { + for (const auto j : c10::irange(8)) { + const scalar_t u1 = 1 - data[j]; // [0, 1) -> (0, 1] for log. + const scalar_t u2 = data[j + 8]; + const scalar_t radius = std::sqrt(-2 * std::log(u1)); + const scalar_t theta = 2.0f * c10::pi * u2; + data[j] = radius * std::cos(theta) * std + mean; + data[j + 8] = radius * std::sin(theta) * std + mean; + } +} + +#if defined(__VSX__) || defined(CPU_CAPABILITY_VSX) +static void normal_fill_16_VSX(float *data,const Vectorized &two_pi,const Vectorized &one,const Vectorized &minus_two,const Vectorized &mean,const Vectorized &std) { + using Vec = Vectorized; + Vec u1=one-Vec::loadu(data); + Vec u2=Vec::loadu(data+8); + Vec radius=(minus_two * u1.log()); + radius=radius.sqrt(); + Vec theta=two_pi * u2; + Vec output_vec=radius * theta.cos() * std + mean; + Vec output_vec2=radius * theta.sin() * std + mean; + output_vec.store(data); + output_vec2.store(data+8); +} + +template +void normal_fill_VSX(const TensorBase &self, const scalar_t mean, const scalar_t std, RNG generator) { + float *data = self.data_ptr(); + auto size = self.numel(); + std::lock_guard lock(generator->mutex_); + for (const auto i : c10::irange(size)) { + at::uniform_real_distribution uniform(0, 1); + data[i] = uniform(generator); + } + + using Vec = Vectorized; + const Vec two_pi = Vec(2.0f * c10::pi); + const Vec one = Vec(1.0f); + const Vec minus_two = Vec(-2.0f); + const Vec var_vec = Vec(std); + const Vec mean_vec = Vec(mean); + + for (int64_t i = 0; i < size - 15; i += 16) { + if(Vec::size()==8) { + normal_fill_16_VSX(data + i, two_pi, one, minus_two, mean_vec, var_vec); + } + else{ + normal_fill_16(data + i, mean, std); + } + } + if (size % 16 != 0) { + // Recompute the last 16 values. + data = data + size - 16; + for (const auto i : c10::irange(16)) { + at::uniform_real_distribution uniform(0, 1); + data[i] = uniform(generator); + } + if(Vec::size()==8){ + normal_fill_16_VSX(data, two_pi, one, minus_two, mean_vec, var_vec); + } + else{ + normal_fill_16(data, mean, std); + } + } +} +#endif //VSX + +template +void normal_fill(const TensorBase &self, const scalar_t mean, const scalar_t std, RNG generator) { + scalar_t *data = self.data_ptr(); + auto size = self.numel(); + std::lock_guard lock(generator->mutex_); + for (const auto i : c10::irange(size)) { + at::uniform_real_distribution uniform(0, 1); + data[i] = uniform(generator); + } + + for (int64_t i = 0; i < size - 15; i += 16) { + normal_fill_16(data + i, mean, std); + } + if (size % 16 != 0) { + // Recompute the last 16 values. + data = data + size - 16; + for (const auto i : c10::irange(16)) { + at::uniform_real_distribution uniform(0, 1); + data[i] = uniform(generator); + } + normal_fill_16(data, mean, std); + } +} + +template +void normal_kernel(const TensorBase &self, double mean, double std, RNG generator) { + auto size = self.numel(); + if (self.scalar_type() == ScalarType::Float && size >= 16 && self.is_contiguous()) { +#ifdef CPU_CAPABILITY_AVX2 + normal_fill_AVX2(self, static_cast(mean), static_cast(std), generator); +#elif defined(__VSX__) || defined(CPU_CAPABILITY_VSX) + normal_fill_VSX(self, static_cast(mean), static_cast(std), generator); +#else + normal_fill(self, static_cast(mean), static_cast(std), generator); +#endif + } else { + AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, self.scalar_type(), "normal_kernel_cpu", [&] { + if (size >= 16 && self.is_contiguous()) { + normal_fill(self, static_cast(mean), static_cast(std), generator); + } else { + auto iter = TensorIterator::borrowing_nullary_op(self); + std::lock_guard lock(generator->mutex_); + cpu_serial_kernel(iter, [mean, std, generator]() -> scalar_t { + at::normal_distribution normal(mean, std); + return static_cast(normal(generator)); + }); + } + }); + } +} + +template +struct NormalKernel { + void operator()(Tensor& self, double mean, double std, std::optional gen) { + normal_kernel(self, mean, std, check_generator(gen)); + } +}; + +// ==================================================== Uniform ======================================================= + +template +void uniform_kernel(TensorIteratorBase& iter, double from_, double to_, RNG generator) { + AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, iter.dtype(), "uniform_kernel_cpu", [&]() { + std::lock_guard lock(generator->mutex_); + auto from = static_cast(from_); + auto to = static_cast(to_); + at::uniform_real_distribution uniform(from, to); + cpu_serial_kernel(iter, [&uniform, generator]() -> scalar_t { + return static_cast(uniform(generator)); + }); + }); +} + +template +struct UniformKernel { + void operator()(TensorIteratorBase& iter, double from, double to, std::optional gen) { + uniform_kernel(iter, from, to, check_generator(gen)); + } +}; + +// ==================================================== Cauchy ======================================================== + +template +void cauchy_kernel(TensorIteratorBase& iter, double median, double sigma, RNG generator) { + AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, iter.dtype(), "cauchy_cpu", [&]() { + std::lock_guard lock(generator->mutex_); + at::cauchy_distribution cauchy(median, sigma); + cpu_serial_kernel(iter, [&cauchy, generator]() -> scalar_t { + return static_cast(cauchy(generator)); + }); + }); +} + +template +struct CauchyKernel { + void operator()(TensorIteratorBase& iter, double median, double sigma, std::optional gen) { + cauchy_kernel(iter, median, sigma, check_generator(gen)); + } +}; + +// ================================================== LogNormal ======================================================= + +template +void log_normal_kernel(TensorIteratorBase& iter, double mean, double std, RNG generator) { + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "log_normal_cpu", [&]() { + std::lock_guard lock(generator->mutex_); + at::lognormal_distribution logNormal(mean, std); + cpu_serial_kernel(iter, [&logNormal, generator]() -> scalar_t { + return static_cast(logNormal(generator)); + }); + }); +} + +template +struct LogNormalKernel { + void operator()(TensorIteratorBase& iter, double mean, double std, std::optional gen) { + log_normal_kernel(iter, mean, std, check_generator(gen)); + } +}; + +// =================================================== Geometric ====================================================== + +template +void geometric_kernel(TensorIteratorBase& iter, double p, RNG generator) { + AT_DISPATCH_ALL_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "geometric_cpu", [&]() { + std::lock_guard lock(generator->mutex_); + at::geometric_distribution geometric(p); + cpu_serial_kernel(iter, [&geometric, generator]() -> scalar_t { + return static_cast(geometric(generator)); + }); + }); +} + +template +struct GeometricKernel { + void operator()(TensorIteratorBase& iter, double p, std::optional gen) { + geometric_kernel(iter, p, check_generator(gen)); + } +}; + +// ================================================== Exponential ===================================================== + +template +void exponential_kernel(TensorIteratorBase& iter, double lambda, RNG generator) { + TORCH_CHECK(isFloatingType(iter.dtype()), "Exponential distribution is a continuous probability distribution. dtype must be a floating point but you specified ", iter.dtype()); + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "exponential_cpu", [&]() { + std::lock_guard lock(generator->mutex_); + at::exponential_distribution exponential(lambda); + cpu_serial_kernel(iter, [&exponential, generator]() -> scalar_t { + return static_cast(exponential(generator)); + }); + }); +} + +template +struct ExponentialKernel { + void operator()(TensorIteratorBase& iter, double lambda, std::optional gen) { + exponential_kernel(iter, lambda, check_generator(gen)); + } +}; + +// ================================================== Bernoulli ======================================================= + +template +void bernoulli_kernel(const TensorBase &self, const TensorBase &p_, RNG generator) { + AT_DISPATCH_ALL_TYPES_AND3(at::ScalarType::Bool, at::ScalarType::BFloat16, at::ScalarType::Half, + self.scalar_type(), "bernoulli_tensor_cpu_self_", [&] { + // See Note [Acquire lock when using random generators] + std::lock_guard lock(generator->mutex_); + using self_t = scalar_t; + auto p_cpu = p_.to(kCPU); + auto p = expand_inplace(self, p_cpu); + auto iter = TensorIteratorConfig() + .add_output(self) + .add_const_input(*p) + .check_all_same_dtype(false) + .build(); + if (p->scalar_type() == kDouble) { + cpu_serial_kernel(iter, [&](const double p_val) -> self_t { + at::bernoulli_distribution bernoulli(p_val); + return static_cast(bernoulli(generator)); + }); + } else { + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::BFloat16, at::ScalarType::Half, + p->scalar_type(), "bernoulli_tensor_cpu_p_", [&] { + using p_t = scalar_t; + cpu_serial_kernel(iter, [&](const p_t p_val) -> self_t { + at::bernoulli_distribution bernoulli(p_val); + return static_cast(bernoulli(generator)); + }); + }); + } + }); +} + +template +void bernoulli_kernel(const TensorBase &self, double p, RNG generator) { + AT_DISPATCH_ALL_TYPES_AND3(at::ScalarType::Bool, at::ScalarType::BFloat16, at::ScalarType::Half, + self.scalar_type(), "bernoulli_scalar_cpu_", [&] { + // See Note [Acquire lock when using random generators] + std::lock_guard lock(generator->mutex_); + auto iter = TensorIterator::borrowing_nullary_op(self); + cpu_serial_kernel(iter, [p, generator]() -> scalar_t { + at::bernoulli_distribution bernoulli(p); + return static_cast(bernoulli(generator)); + }); + }); +} + +template +struct BernoulliKernel { + void operator()(const TensorBase &self, double p, std::optional gen) { + bernoulli_kernel(self, p, check_generator(gen)); + } + void operator()(const TensorBase &self, const TensorBase &p_, std::optional gen) { + bernoulli_kernel(self, p_, check_generator(gen)); + } +}; + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Gelu.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Gelu.h new file mode 100644 index 0000000000000000000000000000000000000000..390d3b28e3c595109a141d131c44bdbd270e548f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Gelu.h @@ -0,0 +1,74 @@ +#pragma once + +#include +#include // For c10::is_reduced_floating_point_v. + +namespace at::native { +constexpr double kGeluBeta = M_SQRT2 * M_2_SQRTPI * 0.5; +constexpr double kGeluKappa = 0.044715; + +template +using reduced_fp_to_float_t = std::conditional_t, float, T>; + +template , bool> = true> +float reduced_fp_to_float(T x) { + return float(x); +} + +template , bool> = true> +T reduced_fp_to_float(T x) { + return x; +} + +template +T scalar_gelu_approximated_with_tanh(T x) { + using opmath_t = reduced_fp_to_float_t; + auto x_float = reduced_fp_to_float(x); + auto x_cube = x_float * x_float * x_float; + auto inner = opmath_t(kGeluBeta) * (x_float + opmath_t(kGeluKappa) * x_cube); + return opmath_t(0.5) * x_float * (opmath_t(1) + std::tanh(inner)); +} + +template , bool> = true> +vec::Vectorized vectorized_gelu_approximated_with_tanh(vec::Vectorized x) { + const vec::Vectorized kPointFiveVec(T(0.5)); + const vec::Vectorized kOneVec(T(1)); + const vec::Vectorized kGeluBetaVec((T(kGeluBeta))); + const vec::Vectorized kGeluKappaVec((T(kGeluKappa))); + auto x_cube = x * x * x; + vec::Vectorized inner_vec = kGeluBetaVec * (x + kGeluKappaVec * x_cube); + return kPointFiveVec * x * (kOneVec + inner_vec.tanh()); +} + +template , bool> = true> +vec::Vectorized vectorized_gelu_approximated_with_tanh(vec::Vectorized x) { + auto [x0, x1] = at::vec::convert_to_float(x); + return at::vec::convert_from_float( + vectorized_gelu_approximated_with_tanh(x0), + vectorized_gelu_approximated_with_tanh(x1)); +} + + +template +T scalar_gelu(T x) { + using opmath_t = reduced_fp_to_float_t; + const auto kAlpha = opmath_t(M_SQRT1_2); + return reduced_fp_to_float(x) * opmath_t(0.5) * (opmath_t(1) + std::erf(reduced_fp_to_float(x) * kAlpha)); +} + +template, bool> = true> +vec::Vectorized vectorized_gelu(vec::Vectorized x) { + const vec::Vectorized kAlphaVec(T(M_SQRT1_2)); + const vec::Vectorized kOneVec(T(1)); + const vec::Vectorized kPointFiveVec(T(0.5)); + return x * kPointFiveVec * (kOneVec + (x * kAlphaVec).erf()); +} + +template, bool> = true> +vec::Vectorized vectorized_gelu(vec::Vectorized x) { + auto [x0, x1] = at::vec::convert_to_float(x); + return at::vec::convert_from_float(vectorized_gelu(x0), vectorized_gelu(x1)); +} + + +} // namespace diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/GridSamplerKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/GridSamplerKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..743bbfdb7e800e6f8b0770787bb10d7aa24000e3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/GridSamplerKernel.h @@ -0,0 +1,34 @@ +#pragma once + +#include + +#include +#include + +namespace at { +class TensorBase; +} + +namespace at::native { + +using forward_2d_fn = void (*) ( + const TensorBase &output, + const TensorBase &input, + const TensorBase &grid, + int64_t interpolation_mode, + int64_t padding_mode, + bool align_corners); +using backward_2d_fn = void (*) ( + const TensorBase &grad_input, + const TensorBase &grad_grid, + const TensorBase &grad_output, + const TensorBase &input, + const TensorBase &grid, + int64_t interpolation_mode, + int64_t padding_mode, + bool align_corners, + std::array output_mask); +DECLARE_DISPATCH(forward_2d_fn, grid_sampler_2d_cpu_kernel) +DECLARE_DISPATCH(backward_2d_fn, grid_sampler_2d_backward_cpu_kernel) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/IndexKernelUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/IndexKernelUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..c513d128e23421a6c828d2f710732b04b2d1800a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/IndexKernelUtils.h @@ -0,0 +1,85 @@ +#pragma once +#include +#include + +namespace at::native { + +inline bool is_constant_index(int ntensor, const int64_t* strides) { + AT_ASSERT(ntensor >= 3); + for (const auto arg : c10::irange(2, ntensor)) { + if (strides[arg] != 0) { + return false; + } + } + return true; +} + + +struct Indexer { + Indexer(int64_t num_indexers, char** indexers, const int64_t* indexer_strides, + IntArrayRef original_sizes, IntArrayRef original_strides) + : num_indexers(num_indexers) + , indexers(indexers) + , indexer_strides(indexer_strides) + , original_strides(original_strides.data()) + , original_sizes(original_sizes.data()) { + AT_ASSERT(static_cast(original_strides.size()) == num_indexers); + AT_ASSERT(static_cast(original_sizes.size()) == num_indexers); + } + + int64_t num_indexers; + char** indexers; + const int64_t* indexer_strides; + const int64_t* original_strides; + const int64_t* original_sizes; + + int64_t get(int64_t idx) { + int64_t offset = 0; + for (const auto j : c10::irange(num_indexers)) { + int64_t value = *(int64_t*)&indexers[j][idx * indexer_strides[j]]; + int64_t size = original_sizes[j]; + TORCH_CHECK_INDEX(value >= -size && value < size, + "index ", value, " is out of bounds for dimension ", j, " with size ", size); + if (value < 0) { + value += size; + } + offset += value * original_strides[j]; + } + return offset; + } +}; + +template +void cpu_index_kernel(TensorIteratorBase& iter, IntArrayRef index_size, IntArrayRef index_stride, + const func_t& f, bool serial_execution=false) +{ + int ntensor = iter.ntensors(); + // When launch the index parallel version, set a relative small grain size less than the INTERNAL::GRAIN_SIZE + // to make the whole available thread numbers get more balanced work load and a better cache location. + // The grain size here is chosen by the op benchmark to overcome the thread launch overhead + const int index_parallel_grain_size = 3000; + auto loop = [&](char** data, const int64_t* strides, int64_t n) { + auto indexer = Indexer(ntensor - 2, &data[2], &strides[2], index_size, index_stride); + char* dst = data[0]; + char* src = data[1]; + if (is_constant_index(ntensor, strides)) { + // specialization for when every element uses the same index + int64_t offset = indexer.get(0); + for (const auto i : c10::irange(n)) { + f(dst + strides[0] * i, src + strides[1] * i, offset); + } + } else { + for (const auto i : c10::irange(n)) { + int64_t offset = indexer.get(i); + f(dst + strides[0] * i, src + strides[1] * i, offset); + } + } + }; + if (serial_execution) { + iter.serial_for_each(loop, {0, iter.numel()}); + } else { + iter.for_each(loop, index_parallel_grain_size); + } +} +} // at +// native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Intrinsics.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Intrinsics.h new file mode 100644 index 0000000000000000000000000000000000000000..f3b35328f1882729a9158eaed7eb2abf77097484 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Intrinsics.h @@ -0,0 +1,33 @@ +#pragma once + +#if defined(__clang__) && (defined(__x86_64__) || defined(__i386__)) +/* Clang-compatible compiler, targeting x86/x86-64 */ +#include +#elif defined(_MSC_VER) +/* Microsoft C/C++-compatible compiler */ +#include +#if _MSC_VER <= 1900 +#define _mm256_extract_epi64(X, Y) (((uint64_t*)&X)[Y]) +#endif +#elif defined(__GNUC__) && (defined(__x86_64__) || defined(__i386__)) +/* GCC-compatible compiler, targeting x86/x86-64 */ +#include +#elif defined(__GNUC__) && defined(__ARM_NEON__) +/* GCC-compatible compiler, targeting ARM with NEON */ +#include +#elif defined(__GNUC__) && defined(__IWMMXT__) +/* GCC-compatible compiler, targeting ARM with WMMX */ +#include +#elif (defined(__GNUC__) || defined(__xlC__)) && \ + (defined(__VEC__) || defined(__ALTIVEC__)) +/* XLC or GCC-compatible compiler, targeting PowerPC with VMX/VSX */ +#include +/* We need to undef those tokens defined by to avoid conflicts + with the C++ types. => Can still use __bool/__vector */ +#undef bool +#undef vector +#undef pixel +#elif defined(__GNUC__) && defined(__SPE__) +/* GCC-compatible compiler, targeting PowerPC with SPE */ +#include +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/IsContiguous.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/IsContiguous.h new file mode 100644 index 0000000000000000000000000000000000000000..02d8f5dd78e40f2628031d68719a5059db869302 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/IsContiguous.h @@ -0,0 +1,64 @@ +#pragma once + +namespace at::native { inline namespace CPU_CAPABILITY { + +// n: number of function arguments (arity) +// traits: function_traits (see FunctionTraits.h) +// s: index of scalar argument or -1 +template +struct IsContiguous { + static bool eval(const int64_t* strides) { + using type = typename traits::template arg::type; + return strides[stride_index] == (s == n ? 0 : sizeof(type)) && + IsContiguous::eval(strides); + } +}; + +// will be called when there is an output exists +template +struct IsContiguous<0, 0, traits, s> { + static bool eval(const int64_t* strides) { + return strides[0] == sizeof(typename traits::result_type); + } +}; + +// will be called when there is no output +template +struct IsContiguous<0, -1, traits, s> { + static bool eval(const int64_t* /*strides*/) { + return true; + } +}; + +// output and all inputs are contiguous +template < + typename traits, + std::enable_if_t>* = + nullptr> +static inline bool is_contiguous(const int64_t* strides) { + return IsContiguous::eval(strides); +} + +template >* = nullptr> +static inline bool is_contiguous(const int64_t* strides) { + return IsContiguous::eval(strides); +} + +// input at `s` is scalar (stride 0); output and other inputs are contiguous +// NB: output is typically at strides[0] so first input corresponds to s=1 +template >* = nullptr> +static inline bool is_contiguous_scalar(const int64_t* strides) { + static_assert(s > 0 && s <= traits::arity, "scalar argument index out of bounds"); + return IsContiguous::eval(strides); +} + +template >* = nullptr> +static inline bool is_contiguous_scalar(const int64_t* strides) { + static_assert(s > 0 && s <= traits::arity, "scalar argument index out of bounds"); + return IsContiguous::eval(strides); +} + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/LogAddExp.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/LogAddExp.h new file mode 100644 index 0000000000000000000000000000000000000000..e2b80a648df6b11a99ceadff5488dd597af4f9ac --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/LogAddExp.h @@ -0,0 +1,61 @@ +#pragma once + +#include +#include + +namespace at::native { +inline namespace CPU_CAPABILITY { + +// custom min and max to be used in logcumsumexp for complex arguments +template +std::pair, c10::complex> _logcumsumexp_minmax(c10::complex x, c10::complex y) { + if (at::_isnan(y)) { // either real is nan or imag is nan + return std::make_pair(y, y); + } else if (at::_isnan(x)) { // either real is nan or imag is nan + return std::make_pair(x, x); + } else { + return (x.real() < y.real()) ? std::make_pair(x, y) : std::make_pair(y, x); + } +} + +template +scalar_t _log_add_exp_helper(scalar_t x, scalar_t y) { + // Reference : https://www.tensorflow.org/api_docs/python/tf/math/cumulative_logsumexp + scalar_t min = at::_isnan(y) ? y : std::min(x, y); // std::min returns first arg if one of the args is nan + scalar_t max = at::_isnan(y) ? y : std::max(x, y); // std::max returns first arg if one of the args is nan + if (min != max || std::isfinite(min)) { + // nan will be propagated here + return std::log1p(std::exp(min - max)) + max; + } else { + // special case to correctly handle infinite cases + return x; + } +} + +template +c10::complex _log_add_exp_helper(const c10::complex& x, const c10::complex& y) { + auto [min, max] = _logcumsumexp_minmax(x, y); + auto min_real = std::real(min); + auto max_real = std::real(max); + + if (at::_isnan(min)) { // either real is nan or imag is nan + // handling the "infectious" NaNs + return {std::numeric_limits::quiet_NaN(), std::numeric_limits::quiet_NaN()}; + } else if (!std::isfinite(min_real) && (min_real == max_real)) { + if (min_real < 0) { + // handle the -inf case, the imaginary part here does not really matter as the exp(value) + // will be around 0.0 and the angle (i.e. the imaginary part) cannot be determined. + // It does not matter if we're taking the exp of this value + return min; + } else { + // handle the +inf case, we don't need the special precision for log1p for small values + // and to avoid producing nan in case of real(max) == real(min) == +inf + return std::log(std::exp(min) + std::exp(max)); + } + } else { + return std::log1p(std::exp(min - max)) + max; + } +} + +} // end namespace +} //end at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Loops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Loops.h new file mode 100644 index 0000000000000000000000000000000000000000..5715fd8f047f29430ddf8becccb91666d1d0242a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Loops.h @@ -0,0 +1,395 @@ +#pragma once + +// This file provides two functions to help write elementwise kernels: +// +// cpu_kernel(TensorIterator iter, ) +// cpu_kernel_vec(TensorIterator iter, , ) +// +// Both functions may generate vectorized code. The cpu_kernel implementation +// relies on the compiler's auto-vectorization. The cpu_kernel_vec +// implementation uses x86 SIMD intrinsics when available. These functions +// are only intended to be used in the ATen/native/cpu subdirectory, since files +// in other directories are not compiled with AVX/AVX2 enabled. See README.md +// for more details. +// +// For example, to write a multiplication kernel for float: +// +// cpu_kernel(iter, [](float a, float b) { return a * b; }); +// +// Or you may write: +// +// cpu_kernel_vec(iter, +// [](float a, float b) { return a * b; }, +// [](Vectorized a, Vectorized b) { return a * b; }); +// +// See BinaryOpsKernel.cpp for the complete implementation +// +// + +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include + +namespace at::native { inline namespace CPU_CAPABILITY { + +using namespace vec; + +template +typename traits::ArgsTuple +dereference_impl(char* C10_RESTRICT data[], const int64_t* strides, int64_t i, + std::index_sequence) { + return std::make_tuple( + c10::load::type>( + data[INDEX] + i * strides[INDEX])...); +} + +template +typename traits::ArgsTuple +dereference(char* C10_RESTRICT data[], const int64_t* strides, int64_t i) { + using Indices = std::make_index_sequence; + return dereference_impl(data, strides, i, Indices{}); +} + +template +typename traits::ArgsTuple +dereference_vec_impl(char* C10_RESTRICT data[], + const typename traits::result_type& opt_scalar, + size_t S, + int64_t i, + std::index_sequence) { + using Vec = typename traits::result_type; + using scalar_t = typename Vec::value_type; + return std::make_tuple( + S == INDEX + 1 ? + opt_scalar : + Vec::loadu(data[INDEX] + i * sizeof(scalar_t))...); +} + +template +typename traits::ArgsTuple +dereference_vec(char* C10_RESTRICT data[], const typename traits::result_type& opt_scalar, size_t S, int64_t i) { + using Indices = std::make_index_sequence; + return dereference_vec_impl(data, opt_scalar, S, i, Indices{}); +} + +template ::result_type>>* = nullptr> +inline void +execute_op(char* C10_RESTRICT data[], const int64_t* strides, int64_t i, int64_t n, func_t&& op) { + using traits = function_traits; + using result_type = typename traits::result_type; + for (; i < n; i++) { + result_type* out_ptr = (result_type*)(data[0] + i * strides[0]); + *out_ptr = c10::guts::apply(op, dereference( + &data[1], + &strides[1], + i)); + } +} + +template ::result_type>>* = nullptr> +inline void +execute_op(char* C10_RESTRICT data[], const int64_t* strides, int64_t i, int64_t n, func_t&& op) { + using traits = function_traits; + for (; i < n; i++) { + c10::guts::apply(op, dereference( + &data[0], + &strides[0], + i)); + } +} + +// Basic loop operation (one output, N inputs). May be auto-vectorized +// by the compiler. Supports inputs and outputs of different types. +template +inline void +basic_loop(char* C10_RESTRICT data[], const int64_t* strides_, int64_t i, int64_t n, func_t&& op) { + using traits = function_traits; + constexpr int ntensors = traits::arity + 1; + + // Copying strides to temporary array helps auto vectorization in older GCC + // versions. + int64_t strides[ntensors]; + for (const auto arg : c10::irange(ntensors)) { + strides[arg] = strides_[arg]; + } + + execute_op(data, strides, i, n, std::forward(op)); +} + +// the recursive variadic template for iterating over the returned tuple +template +struct TupleOutput { + static void handle(char *C10_RESTRICT data[], const int64_t *strides, int64_t i, + const T &tuple) { + TupleOutput::handle(data, strides, i, tuple); + + auto output = std::get(tuple); + using output_type = decltype(output); + output_type * out_ptr = (output_type *)(data[N - 1] + i * strides[N - 1]); + *out_ptr = output; + } +}; + +// Base case for the above recursive template +template +struct TupleOutput { + static void handle(char *C10_RESTRICT data[], const int64_t *strides, int64_t i, + const T &tuple) { + auto output = std::get<0>(tuple); + using output_type = decltype(output); + output_type* out_ptr = (output_type *)(data[0] + i * strides[0]); + *out_ptr = output; + } +}; + +template +void handle_tuple_outputs(char* C10_RESTRICT data[], + const int64_t* strides, + int64_t i, + const std::tuple &tuple) { + TupleOutput::handle(data, strides, i, tuple); +} + +// Loop operation for `cpu_kernel_multiple_outputs`. +// 1. Use `c10::guts::apply` to make dynamic method invocation +// for the lambda passed in `cpu_kernel_multiple_outputs`. +// 2. Iterate over the members of the returned tuple, set the corresponding +// output tensor by the tuple member in `handle_tuple_outputs` function. +template +inline void +multiple_outputs_loop(char* C10_RESTRICT data[], const int64_t* strides_, int64_t i, int64_t n, func_t&& op) { + using traits = function_traits; + + using result_type = typename traits::result_type; + constexpr int num_outputs = std::tuple_size_v; + constexpr int ntensors = traits::arity + num_outputs; + + // Copying strides to temporary array helps auto vectorization in older GCC + // versions. + int64_t strides[ntensors]; + for (const auto arg : c10::irange(ntensors)) { + strides[arg] = strides_[arg]; + } + + for (; i < n; i++) { + auto output = c10::guts::apply(op, dereference( + &data[num_outputs], + &strides[num_outputs], + i)); + handle_tuple_outputs(data, strides, i, output); + } +} + +// Explicitly vectorized loop implementation. All inputs and outputs must be +// the same type and contiguous with one exception: a single input may be +// a scalar (stride 0). It's position is indicated by the argument `S`. If `S` +// is 0, then there are no scalar inputs. +template +inline void +vectorized_loop(char** C10_RESTRICT data_, int64_t n, int64_t S, func_t&& op, vec_func_t&& vop) { + using traits = function_traits; + using scalar_t = typename function_traits::result_type; + using Vec = Vectorized; + constexpr int ntensors = traits::arity + 1; + + char* C10_RESTRICT data[ntensors]; + for (const auto arg : c10::irange(ntensors)) { + data[arg] = data_[arg]; + } + + Vec opt_scalar = Vec(S > 0 ? c10::load((scalar_t*)data[S]) : scalar_t(0)); + int64_t i = 0; + for (; i <= n - 2 * Vec::size(); i += 2 * Vec::size()) { + auto args1 = dereference_vec(&data[1], opt_scalar, S, i); + auto args2 = dereference_vec(&data[1], opt_scalar, S, i + Vec::size()); + auto out1 = c10::guts::apply(vop, std::move(args1)); + auto out2 = c10::guts::apply(vop, std::move(args2)); + out1.store(data[0] + i * sizeof(scalar_t)); + out2.store(data[0] + (i + Vec::size()) * sizeof(scalar_t)); + } + if (i < n) { + int64_t strides[ntensors]; + for (const auto arg : c10::irange(ntensors)) { + strides[arg] = (S > 0 && arg == S) ? 0 : sizeof(scalar_t); + } + basic_loop(data, strides, i, n, std::forward(op)); + } +} + + +template +inline void unroll_contiguous_scalar_checks( + const int64_t* /*strides*/, + std::index_sequence<>, + cb_t&& cb) { + cb(0); +} + +template +inline void unroll_contiguous_scalar_checks( + const int64_t* strides, + std::index_sequence, + cb_t&& cb) { + if (is_contiguous_scalar(strides)) { + cb(INDEX0 + 1); + } else { + unroll_contiguous_scalar_checks(strides, std::index_sequence{}, std::forward(cb)); + } +} + +template +struct VectorizedLoop2d { + op_t op; + vop_t vop; + + using traits = function_traits; + static constexpr int ntensors = traits::arity + 1; + using data_t = std::array; + + VectorizedLoop2d(op_t op, vop_t vop): + op(std::move(op)), vop(std::move(vop)) {} + + static void advance(data_t &data, const int64_t *outer_strides) { + for (const auto arg : c10::irange(data.size())) { + data[arg] += outer_strides[arg]; + } + } + + void operator()(char** base, const int64_t *strides, int64_t size0, int64_t size1) { + data_t data; + std::copy_n(base, ntensors, data.data()); + const int64_t *outer_strides = &strides[ntensors]; + + if (is_contiguous(strides)) { + for ([[maybe_unused]] const auto i : c10::irange(size1)) { + vectorized_loop(data.data(), size0, 0, op, vop); + advance(data, outer_strides); + } + } else { + using Indices = std::make_index_sequence; + unroll_contiguous_scalar_checks(strides, Indices{}, [&](size_t idx) { + if (idx) { + for ([[maybe_unused]] const auto i : c10::irange(size1)) { + vectorized_loop(data.data(), size0, idx, op, vop); + advance(data, outer_strides); + } + } else { + for ([[maybe_unused]] const auto i : c10::irange(size1)) { + basic_loop(data.data(), strides, 0, size0, op); + advance(data, outer_strides); + } + } + }); + } + } +}; + +template +VectorizedLoop2d make_vectorized_loop2d( + op_t &&op, vop_t &&vop) { + return VectorizedLoop2d(std::forward(op), std::forward(vop)); +} + +template +void cpu_kernel(TensorIteratorBase& iter, func_t&& op, int64_t grain_size = at::internal::GRAIN_SIZE) { + using traits = function_traits; + // this could be extended to work with void return types + TORCH_INTERNAL_ASSERT(iter.ninputs() == traits::arity); + TORCH_INTERNAL_ASSERT(iter.noutputs() == 1); + // dynamic casting not currently supported on CPU + TORCH_INTERNAL_ASSERT(!needs_dynamic_casting::check(iter)); + + iter.for_each([&](char** data, const int64_t* strides, int64_t n) { + // basic loop can handle 1d slices with arbitrary strides, and 1d slices is all that + // iter.for_each is ever sending to the loop lambda + basic_loop(data, strides, 0, n, op); + }, grain_size); + iter.cast_outputs(); +} + +// This function helps write elementwise kernels that requires multiple outputs. +// It follows the similar structure of cpu_kernel. +// Instead of `basic_loop` function, a new `multiple_outputs_loop` function is +// manipulated to handle multiple return values. +// For now `needs_dynamic_casting` check is not added as the passed lambda (`func_t`) +// of `multiple_outputs_loop` returns `std::tuple` instead of `scalar_t`. +// The `gpu_kernel_multiple_outputs` is also implemented without this check, +// We could extend `needs_dynamic_casting` to support both `std::tuple` and +// `thrust::tuple` in the future. +template +void cpu_kernel_multiple_outputs(TensorIteratorBase& iter, func_t&& op, int64_t grain_size = at::internal::GRAIN_SIZE) { + using traits = function_traits; + TORCH_INTERNAL_ASSERT(iter.ninputs() == traits::arity); + + iter.for_each([&](char** data, const int64_t* strides, int64_t n) { + multiple_outputs_loop(data, strides, 0, n, op); + }, grain_size); + iter.cast_outputs(); +} + +template +void cpu_kernel_vec(TensorIteratorBase& iter, func_t&& op, vec_func_t&& vop, int64_t grain_size = at::internal::GRAIN_SIZE) { + using traits = function_traits; + // this could be extended to work with void return types + TORCH_INTERNAL_ASSERT(iter.ninputs() == traits::arity); + TORCH_INTERNAL_ASSERT(iter.noutputs() == 1); + // dynamic casting not currently supported on CPU, but some kernels (like Fill) + // explicitly dynamic_cast, so we give the opt-out of checking. + if constexpr (check_dynamic_cast) { + TORCH_INTERNAL_ASSERT(!needs_dynamic_casting::check(iter)); + } + + iter.for_each(make_vectorized_loop2d(std::forward(op), std::forward(vop)), grain_size); + iter.cast_outputs(); +} + +template +void cpu_serial_kernel(TensorIteratorBase& iter, func_t&& op, const Range& range) { + using traits = function_traits; + constexpr bool result_void = std::is_void_v; + TORCH_INTERNAL_ASSERT(iter.ninputs() == traits::arity && + ((result_void && iter.noutputs() == 0) || (!result_void && iter.noutputs() == 1))); + // dynamic casting not currently supported on CPU + TORCH_INTERNAL_ASSERT(!needs_dynamic_casting::check(iter)); + + iter.serial_for_each([&](char** data, const int64_t* strides, int64_t n) { + basic_loop(data, strides, 0, n, op); + }, range); + iter.cast_outputs(); +} + +template +void cpu_serial_kernel(TensorIteratorBase& iter, func_t&& op) { + cpu_serial_kernel(iter, std::forward(op), {0, iter.numel()}); +} + +template +void cpu_serial_kernel_vec(TensorIteratorBase& iter, func_t&& op, vec_func_t&& vop, const Range& range) { + using traits = function_traits; + // this could be extended to work with void return types + TORCH_INTERNAL_ASSERT(iter.ninputs() == traits::arity); + TORCH_INTERNAL_ASSERT(iter.noutputs() == 1); + // dynamic casting not currently supported on CPU + TORCH_INTERNAL_ASSERT(!needs_dynamic_casting::check(iter)); + + iter.serial_for_each(make_vectorized_loop2d(std::forward(op), std::forward(vop)), range); + iter.cast_outputs(); +} + +template +void cpu_serial_kernel_vec(TensorIteratorBase& iter, func_t&& op, vec_func_t&& vop) { + cpu_serial_kernel_vec(iter, std::forward(op), std::forward(vop), {0, iter.numel()}); +} + +}} // namespace at::native:: diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/MaxUnpoolKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/MaxUnpoolKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..c9a079cc203f26f5da2123300ff251203feb3835 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/MaxUnpoolKernel.h @@ -0,0 +1,14 @@ +#pragma once +#include + +namespace at { +class Tensor; + +namespace native { + +using max_unpooling_fn = void(*)(Tensor&, const Tensor&, const Tensor&); + +DECLARE_DISPATCH(max_unpooling_fn, max_unpool2d_kernel) +DECLARE_DISPATCH(max_unpooling_fn, max_unpool3d_kernel) + +}} // at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/PixelShuffleKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/PixelShuffleKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..abdb4945c98c91209ec4f6bb9cb62092db74b2e3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/PixelShuffleKernel.h @@ -0,0 +1,14 @@ +#pragma once +#include + +namespace at { +class TensorBase; +} + +namespace at::native { + +using pixel_shuffle_fn = void(*)(TensorBase&, const TensorBase&, int64_t); +DECLARE_DISPATCH(pixel_shuffle_fn, pixel_shuffle_kernel) +DECLARE_DISPATCH(pixel_shuffle_fn, pixel_unshuffle_kernel) + +} // at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Reduce.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Reduce.h new file mode 100644 index 0000000000000000000000000000000000000000..6c9efbb0f6e7f5d849a3e2ae48ca22ab147d6915 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/Reduce.h @@ -0,0 +1,310 @@ +#pragma once + +#include +#include +#include +#include +#include + +#include + +namespace at::native { inline namespace CPU_CAPABILITY { + +using namespace vec; + +#define VEC_LOOP_HEADER(func_t, data) \ + using scalar_t = typename function_traits::result_type; \ + using Vec = Vectorized; \ + char* out_ptr = data[0]; \ + (void) out_ptr; + +// reduction that is contiguous over the input in dim 0 +template +inline bool is_contiguous_reduction(const int64_t* strides) { + return strides[0] == 0 && + strides[1] == sizeof(typename traits::arg2_t); +} + +// reduction that is contiguous over the input in dim 1 +template +inline bool is_outer_reduction(const int64_t* strides) { + return strides[0] == 0 && + strides[2] == sizeof(typename traits::result_type) && + strides[3] == sizeof(typename traits::arg2_t); +} + +template +inline void vectorized_reduction(char** data, int64_t n, int64_t stride, + func_t op, vec_func_t vop, bool reduce) { + VEC_LOOP_HEADER(func_t, data) + const char* in1_ptr = data[1]; + Vec acc[4]; + for (const auto j : c10::irange(4)) { + acc[j] = Vec::loadu(in1_ptr + j * Vec::size() * sizeof(scalar_t)); + } + for (const auto i : c10::irange(1, n)) { + const char* ptr = in1_ptr + stride * i; + acc[0] = vop(acc[0], Vec::loadu(ptr + (0 * Vec::size() * sizeof(scalar_t)))); + acc[1] = vop(acc[1], Vec::loadu(ptr + (1 * Vec::size() * sizeof(scalar_t)))); + acc[2] = vop(acc[2], Vec::loadu(ptr + (2 * Vec::size() * sizeof(scalar_t)))); + acc[3] = vop(acc[3], Vec::loadu(ptr + (3 * Vec::size() * sizeof(scalar_t)))); + } + if (reduce) { + scalar_t buffer[Vec::size()]; + acc[0] = vop(vop(acc[0], acc[1]), vop(acc[2], acc[3])); + acc[0].store(buffer); + for (const auto j : c10::irange(1, Vec::size())) { + buffer[0] = op(buffer[0], buffer[j]); + } + auto dst = (scalar_t*)out_ptr; + *dst = op(*dst, buffer[0]); + } else { + for (const auto j : c10::irange(4)) { + auto dst = out_ptr + j * Vec::size() * sizeof(scalar_t); + acc[j] = vop(acc[j], Vec::loadu(dst)); + acc[j].store(dst); + } + } +} + +template +inline void UNARY_OUTER_LOOP(char* data[2], const int64_t strides[2], int64_t n, F f) { + for ([[maybe_unused]] const auto j : c10::irange(n)) { + f(); + data[0] += strides[0]; + data[1] += strides[1]; + } +} + +// computes the reduction out = op(out, in) +template +inline void vectorized_inner_reduction(char** data, int64_t n, func_t op, vec_func_t vop) { + VEC_LOOP_HEADER(func_t, data) + constexpr int64_t vector_stride = 4 * Vec::size() * sizeof(scalar_t); + int64_t count = n / (4 * Vec::size()); + if (count > 0) { + vectorized_reduction(data, count, vector_stride, op, vop, /*reduce=*/true); + } + char* ptrs[3] = { data[0], data[0], data[1] }; + int64_t strides[] = { 0, 0, sizeof(scalar_t) }; + basic_loop(ptrs, strides, count * 4 * Vec::size(), n, op); +} + +// computes the reduction out = op(out, in) +template +inline void vectorized_outer_reduction(char** data, int64_t inner_stride, int64_t size0, int64_t size1, func_t op, vec_func_t vop) { + VEC_LOOP_HEADER(func_t, data) + + // reduce down each column of 4 * Vec::size() elements. + constexpr int64_t vector_stride = 4 * Vec::size() * sizeof(scalar_t); + int64_t outer_stride[2] = { vector_stride, vector_stride }; + UNARY_OUTER_LOOP(data, outer_stride, size1 / (4 * Vec::size()), [&] { + vectorized_reduction(data, size0, inner_stride, op, vop, /*reduce=*/false); + }); + + // reduce down the remaining columns + int64_t step[] = { sizeof(scalar_t), sizeof(scalar_t) }; + int64_t remaining = size1 % (4 * Vec::size()); + UNARY_OUTER_LOOP(data, step, remaining, [&] { + char* ptrs[3] = { data[0], data[0], data[1] }; + int64_t strides[] = { 0, 0, inner_stride }; + basic_loop(ptrs, strides, 0, size0, op); + }); +} + +template +static void set_result(const int index, const res_t result, const TensorIteratorBase &iter, const int num_outputs) { + // static_assert(std::is_same_v, "data types must match"); + if (index < num_outputs) { + char *out = (char *) iter.data_ptr(index); + *(res_t *) out = result; + } +} + +template +static void set_results(const res_t result, const TensorIteratorBase &iter, const int num_outputs) { + AT_ASSERT(num_outputs == 1); + set_result(0, result, iter, num_outputs); +} + +template +inline std::enable_if_t +for_each_in_tuple(const std::tuple& /*t*/, const TensorIteratorBase& /*iter*/, const int /*num_outputs*/) { + return i; +} + +template +inline std::enable_if_t +for_each_in_tuple(const std::tuple& t, const TensorIteratorBase &iter, const int num_outputs) { + if (i < (size_t)num_outputs) { + set_result(i, std::get(t), iter, num_outputs); + return for_each_in_tuple(t, iter, num_outputs); + } + return i; +} + +template +static void set_results(const std::tuple& result, const TensorIteratorBase &iter, const int num_outputs) { + AT_ASSERT(num_outputs >= 1); + std::size_t result_size = for_each_in_tuple(result, iter, num_outputs); + AT_ASSERT((size_t)num_outputs == result_size); +} + +template +struct all_same : std::conjunction< + std::is_same... +> {}; + +// data_t is the input/output data type. +// acc_t is a type that contains all the necessary data +// to continue reducing. +// index_t is a one-dimensional index +// +// ops_t is such that &ops_t::reduce, &ops_t::combine, and &ops_t::project exist and satisfy +// the following. +// reduce: (acc_t, data_t, index_t) -> acc_t adds one data point to the accumulated value. +// combine: (acc_t, acc_t) -> acc_t combines two accumulated values into one. +// project: acc_t -> out_t finishes the reduction, getting the required output. +// +// Additionally, acc_t must be default-constructible: +// acc_t {} is an identity for combine, +// and project(acc_t {}) is the value of the operation on zero elements. +// +// The point of `combine` is to support parallelization - +// the idea is to one sequence of `reduce` calls per thread of execution, +// and then to combine them at the end with `combine`. +// +// If there is more than one output element, +// our parallelization strategy is to use one thread for each of them, +// which means that `combine` will never be called. +// +// If, on the other hand, there is only one, then we split the input into +// into several pieces, reduce each separately, and then combine them. + +template +void binary_kernel_reduce(TensorIteratorBase& iter, ops_t ops, init_t init) { + using rf_t = decltype(&ops_t::reduce); + using cf_t = decltype(&ops_t::combine); + using pf_t = decltype(&ops_t::project); + using r_traits = binary_function_traits; + using c_traits = binary_function_traits; + using p_traits = unary_function_traits; + using acc_t = typename p_traits::arg1_t; + using data_t = typename r_traits::arg2_t; + static_assert( + all_same< + acc_t, + init_t, + typename r_traits::arg1_t, + typename r_traits::result_type, + typename c_traits::arg1_t, + typename c_traits::arg2_t, + typename c_traits::result_type>::value, + "all accumulate types must match"); + static_assert( + std::is_default_constructible_v, + "the accumulate type must be default-constructible" + ); + const int num_outputs = iter.noutputs(); + iter.foreach_reduced_elt([&ops, &init, num_outputs](TensorIteratorBase &sub_iter) { + auto reduction_body = [&ops, &sub_iter, num_outputs](acc_t acc, int64_t begin, int64_t end) -> acc_t { + int ntensors = sub_iter.ntensors(); + sub_iter.serial_for_each([&acc, &ops, num_outputs, ntensors, begin](char** data, const int64_t* strides, int64_t size) { + AT_ASSERT(ntensors - num_outputs == 1); + char *in = data[ntensors - 1]; + int64_t stride = strides[ntensors - 1]; + for (const auto i : c10::irange(size)) { + acc = ops.reduce(acc, c10::load(in), begin + i); + in += stride; + } + }, {begin, end}); + return ops.translate_idx(acc, sub_iter.view_offsets()[0]); + }; + acc_t total_acc = init; + auto numel = sub_iter.numel(); + if (numel < at::internal::GRAIN_SIZE || at::get_num_threads() == 1 || + at::in_parallel_region()) { + total_acc = reduction_body(total_acc, 0, numel); + } else { + int max_threads = at::get_num_threads(); + AT_ASSERT(max_threads > 0); + static_assert( + !std::is_same_v, + "Concurrently modifying different references into std::vector is UB." + ); + std::vector buffer((unsigned)max_threads, init); + at::parallel_for(0, numel, internal::GRAIN_SIZE, + [&](int64_t begin, int64_t end) { + auto& acc = buffer[at::get_thread_num()]; + acc = reduction_body(acc, begin, end); + } + ); + for (const auto i : c10::irange(max_threads)) { + total_acc = ops.combine(total_acc, buffer[i]); + } + } + set_results(ops.project(total_acc), sub_iter, num_outputs); + }); +} + +template +void binary_kernel_reduce_vec(TensorIteratorBase& iter, func_t op, vec_func_t vop, double ident = 0) { + using traits = binary_function_traits; + static_assert( + all_same< + typename traits::result_type, + typename traits::arg1_t, + typename traits::arg2_t>::value, + "all types must match"); + + iter.output_base().fill_(ident); + iter.parallel_reduce([&](char** data, const int64_t* strides, int64_t size0, int64_t size1) { + int64_t outer_strides[] = { strides[2], strides[3] }; + if (is_contiguous_reduction(strides)) { + // input is contiguous in dim 0, output is reduced in dim 0 + UNARY_OUTER_LOOP(data, outer_strides, size1, [&] { + vectorized_inner_reduction(data, size0, op, vop); + }); + } else if (is_outer_reduction(strides)) { + // input and output are contiguous in dim 1 + int64_t inner_stride = strides[1]; // stride of input in dim 0 + vectorized_outer_reduction(data, inner_stride, size0, size1, op, vop); + } else { + UNARY_OUTER_LOOP(data, outer_strides, size1, [&] { + char* ptrs[3] = { data[0], data[0], data[1] }; + int64_t inner_strides[3] = { strides[0], strides[0], strides[1] }; + basic_loop(ptrs, inner_strides, 0, size0, op); + }); + } + }); +} + +// when reduction is on most inner dimension (dim 0 in TensorIterator) +// and input has contiguous most inner dimension, `binary_kernel_reduce_lastdim` +// can be used. +inline bool is_reduce_lastdim(TensorIteratorBase& iter) { + return iter.num_reduce_dims() == 1 && iter.is_dim_reduced(0) + && iter.ninputs() == 1 && iter.strides(1)[0] == iter.element_size(1); +} + +template +void binary_kernel_reduce_lastdim(TensorIteratorBase& iter, reduce_func_t reduce_op) { + auto shape = iter.shape(); + int64_t dim_size = shape[0]; + int64_t grain_size = std::max((int64_t) 1, at::internal::GRAIN_SIZE / dim_size); + TensorIterator sub_iter(iter); + // create sub iterator to parallel on all non-reduce-dims + sub_iter.narrow(0, 0, 1); + auto loop = [&](char** data, const int64_t* strides, int64_t size) { + char* out = data[0]; + char* in = data[1]; + for (int64_t i = 0; i < size; ++i) { + reduce_op(out, in, dim_size); + out += strides[0]; + in += strides[1]; + } + }; + sub_iter.for_each(loop, grain_size); +} + +}} // namespace at::native:: diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/ReduceUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/ReduceUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..fd7c4a2750a6c953fb30d29cd13c6924c99bec39 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/ReduceUtils.h @@ -0,0 +1,238 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at::native { +inline namespace CPU_CAPABILITY { + +using namespace vec; + +#define AT_DISPATCH_REDUCTION_TYPES(op, ...) \ + [&] { \ + switch (op) { \ + case ReductionType::SUM: { \ + static constexpr auto reduce = ReductionType::SUM; \ + return __VA_ARGS__(); \ + } \ + case ReductionType::MEAN: { \ + static constexpr auto reduce = ReductionType::MEAN; \ + return __VA_ARGS__(); \ + } \ + case ReductionType::MIN: { \ + static constexpr auto reduce = ReductionType::MIN; \ + return __VA_ARGS__(); \ + } \ + case ReductionType::MAX: { \ + static constexpr auto reduce = ReductionType::MAX; \ + return __VA_ARGS__(); \ + } \ + case ReductionType::PROD: { \ + static constexpr auto reduce = ReductionType::PROD; \ + return __VA_ARGS__(); \ + } \ + } \ + }() + +template +inline vec_scalar_t init_value() { + using acc_t = vec_scalar_t; + acc_t val; + if (reduce == ReductionType::SUM || + reduce == ReductionType::MEAN) { + val = static_cast(0); + } else if (reduce == ReductionType::PROD) { + val = static_cast(1); + } else if (reduce == ReductionType::MAX) { + val = -std::numeric_limits::infinity(); + } else { + TORCH_INTERNAL_ASSERT(reduce == ReductionType::MIN); + val = std::numeric_limits::infinity(); + } + return val; +} + +template +inline vec_scalar_t init_value(const std::optional& initial) { + using acc_t = vec_scalar_t; + if (initial.has_value()) { + return initial.value().to(); + } else { + return init_value(); + } +} + +template +inline void init(scalar_t* out, int64_t size, const vec_scalar_t& val) { + using Vec = Vectorized>; + map( + [val](Vec x) { return Vec(val); }, + out, + out, + size); +} + +template +inline void init(scalar_t* out, int64_t size, const std::optional& initial) { + using acc_t = vec_scalar_t; + acc_t val = init_value(initial); + init(out, size, val); +} + +// overload with `include_self`, used by scatter_reduce +template +inline void init(scalar_t* out, int64_t size, bool include_self = false) { + using acc_t = vec_scalar_t; + if (!include_self) { + acc_t val = init_value(); + init(out, size, val); + } +} + +template +inline void _init(scalar_t* self_ptr, at::opmath_type* buffer_ptr, int64_t size, bool include_self) { + if (!include_self) { + init, reduce>(buffer_ptr, size, include_self); + } else { + vec::convert(self_ptr, buffer_ptr, size); + } +} + +template +inline std::enable_if_t, scalar_t> +_max(const scalar_t& x, const scalar_t& y) { + return at::_isnan(y) ? y : std::max(x, y); +} + +template +inline Vectorized _max(const Vectorized& x, const Vectorized& y) { + // vec::maximum propagates NaN + return vec::maximum(x, y); +} + +template +inline std::enable_if_t, Vec2> +_max(const vec_t& x, const vec_t& y) { + // vec::maximum propagates NaN + return maximum(x, y); +} + +template +inline std::enable_if_t, scalar_t> +_min(const scalar_t& x, const scalar_t& y) { + return at::_isnan(y) ? y : std::min(x, y); +} + +template +inline Vectorized _min(const Vectorized& x, const Vectorized& y) { + // vec::minimum propagates NaN + return vec::minimum(x, y); +} + +template +inline std::enable_if_t, Vec2> +_min(const vec_t& x, const vec_t& y) { + // vec::minimum propagates NaN + return minimum(x, y); +} + +template , int> = 0> +inline void map_acc( + const Op& vec_fun, + accumut* output_data, + const accumut* input_data, + const scalar_t* input_data2, + int64_t size) { + using Vec = vec::Vectorized; + using aVec = vec::Vectorized; + int64_t d = 0; + constexpr int64_t kVecSize = Vec::size(); + constexpr int64_t kaVecSize = aVec::size(); + for (d = 0; d < size - (size % kVecSize); d += kVecSize) { + Vec data2_vec = Vec::loadu(input_data2 + d); + auto [data2_avec0, data2_avec1] = convert_to_float(data2_vec); + aVec input_vec0 = aVec::loadu(input_data + d); + aVec input_vec1 = aVec::loadu(input_data + d + kaVecSize); + vec_fun(input_vec0, data2_avec0).store(output_data + d); + vec_fun(input_vec1, data2_avec1).store(output_data + d + kaVecSize); + } + if (size - d > 0) { + int64_t tail_size = size - d; + Vec data2_vec = Vec::loadu(input_data2 + d, tail_size); + auto [data2_avec0, data2_avec1] = convert_to_float(data2_vec); + if (tail_size > kaVecSize) { + aVec input_vec0 = aVec::loadu(input_data + d); + aVec input_vec1 = aVec::loadu(input_data + d + kaVecSize, tail_size - kaVecSize); + vec_fun(input_vec0, data2_avec0).store(output_data + d); + vec_fun(input_vec1, data2_avec1).store(output_data + d + kaVecSize, tail_size - kaVecSize); + } else { + aVec input_vec0 = aVec::loadu(input_data + d, tail_size); + vec_fun(input_vec0, data2_avec0).store(output_data + d, tail_size); + } + } +} + +// for Max and Min, propagate NaN: +template +inline T update(const T& x, const T& y) { + if (reduce == ReductionType::SUM || + reduce == ReductionType::MEAN) { + return x + y; + } else if (reduce == ReductionType::PROD) { + return x * y; + } else if (reduce == ReductionType::MAX) { + return _max(x, y); + } else { + TORCH_INTERNAL_ASSERT(reduce == ReductionType::MIN); + return _min(x, y); + } +} + +template +inline void update(scalar_t* out, const scalar_t* data, int64_t K) { + using Vec = vec::Vectorized>; + map2( + [](Vec x, Vec y) { return update(x, y); }, + out, + out, + data, + K); +} + +template , int> = 0> +inline void update(at::opmath_type* out, const scalar_t* data, int64_t K) { + using opmath_t = at::opmath_type; + using Vec = vec::Vectorized; + map_acc( + [](Vec x, Vec y) { return update(x, y); }, + out, + out, + data, + K); +} + +template +inline void write(scalar_t* out, int64_t count, int64_t K) { + using Vec = vec::Vectorized>; + if (reduce == ReductionType::MEAN) { + if (count > 0) { + vec::map( + [count](Vec x) { return x / Vec(count); }, + out, + out, + K); + } + } +} + +} // namespace CPU_CAPABILITY +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/ReducedPrecisionFloatGemvFastPathKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/ReducedPrecisionFloatGemvFastPathKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..cd7a74cd74026f8f567d46ed81b2f9e71bc003ce --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/ReducedPrecisionFloatGemvFastPathKernel.h @@ -0,0 +1,21 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::native { +#if !defined(C10_MOBILE) +using fp16_gemv_fn = void(*)(int, int, float, const Half*, int, const Half*, int, float, Half*, int); +DECLARE_DISPATCH(fp16_gemv_fn, fp16_gemv_trans_stub) + +using bf16_gemv_fn = void(*)(int, int, BFloat16, const BFloat16*, int, const BFloat16*, int, BFloat16, BFloat16*, int); +DECLARE_DISPATCH(bf16_gemv_fn, bf16_gemv_trans_stub) + +inline namespace CPU_CAPABILITY { +float fp16_dot_with_fp32_arith(const Half* vec1, const Half* vec2, int64_t len); +float bf16_dot_with_fp32_arith(const BFloat16* vec1, const BFloat16* vec2, int64_t len); +} // inline namespace CPU_CAPABILITY +#endif // !defined(C10_MOBILE) +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SampledAddmmKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SampledAddmmKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..b5081e1822455fcc0927e258222a9a56ee94051c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SampledAddmmKernel.h @@ -0,0 +1,12 @@ +#pragma once + +#include +#include + +namespace at::native { + +using sampled_addmm_sparse_csr_fn = void(*)(const Tensor&, const Tensor&, const Scalar&, const Scalar&, const Tensor&); + +DECLARE_DISPATCH(sampled_addmm_sparse_csr_fn, sampled_addmm_sparse_csr_stub) + +} // at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SerialStackImpl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SerialStackImpl.h new file mode 100644 index 0000000000000000000000000000000000000000..88ba1c91b6c8cb30cae8a55718e400153a9699a7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SerialStackImpl.h @@ -0,0 +1,146 @@ +// Copyright 2004-present Facebook. All Rights Reserved. +#pragma once + +#include + +#include +#include +#include +#include +#include +#include + +namespace at::native::detail { + +struct InputMeta { + void* data_ptr; + int64_t inner_size; + + InputMeta(const Tensor& t, int64_t dim, int64_t inner) + : data_ptr(t.data_ptr()), inner_size(t.sizes()[dim] * inner) {} +}; + +// This kernel is used by two TensorList types: +// 1. stack_serial_kernel uses at::ArrayRef +// 2. Static runtime calls this kernel directly (csrc/jit/runtime/static/ops.cpp) with +// ProcessedNodeInputWrapper. +// When making changes, make sure that they are compatible with both types! +template +void stack_serial_kernel_impl(Tensor& result, TensorListType tensors, int64_t dim) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + dim >= 0 && dim <= result.dim(), + "dim out of range in stack_serial_kernel_impl"); + int64_t outer = + result.numel() / (result.sizes()[dim] * result.strides()[dim]); + scalar_t* result_data = result.data_ptr(); + int64_t ninputs = tensors.size(); + std::vector inputs; + inputs.reserve(ninputs); + for (const auto& tensor : tensors) { + inputs.emplace_back(tensor, dim, tensor.strides()[dim]); + } + + using Vec = vec::Vectorized; + scalar_t* result_ptr = result_data; + for (const auto i : c10::irange(outer)) { + for (const auto j : c10::irange(ninputs)) { + int64_t local_inner = inputs[j].inner_size; + scalar_t* input_ptr = (scalar_t*)(inputs[j].data_ptr) + i * local_inner; + + if (local_inner < Vec::size()) { + for (const auto k : c10::irange(local_inner)) { + result_ptr[k] = input_ptr[k]; + } + } else { + vec::map( + [](Vec x) { return x; }, result_ptr, input_ptr, local_inner); + } + result_ptr += local_inner; + } + } +} + +// Checks to see whether native stack can be invoked under these conditions: +// - result and input tensors are contiguous +// - only one thread is used +// - no type promotion has to occur +// - tensors dtype is Double or Float +template +bool can_use_native_serial_stack_impl(Tensor& result, TensorListType tensors, int64_t dim) { + TORCH_CHECK(tensors.size() > 0, "expected a non-empty list of Tensors"); + const Tensor& first_tensor = tensors[0]; + // stack dimension should be in range [0,firstTensor.dim()) + // dim == firstTensor.dim() is a valid input, but it is handled by default code path + // that uses unsqueeze + if (dim >= first_tensor.dim()) return false; + // Native stack doesn't apply any tensor is skipped. + if (first_tensor.numel() == 0 && first_tensor.dim() == 1) return false; + // there should be no type promotion + if (result.dtype() != first_tensor.dtype()) return false; + + auto first_tensor_mem_format = first_tensor.suggest_memory_format(); + ScalarType dtype = first_tensor.scalar_type(); + + if (!result.is_contiguous(first_tensor_mem_format)) { + return false; + } + + // fast path only works for Double and Float + if (dtype != ScalarType::Double && dtype != ScalarType::Float) { + return false; + } + + // check remainder of inputs +#ifndef STRIP_ERROR_MESSAGES + auto const &first_tensor_shape = first_tensor.sizes(); +#endif + for (const auto i : c10::irange(1, tensors.size())) { + auto const &tensor = tensors[i]; + TORCH_CHECK(tensors[i].sizes() == first_tensor.sizes(), + "stack expects each tensor to be equal size, but got ", first_tensor_shape, + " at entry 0 and ", tensor.sizes(), " at entry ", i); + + // every tensor must be contiguous + // tensor sizes and strides must be the same + // there should be no type promotion + if (!tensor.is_contiguous(first_tensor_mem_format) || + tensor.strides() != first_tensor.strides() || + tensor.dtype() != dtype) { + return false; + } + } + + // fast native stack should only be used when it is not worth using multiple threads + // or there is only one thread. Note that we aren't checking result.numel() here because + // it may not have been resized and we want to defer that cost till later. + int64_t numel_in_stack = first_tensor.numel() * tensors.size(); + return numel_in_stack < at::internal::GRAIN_SIZE || at::get_num_threads() == 1; +} + +template +struct CanUseNativeSerialStack; + +template +struct CanUseNativeSerialStack { + static bool call(Tensor& result, TensorListType tensors, int64_t dim) { + // Inputs cannot alias the output tensor + for (const auto i : c10::irange(tensors.size())) { + auto lap = at::get_overlap_status(result, tensors[i]); + TORCH_CHECK(lap != at::MemOverlapStatus::Partial && + lap != at::MemOverlapStatus::Full, 0, + "unsupported operation: the input tensors cannot refer to any of the " + "output memory locations. Found overlap in input tensor ", i); + } + + return can_use_native_serial_stack_impl(result, tensors, dim); + } +}; + +template +struct CanUseNativeSerialStack { + static bool call(Tensor& result, TensorListType tensors, int64_t dim) { + return can_use_native_serial_stack_impl(result, tensors, dim); + } +}; + +} // namespace at::native::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SoftmaxKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SoftmaxKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..8bc86a036e2ef501824f51bb704bce06856c8e1a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SoftmaxKernel.h @@ -0,0 +1,28 @@ +#pragma once + +#include +#include + +namespace at { +class Tensor; + +namespace native { + +using forward_fn = void (*)(const Tensor&, const Tensor&); +using backward_fn = void(*)(const Tensor &, const Tensor &, const Tensor&); + +DECLARE_DISPATCH(forward_fn, softmax_lastdim_kernel) +DECLARE_DISPATCH(forward_fn, log_softmax_lastdim_kernel) +DECLARE_DISPATCH(backward_fn, softmax_backward_lastdim_kernel) +DECLARE_DISPATCH(backward_fn, log_softmax_backward_lastdim_kernel) + +using forward_fn_with_dim = void(*)(const Tensor &, const Tensor &, const int64_t); +using backward_fn_with_dim = + void (*)(const Tensor&, const Tensor&, const Tensor&, const int64_t); + +DECLARE_DISPATCH(forward_fn_with_dim, softmax_kernel) +DECLARE_DISPATCH(forward_fn_with_dim, log_softmax_kernel) +DECLARE_DISPATCH(backward_fn_with_dim, softmax_backward_kernel) +DECLARE_DISPATCH(backward_fn_with_dim, log_softmax_backward_kernel) +} +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SpmmReduceKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SpmmReduceKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..336d30a941d2703cf0246b86621b73e35d17cf86 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/SpmmReduceKernel.h @@ -0,0 +1,22 @@ +#pragma once + +#include +#include +#include + +namespace at::native { + +using spmm_reduce_fn = void(*)(const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, ReductionType op); +using spmm_reduce_arg_fn = void(*)(const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, ReductionType op); +using spmm_reduce_backward_input_fn = void(*)(const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, ReductionType op); +using spmm_reduce_backward_input_arg_fn = void(*)(const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, ReductionType op); +using spmm_reduce_backward_other_fn = void(*)(const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, const Tensor&, ReductionType op); + +DECLARE_DISPATCH(spmm_reduce_fn, spmm_reduce_stub) +DECLARE_DISPATCH(spmm_reduce_arg_fn, spmm_reduce_arg_stub) +DECLARE_DISPATCH(spmm_reduce_backward_input_fn, spmm_reduce_backward_input_stub) +DECLARE_DISPATCH(spmm_reduce_backward_input_arg_fn, spmm_reduce_backward_input_arg_stub) +DECLARE_DISPATCH(spmm_reduce_backward_other_fn, spmm_reduce_backward_other_stub) +DECLARE_DISPATCH(spmm_reduce_backward_input_arg_fn, spmm_reduce_backward_other_arg_stub) + +} // at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/StackKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/StackKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..3ff30c4bc6310f2899856e6d7032ded1662f1271 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/StackKernel.h @@ -0,0 +1,12 @@ +// Copyright 2004-present Facebook. All Rights Reserved. +#pragma once + +#include +#include + +namespace at::native { + +using stack_serial_fn = void(*)(Tensor &, TensorList, int64_t); +DECLARE_DISPATCH(stack_serial_fn, stack_serial_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/UpSampleKernelAVXAntialias.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/UpSampleKernelAVXAntialias.h new file mode 100644 index 0000000000000000000000000000000000000000..5b545509b1d99e6bbe7ca6ed40d312b9f4c3a5d5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/UpSampleKernelAVXAntialias.h @@ -0,0 +1,1376 @@ +/* +The Python Imaging Library (PIL) is + + Copyright © 1997-2011 by Secret Labs AB + Copyright © 1995-2011 by Fredrik Lundh + +Pillow is the friendly PIL fork. It is + + Copyright © 2010-2022 by Alex Clark and contributors + +Like PIL, Pillow is licensed under the open source HPND License +*/ + +// This code is heavily inspired from PILLOW-SIMD's implementation: +// https://github.com/uploadcare/pillow-simd/blob/simd/master/src/libImaging/Resample.c + +#pragma once +#ifdef CPU_CAPABILITY_AVX2 +// TODO: This file only supports AVX2. We could split the AVX kernels into +// smaller logical blocks in order to port them into the Vec.h logic. This would +// allow to support other vectorization architectures and perhaps also support +// the non-vectorized fallback (we'd need to make sure it's not slower than the +// current fallback). + +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + + +namespace { + +static inline __m128i mm_cvtsi32_si128(const uint8_t* C10_RESTRICT ptr, bool i32_aligned) { + int32_t v; + if (i32_aligned) { + v = *(const int32_t*)ptr; + } else { + std::memcpy(&v, ptr, 4); + } + return _mm_cvtsi32_si128(v); +} + +static inline __m128i mm_cvtepu8_epi32(const uint8_t* C10_RESTRICT ptr, bool i32_aligned) { + return _mm_cvtepu8_epi32(mm_cvtsi32_si128(ptr, i32_aligned)); +} + +static inline void _write_endline_rgb_as_uint32( + uint8_t* C10_RESTRICT output, + uint32_t data +) { + // data is (R G B X), output is (X1 X2 X3 | R1 B1 G1 R2 ...) + // Here we explicitly set X as R1 + uint8_t* data_ptr = reinterpret_cast(&data); + data_ptr[3] = output[3]; + std::memcpy(output, data_ptr, 4); +} + +at::Tensor unpack_rgb(const at::Tensor& packed_tensor) { + // Convert a "packed" tensor (typically RGBRGBRGB if channels_last) into + // RGBARGBARGBA format where A is hard-coded to 0. Each pixel is encoded + // into as 32 bits. This generalizes to num_channels <= 4 and also works for + // non-channels_last tensors. + + const uint8_t* packed = (const uint8_t*)packed_tensor.const_data_ptr(); + auto num_pixels = packed_tensor.size(1) * packed_tensor.size(2); + auto num_channels = packed_tensor.size(0); + + constexpr int rgba_size = 4; + auto unpacked_tensor = at::empty({rgba_size, packed_tensor.size(1), packed_tensor.size(2)}, at::CPU(at::kByte)); + uint8_t* unpacked = (uint8_t*) unpacked_tensor.data_ptr(); + + auto stride_i = packed_tensor.stride(2); + auto stride_j = packed_tensor.stride(0); + + for (const auto i : c10::irange(num_pixels)) { + for (const auto j : c10::irange(rgba_size)) { + unpacked[rgba_size * i + j] = (j < num_channels) ? packed[stride_i * i + stride_j * j] : 0; + } + } + return unpacked_tensor; +} + +void pack_rgb( + const at::Tensor& unpacked_tensor, // IN + const at::Tensor& packed_tensor // OUT +) { + // Convert from unpacked channels last 3-channels or 4-channels tensor into original data layout. + + uint8_t* unpacked = (uint8_t*)unpacked_tensor.data_ptr(); + uint8_t* packed = (uint8_t*)packed_tensor.data_ptr(); + auto num_pixels = packed_tensor.size(1) * packed_tensor.size(2); + auto num_channels = packed_tensor.size(0); + + auto unpacked_increment = unpacked_tensor.size(0); + auto packed_increment = packed_tensor.stride(2); + auto packed_stride = packed_tensor.stride(0); + + TORCH_INTERNAL_ASSERT(unpacked_increment == 3 || unpacked_increment == 4); + + for ([[maybe_unused]] const auto i : c10::irange(num_pixels)) { + for (const auto j : c10::irange(num_channels)) { + packed[j * packed_stride] = unpacked[j]; + } + unpacked += unpacked_increment; + packed += packed_increment; + } +} + +void ImagingResampleHorizontalConvolution8u4x( + uint8_t* C10_RESTRICT lineOut0, + uint8_t* C10_RESTRICT lineOut1, + uint8_t* C10_RESTRICT lineOut2, + uint8_t* C10_RESTRICT lineOut3, + int64_t out_xsize, + const uint8_t* C10_RESTRICT lineIn0, + const uint8_t* C10_RESTRICT lineIn1, + const uint8_t* C10_RESTRICT lineIn2, + const uint8_t* C10_RESTRICT lineIn3, + int64_t in_xsize, + const int64_t* idx_ptr_xmin, + const int64_t* idx_ptr_size, + const int16_t* kk, + int kmax, + unsigned int coefs_precision, + int64_t num_channels, + bool is_last_line); + +void ImagingResampleHorizontalConvolution8u( + uint8_t* C10_RESTRICT lineOut, + int64_t out_xsize, + const uint8_t* C10_RESTRICT lineIn, + int64_t in_xsize, + const int64_t* idx_ptr_xmin, + const int64_t* idx_ptr_size, + const int16_t* kk, + int kmax, + unsigned int coefs_precision, + int64_t num_channels, + bool is_last_line); + +void ImagingResampleVerticalConvolution8u( + uint8_t* C10_RESTRICT lineOut, + const uint8_t* C10_RESTRICT lineIn, + int64_t xsize, + int64_t ids_min, + int64_t ids_size, + const int16_t* k, + unsigned int coefs_precision, + int64_t num_channels); + +template +void ImagingResampleHorizontal( + const at::Tensor & unpacked_output, + const at::Tensor & unpacked_input, + int ksize, + const std::vector& horiz_indices_weights, + unsigned int horiz_weights_precision) { + + // Interpolation horizontal pass: we compute x-axis (image width) interpolation outputs. + + // Input data is stored as + // input = [r[0], g[0], b[0], a[0], r[1], g[1], b[1], a[1], r[2], g[2], b[2], a[2], ...] + // Weights are float values computed for each output pixel and rescaled to uint16: + // weights[i] = [w[i, 0], w[i, 1], ..., w[i, K-1]] + // We want to compute the output as following: + // output = [oR[0], oG[0], oB[0], oA[0], oR[1], oG[1], oB[1], oA[1], ...] + // where + // oR[yoffset + i] = r[yoffset + xmin[i]] * w[i, 0] + ... + r[yoffset + xmin[i] + K-1] * w[i, K-1] + // oG[yoffset + i] = g[yoffset + xmin[i]] * w[i, 0] + ... + g[yoffset + xmin[i] + K-1] * w[i, K-1] + // oB[yoffset + i] = b[yoffset + xmin[i]] * w[i, 0] + ... + b[yoffset + xmin[i] + K-1] * w[i, K-1] + // + + // TODO: we may want to merge that into the fallback code (currently called + // basic_loop_aa_horizontal) + // Although this may not be needed if / when we port all this code to use + // Vec.h since this would potentially give us another fall-back implem + + const int16_t* kk = (int16_t*)(horiz_indices_weights[3].const_data_ptr()); + + auto xout = unpacked_output.size(2); + auto yout = unpacked_output.size(1); + auto xin = unpacked_input.size(2); + TORCH_INTERNAL_ASSERT(num_channels == unpacked_input.size(0)); + + const int64_t* idx_ptr_xmin = horiz_indices_weights[0].const_data_ptr(); + const int64_t* idx_ptr_size = horiz_indices_weights[1].const_data_ptr(); + + uint8_t* unpacked_output_p = unpacked_output.data_ptr(); + const uint8_t* unpacked_input_p = unpacked_input.const_data_ptr(); + + int64_t yy = 0; + auto xout_stride = xout * num_channels; + auto xin_stride = xin * num_channels; + for (; yy < yout - 3; yy += 4) { + ImagingResampleHorizontalConvolution8u4x( + unpacked_output_p + yy * xout_stride, + unpacked_output_p + (yy + 1) * xout_stride, + unpacked_output_p + (yy + 2) * xout_stride, + unpacked_output_p + (yy + 3) * xout_stride, + xout, + unpacked_input_p + yy * xin_stride, + unpacked_input_p + (yy + 1) * xin_stride, + unpacked_input_p + (yy + 2) * xin_stride, + unpacked_input_p + (yy + 3) * xin_stride, + xin, + idx_ptr_xmin, + idx_ptr_size, + kk, + ksize, + horiz_weights_precision, + num_channels, + yy + 3 == yout - 1); + } + for (; yy < yout; yy++) { + ImagingResampleHorizontalConvolution8u( + unpacked_output_p + yy * xout_stride, + xout, + unpacked_input_p + yy * xin_stride, + xin, + idx_ptr_xmin, + idx_ptr_size, + kk, + ksize, + horiz_weights_precision, + num_channels, + yy == yout - 1); + } +} + +void ImagingResampleVertical( + const at::Tensor & unpacked_output, + const at::Tensor & unpacked_input, + int ksize, + const std::vector& vert_indices_weights, + unsigned int vert_weights_precision) { + + // Interpolation vertical pass: we compute y-axis interpolation outputs. + // Input data is stored as + // input = [r[0], g[0], b[0], a[0], r[1], g[1], b[1], a[1], r[2], g[2], b[2], a[2], ...] + // Weights are float values computed for each output pixel and rescaled to uint16: + // weights[i] = [w[i, 0], w[i, 1], ..., w[i, K-1]] + // We want to compute the output as following: + // output = [oR[0], oG[0], oB[0], oA[0], oR[1], oG[1], oB[1], oA[1], ...] + // where + // oR[xoffset + i] = r[xoffset + ymin[i]] * w[i, 0] + ... + r[xoffset + ymin[i] + (K-1) * xsize] * w[i, K-1] + // oG[xoffset + i] = g[xoffset + ymin[i]] * w[i, 0] + ... + g[xoffset + ymin[i] + (K-1) * xsize] * w[i, K-1] + // oB[xoffset + i] = b[xoffset + ymin[i]] * w[i, 0] + ... + b[xoffset + ymin[i] + (K-1) * xsize] * w[i, K-1] + + // TODO: we may want to merge that into the fallback code (currently called + // basic_loop_aa_vertical) + // Although this may not be needed if / when we port all this code to use + // Vec.h since this would potentially give us another fall-back implem + const int16_t* kk = (int16_t*)(vert_indices_weights[3].const_data_ptr()); + + const int64_t* idx_ptr_xmin = vert_indices_weights[0].const_data_ptr(); + const int64_t* idx_ptr_size = vert_indices_weights[1].const_data_ptr(); + + uint8_t* unpacked_output_p = unpacked_output.data_ptr(); + const uint8_t* unpacked_input_p = unpacked_input.const_data_ptr(); + + auto xout = unpacked_output.size(2); + auto yout = unpacked_output.size(1); + const auto num_channels = unpacked_input.size(0); + TORCH_INTERNAL_ASSERT(num_channels == unpacked_output.size(0)); + + auto xout_stride = xout * num_channels; + for (const auto yy : c10::irange(yout)) { + const auto* k = &kk[yy * ksize]; + auto ids_min = idx_ptr_xmin[yy]; + auto ids_size = idx_ptr_size[yy]; + ImagingResampleVerticalConvolution8u( + unpacked_output_p + yy * xout_stride, + unpacked_input_p, + xout, + ids_min, + ids_size, + k, + vert_weights_precision, + num_channels); + } +} + +// This is the only public entry point in this file. It supports bilinear or bicubic +// mode for uint8 dtype when C <= 4, with or without antialias. The +// implem is based on PIL-SIMD. +// Its equivalent implementation (fallback) for when AVX isn't supported or when +// C > 4 is separable_upsample_generic_Nd_kernel_impl() There are a bunch of +// future improvement that can be done: look for the TODOs in this file. +// For details on how the weights are computed and how the multiplications are +// run on int (instead of float weights), see +// [ Weights computation for uint8_t and multiplication trick ] +// For details on how the AVX kernels are implemented, see +// https://gist.github.com/NicolasHug/47c97d731f05eaad5694c173849b86f5 +// See also [ Support for antialias=False as a subcase of antialias=True ] to +// learn more about how the antialias=False case is computed. The same holds +// here: all these kernels are general enough to handle an arbitrary number of +// weights, but when aa=False they could be optimized further. +template +void upsample_avx_bilinear_bicubic_uint8( + const at::Tensor& input_, + const at::Tensor& output, + bool align_corners, + const scale_type& scales, + bool antialias) { + auto batch_size = input_.size(0); + auto num_channels = input_.size(1); + auto xin = input_.size(3); + auto yin = input_.size(2); + auto xout = output.size(3); + auto yout = output.size(2); + + if (xin == xout && yin == yout) { + output.copy_(input_); + return; + } + + at::Tensor input = input_; + if (!(input.is_contiguous() || input.is_contiguous(at::MemoryFormat::ChannelsLast))) { + // If input is not contiguous with memory format channels first or channels last, + // we explicitly convert the input to contiguous channels last memory format. + // This simplifies the rest of the code and let us assume that the format is only contiguous channels first or channels last, + // Most tensors going through this `if` block won't need to go through unpacking, but those having C < 3 may + // have to (this means 2 copies are made). We could avoid the extra copy by handling non-contiguous input + // directly within unpack_rgb() and pack_rgb(), but initial attempts showed that this is fairly complex. + input = input.contiguous(at::MemoryFormat::ChannelsLast); + } + + auto need_horizontal = xout != xin; + auto need_vertical = yout != yin; + + int ksize_horiz, ksize_vert; + std::vector horiz_indices_weights, vert_indices_weights; + unsigned int horiz_weights_precision, vert_weights_precision; + + bool skip_unpacking = (num_channels == 3 || num_channels == 4) && input.is_contiguous(at::MemoryFormat::ChannelsLast); + bool skip_packing = (num_channels == 3 || num_channels == 4) && output.is_contiguous(at::MemoryFormat::ChannelsLast); + + if (need_horizontal) { + int interp_dim = 3; + auto stride = (skip_unpacking) ? num_channels : 4; + std::tie(horiz_indices_weights, ksize_horiz, horiz_weights_precision) = + F::compute_index_ranges_int16_weights( + /*input_size=*/xin, + /*output_size=*/xout, + /*stride=*/stride, + /*ndims=*/4, + /*reshape_dim=*/interp_dim, + /*align_corners=*/align_corners, + /*opt_scale=*/scales[interp_dim - 2], + /*antialias=*/antialias, + /*align_i32=*/true); + } + + if (need_vertical) { + int interp_dim = 2; + auto stride = (skip_unpacking) ? num_channels * xout : 4 * xout; + std::tie(vert_indices_weights, ksize_vert, vert_weights_precision) = + F::compute_index_ranges_int16_weights( + /*input_size=*/yin, + /*output_size=*/yout, + /*stride=*/stride, + /*ndims=*/4, + /*reshape_dim=*/interp_dim, + /*align_corners=*/align_corners, + /*opt_scale=*/scales[interp_dim - 2], + /*antialias=*/antialias, + /*align_i32=*/true); + } + + at::Tensor buffer_horiz, buffer_vert; + // Minor optimization: we can avoid allocating an extra buffer if we're performing + // horizontal-only or vertical-only interpolation, and if the tensor doesn't + // need repacking + if (need_horizontal && (need_vertical || !skip_packing)) { + auto c = (skip_unpacking) ? num_channels : 4; + buffer_horiz = at::empty({c, yin, xout}, input.options()); + } + if (need_vertical && !skip_packing) { + auto c = (skip_unpacking) ? num_channels : 4; + buffer_vert = at::empty({c, yout, xout}, input.options()); + } + + for (const auto i : c10::irange(batch_size)) { + + at::Tensor unpacked_input = (skip_unpacking) ? input[i] : unpack_rgb(input[i]); + at::Tensor unpacked_output; + + if (need_horizontal) { + at::Tensor unpacked_output_temp = (need_vertical || !skip_packing) ? buffer_horiz : output[i]; + + if (skip_unpacking && num_channels == 3) { + ImagingResampleHorizontal<3>( + unpacked_output_temp, + unpacked_input, + ksize_horiz, + horiz_indices_weights, + horiz_weights_precision); + } else { + ImagingResampleHorizontal<4>( + unpacked_output_temp, + unpacked_input, + ksize_horiz, + horiz_indices_weights, + horiz_weights_precision); + } + unpacked_output = unpacked_input = unpacked_output_temp; + } + if (need_vertical) { + unpacked_output = (skip_packing) ? output[i] : buffer_vert; + + ImagingResampleVertical( + unpacked_output, + unpacked_input, + ksize_vert, + vert_indices_weights, + vert_weights_precision + ); + } + + TORCH_INTERNAL_ASSERT(unpacked_output.defined()); + + if (!skip_packing) { + pack_rgb(unpacked_output, output[i]); + } + } +} + +void ImagingResampleHorizontalConvolution8u4x( + uint8_t* C10_RESTRICT lineOut0, + uint8_t* C10_RESTRICT lineOut1, + uint8_t* C10_RESTRICT lineOut2, + uint8_t* C10_RESTRICT lineOut3, + int64_t out_xsize, + const uint8_t* C10_RESTRICT lineIn0, + const uint8_t* C10_RESTRICT lineIn1, + const uint8_t* C10_RESTRICT lineIn2, + const uint8_t* C10_RESTRICT lineIn3, + int64_t in_xsize, + const int64_t* idx_ptr_xmin, + const int64_t* idx_ptr_size, + const int16_t* kk, + int kmax, + unsigned int coefs_precision, + int64_t num_channels, + bool is_last_line) { + + // Interpolation horizontal pass processing together 4 vertical lines. + // - Input data format is RGBA or RGB with R,G,B,A being uint8. In case of RGBA + // we can encode 4 values as a single uint32 value. + // - We split the size of weight vector for a given output index as a sum: + // ids_size = num_blocks_4 * 4 + num_blocks_2 * 2 + num_blocks_1. + // - We load and process 4 weights values in a loop ("block 4") then we process 2 weights values + // in another loop ("block 2") and finally we process 1 weights value in the final loop ("block 1"). + + // Define shuffling masks (low/high) for num_channels 4 and 3 + // Mask low casts lower half of each lane to epi16 and reorder RGBARGBA -> RRGGBBAA: + // [r1 g1 b1 a1 r2 g2 b2 a2 ... | R1 G1 B1 A1 R2 G2 B2 A2 ... ] -> + // [r1 0 r2 0 g1 0 g2 0 b1 0 b2 0 a1 0 a2 0 | R1 0 R2 0 G1 0 G2 0 B1 0 B2 0 A1 0 A2 0] + // Mask high casts upper half of each lane to epi16 and reorder RGBARGBA -> RRGGBBAA:: + // [ ... r3 g3 b3 a3 r4 g4 b4 a4 | ... R3 G3 B3 A3 R4 G4 B4 A4 ] -> + // [r3 0 r4 0 g3 0 g4 0 b3 0 b4 0 a3 0 a4 0 | R3 0 R4 0 G3 0 G4 0 B3 0 B4 0 A3 0 A4 0] + + const auto mask_low_c4 = _mm256_set_epi8( + -1, 7, -1, 3, -1, 6, -1, 2, -1, 5, -1, 1, -1, 4, -1, 0, + -1, 7, -1, 3, -1, 6, -1, 2, -1, 5, -1, 1, -1, 4, -1, 0); + const auto mask_high_c4 = _mm256_set_epi8( + -1, 15, -1, 11, -1, 14, -1, 10, -1, 13, -1, 9, -1, 12, -1, 8, + -1, 15, -1, 11, -1, 14, -1, 10, -1, 13, -1, 9, -1, 12, -1, 8); + const auto mask_low_c3 = _mm256_set_epi8( + -1, -1, -1, -1, -1, 5, -1, 2, -1, 4, -1, 1, -1, 3, -1, 0, + -1, -1, -1, -1, -1, 5, -1, 2, -1, 4, -1, 1, -1, 3, -1, 0); + const auto mask_high_c3 = _mm256_set_epi8( + -1, -1, -1, -1, -1, 11, -1, 8, -1, 10, -1, 7, -1, 9, -1, 6, + -1, -1, -1, -1, -1, 11, -1, 8, -1, 10, -1, 7, -1, 9, -1, 6); + + const auto mask_low = (num_channels == 3) ? mask_low_c3 : mask_low_c4; + const auto mask_high = (num_channels == 3) ? mask_high_c3 : mask_high_c4; + + const auto stride = num_channels * sizeof(uint8_t); + + TORCH_INTERNAL_ASSERT(stride == 3 || stride == 4); + + // out_xsize = output width, out_x = output x index + // ids_min is the input offset index corresponding to out_x + // ids_size is the interpolation size for out_x + + // Let's precompute ids_size limits for block 4 and block 2. + // + // In block 4 (4 means we process 4 weight values together), we read input data + // with _mm_loadu_si128, i.e. 16 bytes, per one line: + // lineIn0 + stride * (i + ids_min) + 16 <= lineIn0 + stride * (ids_size + ids_min) + // --> i <= ids_size - 16.0 / stride + // Strict boundary: + // --> i < ids_size + 1 - int(ceil(16.0 / stride)) = ids_size - b4_delta + // Soft boundary for reading inside the buffer except its boundaries: + // --> i < ids_size + 1 - int(16.0 / stride) = ids_size - b4_delta_soft + // RGBA: b4_delta = b4_delta_soft = 3 + // RGB : b4_delta = 5 + // RGB : b4_delta_soft = 4 + const auto b4_delta = (stride == 4) ? 3 : ((is_last_line) ? 5 : 4); + + // In block 2 (2 means we process 2 weights values together), we read input data + // with _mm_loadl_epi64, i.e. 8 bytes, per one line: + // lineIn0 + stride * (i + ids_min) + 8 <= lineIn0 + stride * (ids_size + ids_min) + // --> i <= ids_size - 8.0 / stride + // Strict boundary: + // --> i < ids_size + 1 - int(ceil(8.0 / stride)) = ids_size - b2_delta + // Soft boundary for reading inside the buffer except its boundaries: + // --> i < ids_size + 1 - int(8.0 / stride) = ids_size - b2_delta_soft + // RGBA: b2_delta = b2_delta_soft = 1 + // RGB : b2_delta = 2 + // RGB : b2_delta_soft = 1 + const auto b2_delta = (stride == 4) ? 1 : ((is_last_line) ? 2 : 1); + + const auto max_out_x_strided = out_xsize * stride; + const auto max_in_x_strided = in_xsize * stride; + + const auto zero = _mm256_setzero_si256(); + const auto initial = _mm256_set1_epi32(1 << (coefs_precision - 1)); + + for (const auto out_x : c10::irange(out_xsize)) { + const auto ids_min = idx_ptr_xmin[out_x]; + const auto ids_size = idx_ptr_size[out_x]; + const auto * k = &kk[out_x * kmax]; + int64_t i = 0; + + auto sss0 = initial; + auto sss1 = initial; + + const auto * lineIn0_min = lineIn0 + ids_min; + const auto * lineIn1_min = lineIn1 + ids_min; + const auto * lineIn2_min = lineIn2 + ids_min; + const auto * lineIn3_min = lineIn3 + ids_min; + + // block 4 + for (; i < ids_size - b4_delta; i += 4) { + // Load 4 values from weight vector + // mmk0 = [wl_0 wh_0 wl_1 wh_1 wl_0 wh_0 wl_1 wh_1 ...] + // mmk1 = [wl_2 wh_2 wl_3 wh_3 wl_2 wh_2 wl_3 wh_3 ...] + const auto mmk0 = _mm256_set1_epi32(*(int32_t*)&k[i]); + const auto mmk1 = _mm256_set1_epi32(*(int32_t*)&k[i + 2]); + + // RGBA: Load 8 pixels (4 per line) from input lines 0 and 1: + // source = [ + // r0 g0 b0 a0 r1 g1 b1 a1 r2 g2 b2 a2 r3 g3 b3 a3 + // R0 G0 B0 A0 R1 G1 B1 A1 R2 G2 B2 A2 R3 G3 B3 A3 + // ] + // RGB: Load 10 pixels (5 per line) + // source = [ + // r0 g0 b0 r1 g1 b1 r2 g2 b2 r3 g3 b3 r4 g4 b4 r5 + // R0 G0 B0 R1 G1 B1 R2 G2 B2 R3 G3 B3 R4 G4 B4 R5 + // ] + auto source = _mm256_inserti128_si256(_mm256_castsi128_si256( + _mm_loadu_si128((__m128i *) (lineIn0_min + stride * i))), + _mm_loadu_si128((__m128i *) (lineIn1_min + stride * i)), 1); + + // Apply mask_low: + // RGBA: + // [r0 0 r1 0 g0 0 g1 0 b0 0 b1 0 a0 0 a1 0 | R0 0 R1 0 G0 0 G1 0 B0 0 B1 0 A0 0 A1 0] + // RGB: + // [r0 0 r1 0 g0 0 g1 0 b0 0 b1 0 0 0 0 0 | R0 0 R1 0 G0 0 G1 0 B0 0 B1 0 0 0 0 0] + auto pix1 = _mm256_shuffle_epi8(source, mask_low); + // Compute output value as C += w0 * C0 + w1 * C1 for each channel in 32-bit precision + sss0 = _mm256_add_epi32(sss0, _mm256_madd_epi16(pix1, mmk0)); + + // Apply mask_high: + // RGBA: + // [r2 0 r3 0 g2 0 g3 0 b2 0 b3 0 a2 0 a3 0 | R2 0 R3 0 G2 0 G3 0 B2 0 B3 0 A2 0 A3 0] + // RGB: + // [r2 0 r3 0 g2 0 g3 0 b2 0 b3 0 0 0 0 0 | R2 0 R3 0 G2 0 G3 0 B2 0 B3 0 0 0 0 0] + auto pix2 = _mm256_shuffle_epi8(source, mask_high); + // Compute output value as C += w2 * C2 + w3 * C3 for each channel in 32-bit precision + sss0 = _mm256_add_epi32(sss0, _mm256_madd_epi16(pix2, mmk1)); + + // Same as above to next lines 2 and 3: + auto source2 = _mm256_inserti128_si256(_mm256_castsi128_si256( + _mm_loadu_si128((__m128i *) (lineIn2_min + stride * i))), + _mm_loadu_si128((__m128i *) (lineIn3_min + stride * i)), 1); + auto pix3 = _mm256_shuffle_epi8(source2, mask_low); + sss1 = _mm256_add_epi32(sss1, _mm256_madd_epi16(pix3, mmk0)); + auto pix4 = _mm256_shuffle_epi8(source2, mask_high); + sss1 = _mm256_add_epi32(sss1, _mm256_madd_epi16(pix4, mmk1)); + } + + // block 2 + for (; i < ids_size - b2_delta; i += 2) { + // Load 2 values from weight vector + // mmk = [wl_0 wh_0 wl_1 wh_1 wl_0 wh_0 wl_1 wh_1 ...] + const auto mmk = _mm256_set1_epi32(*(int32_t*)&k[i]); + + // Load 4 pixels (2 per line) from input lines 0 and 1: + // RGBA: source1 = [ + // r0 g0 b0 a0 r1 g1 b1 a1 0 0 0 0 0 0 0 0 + // R0 G0 B0 A0 R1 G1 B1 A1 0 0 0 0 0 0 0 0 + // ] + // RGB: source1 = [ + // r0 g0 b0 r1 g1 b1 r2 0 0 0 0 0 0 0 0 + // R0 G0 B0 R1 G1 B1 R2 0 0 0 0 0 0 0 0 + // ] + auto source1 = _mm256_inserti128_si256(_mm256_castsi128_si256( + _mm_loadl_epi64((__m128i *) (lineIn0_min + stride * i))), + _mm_loadl_epi64((__m128i *) (lineIn1_min + stride * i)), 1); + // Apply mask_low: + // RGBA: + // [r0 0 r1 0 g0 0 g1 0 b0 0 b1 0 a0 0 a1 0 | R0 0 R1 0 G0 0 G1 0 B0 0 B1 0 A0 0 A1 0] + // RGB: + // [r0 0 r1 0 g0 0 g1 0 b0 0 b1 0 0 0 0 0 | R0 0 R1 0 G0 0 G1 0 B0 0 B1 0 0 0 0 0] + auto pix1 = _mm256_shuffle_epi8(source1, mask_low); + // Compute output value as C += w0 * C0 + w1 * C1 for each channel in 32-bit precision + sss0 = _mm256_add_epi32(sss0, _mm256_madd_epi16(pix1, mmk)); + + // Same as above for lines 2 and 3: + auto source2 = _mm256_inserti128_si256(_mm256_castsi128_si256( + _mm_loadl_epi64((__m128i *) (lineIn2_min + stride * i))), + _mm_loadl_epi64((__m128i *) (lineIn3_min + stride * i)), 1); + auto pix2 = _mm256_shuffle_epi8(source2, mask_low); + sss1 = _mm256_add_epi32(sss1, _mm256_madd_epi16(pix2, mmk)); + } + + // block 1 + const auto i32_aligned = num_channels == 4; + for (; i < ids_size - 1; i++) { + // Load 1 value from weight vector + // mmk = [wl_0 wh_0 0 0 wl_0 wh_0 0 0 ...] + const auto mmk = _mm256_set1_epi32(k[i]); + + // Load 2 pixels (one per line) from input lines 0 and 1: + // RGBA: pix1 = [ + // r0 0 0 0 g0 0 0 0 b0 0 0 0 a0 0 0 0 + // R0 0 0 0 G0 0 0 0 B0 0 0 0 A0 0 0 0 + // ] + // RGB: pix1 = [ + // r0 0 0 0 g0 0 0 0 b0 0 0 0 r1 0 0 0 + // R0 0 0 0 G0 0 0 0 B0 0 0 0 R1 0 0 0 + // ] + auto pix1 = _mm256_inserti128_si256(_mm256_castsi128_si256( + mm_cvtepu8_epi32(lineIn0_min + stride * i, i32_aligned)), + mm_cvtepu8_epi32(lineIn1_min + stride * i, i32_aligned), 1); + // Compute output value as C += w0 * C0 for each channel in 32-bit precision + sss0 = _mm256_add_epi32(sss0, _mm256_madd_epi16(pix1, mmk)); + + // Same as above for lines 2 and 3 + auto pix2 = _mm256_inserti128_si256(_mm256_castsi128_si256( + mm_cvtepu8_epi32(lineIn2_min + stride * i, i32_aligned)), + mm_cvtepu8_epi32(lineIn3_min + stride * i, i32_aligned), 1); + sss1 = _mm256_add_epi32(sss1, _mm256_madd_epi16(pix2, mmk)); + } + + if (i == ids_size - 1) { + // last element + auto mmk = _mm256_set1_epi32(k[i]); + // For num_channels == 3 (3 bytes = one pixel) we tolerate to read 4 bytes + // lines 0, 1 and 2 wont go out of allocated memory bounds + auto pix = _mm256_inserti128_si256(_mm256_castsi128_si256( + mm_cvtepu8_epi32(lineIn0_min + stride * i, i32_aligned)), + mm_cvtepu8_epi32(lineIn1_min + stride * i, i32_aligned), 1); + sss0 = _mm256_add_epi32(sss0, _mm256_madd_epi16(pix, mmk)); + + auto p0 = mm_cvtepu8_epi32(lineIn2_min + stride * i, i32_aligned); + __m128i p1; + if (num_channels == 3 && C10_UNLIKELY(is_last_line && ids_min + stride * i + 4 >= max_in_x_strided)) { + uint8_t input[4]; + std::memcpy(input, lineIn3_min + stride * i, 3); + p1 = mm_cvtepu8_epi32(input, true); + } else { + p1 = mm_cvtepu8_epi32(lineIn3_min + stride * i, i32_aligned); + } + auto pix2 = _mm256_inserti128_si256(_mm256_castsi128_si256(p0), p1, 1); + sss1 = _mm256_add_epi32(sss1, _mm256_madd_epi16(pix2, mmk)); + } + + // Convert fixed point values back to integers (truncating) + sss0 = _mm256_srai_epi32(sss0, coefs_precision); + sss1 = _mm256_srai_epi32(sss1, coefs_precision); + // Convert packed signed 32-bit integers to packed 16-bit integers using signed saturation + // (a a a a b b b b c c c c d d d d) -> (a a b b c c d d 0 0 0 0 0 0 0 0) + sss0 = _mm256_packs_epi32(sss0, zero); + sss1 = _mm256_packs_epi32(sss1, zero); + // Convert packed signed 16-bit integers to packed 8-bit integers using unsigned saturation + // (a a b b c c d d) -> (a b c d 0 0 0 0) + sss0 = _mm256_packus_epi16(sss0, zero); + sss1 = _mm256_packus_epi16(sss1, zero); + + // Write the output into single uint32 + // (a b c d) -> x_uint32 + auto o0 = _mm_cvtsi128_si32(_mm256_castsi256_si128(sss0)); + auto o1 = _mm_cvtsi128_si32(_mm256_extracti128_si256(sss0, 1)); + auto o2 = _mm_cvtsi128_si32(_mm256_castsi256_si128(sss1)); + auto o3 = _mm_cvtsi128_si32(_mm256_extracti128_si256(sss1, 1)); + + const auto out_x_strided = stride * out_x; + + if (num_channels == 3 && C10_UNLIKELY(out_x_strided + 4 >= max_out_x_strided)) { + // Memcpy 4-bytes is faster than 3-bytes and this is a boundary case when we want to write + // 4 bytes (R G B | X) to the output buffer (X1 X2 X3 | R1). + // The 4th byte in the register (X) has a garbage value and 4th byte in the output buffer (R1) has a correct + // value which was previously computed by another line. In other words, it means that we can not overwrite + // it by simply writing 4 bytes from the register to the output. We'll do the following: + // v----------| + // Output = [... X1 X2 X3 | R1 G1 B1 R2 ...] + // First, we write R1 value to the 4th byte of (R G B | X) -> (R G B | R1) + // Second, we write 4 bytes from the register to the output: (X1 X2 X3 | R1) -> (R G B | R1) + // Output = [... R G B | R1 G1 B1 R2 ...] + + _write_endline_rgb_as_uint32(lineOut0 + out_x_strided, o0); + _write_endline_rgb_as_uint32(lineOut1 + out_x_strided, o1); + _write_endline_rgb_as_uint32(lineOut2 + out_x_strided, o2); + + if (C10_UNLIKELY(is_last_line)) { + // When we handle the last line, we can not access the next 4 bytes + // as they are out of memory bounds. + std::memcpy(lineOut3 + out_x_strided, (uint8_t *) &o3, num_channels); + } else { + _write_endline_rgb_as_uint32(lineOut3 + out_x_strided, o3); + } + } else if (num_channels == 3) { + // Memcpy 4-bytes is faster than 3-bytes and here + // we simply write 4 bytes (... R G B X 0 0 0 0 0 ...) where X is a garbage value + // that we will overwrite on the next iteration: (... R G B R G B X 0 0 ...) + std::memcpy(lineOut0 + out_x_strided, (uint8_t *) &o0, 4); + std::memcpy(lineOut1 + out_x_strided, (uint8_t *) &o1, 4); + std::memcpy(lineOut2 + out_x_strided, (uint8_t *) &o2, 4); + std::memcpy(lineOut3 + out_x_strided, (uint8_t *) &o3, 4); + } else { + // num_channels = 4 -> lineOutX + out_x_strided should be uint32 aligned + *(uint32_t *)(lineOut0 + out_x_strided) = o0; + *(uint32_t *)(lineOut1 + out_x_strided) = o1; + *(uint32_t *)(lineOut2 + out_x_strided) = o2; + *(uint32_t *)(lineOut3 + out_x_strided) = o3; + } + } +} + +void ImagingResampleHorizontalConvolution8u( + uint8_t* C10_RESTRICT lineOut, + int64_t out_xsize, + const uint8_t* C10_RESTRICT lineIn, + int64_t in_xsize, + const int64_t* idx_ptr_xmin, + const int64_t* idx_ptr_size, + const int16_t* kk, + int kmax, + unsigned int coefs_precision, + int64_t num_channels, + bool is_last_line) { + + // Interpolation horizontal pass processing only one vertical line. + // - Input data format is RGBA or RGB with R,G,B,A being uint8. In case of RGBA + // we can encode 4 values as a single uint32 value. + // - We split the size of weight vector for a given output index as a sum: + // ids_size = num_blocks_8 * 8 + num_blocks_4 * 4 + num_blocks_2 * 2 + num_blocks_1 + // - We load and process 8 weights values in a loop ("block 8") then 4 weights and 2 weights values in + // in another loops ("block 4" and "block 2") and finally we process 1 weight value in the final loop ("block 1"). + + // Define various shuffling masks + const auto kmask_low = _mm256_set_epi8( + 11, 10, 9, 8, 11, 10, 9, 8, 11, 10, 9, 8, 11, 10, 9, 8, + 3, 2, 1, 0, 3, 2, 1, 0, 3, 2, 1, 0, 3, 2, 1, 0); + const auto kmask_high = _mm256_set_epi8( + 15, 14, 13, 12, 15, 14, 13, 12, 15, 14, 13, 12, 15, 14, 13, 12, + 7, 6, 5, 4, 7, 6, 5, 4, 7, 6, 5, 4, 7, 6, 5, 4); + const auto kmask_hl = _mm256_set_epi8( + 7, 6, 5, 4, 7, 6, 5, 4, 7, 6, 5, 4, 7, 6, 5, 4, + 3, 2, 1, 0, 3, 2, 1, 0, 3, 2, 1, 0, 3, 2, 1, 0); + + const auto mask_low_c4 = _mm256_set_epi8( + -1, 7, -1, 3, -1, 6, -1, 2, -1, 5, -1, 1, -1, 4, -1, 0, + -1, 7, -1, 3, -1, 6, -1, 2, -1, 5, -1, 1, -1, 4, -1, 0); + const auto mask_high_c4 = _mm256_set_epi8( + -1, 15, -1, 11, -1, 14, -1, 10, -1, 13, -1, 9, -1, 12, -1, 8, + -1, 15, -1, 11, -1, 14, -1, 10, -1, 13, -1, 9, -1, 12, -1, 8); + const auto mask_low_c3 = _mm256_set_epi8( + -1, -1, -1, -1, -1, 5, -1, 2, -1, 4, -1, 1, -1, 3, -1, 0, + -1, -1, -1, -1, -1, 5, -1, 2, -1, 4, -1, 1, -1, 3, -1, 0); + const auto mask_high_c3 = _mm256_set_epi8( + -1, -1, -1, -1, -1, 11, -1, 8, -1, 10, -1, 7, -1, 9, -1, 6, + -1, -1, -1, -1, -1, 11, -1, 8, -1, 10, -1, 7, -1, 9, -1, 6); + const auto mask_hl_c3 = _mm256_set_epi8( + -1, -1, -1, -1, -1, 11, -1, 8, -1, 10, -1, 7, -1, 9, -1, 6, + -1, -1, -1, -1, -1, 5, -1, 2, -1, 4, -1, 1, -1, 3, -1, 0); + const auto mask_hl_c4 = _mm256_set_epi8( + -1, 15, -1, 11, -1, 14, -1, 10, -1, 13, -1, 9, -1, 12, -1, 8, + -1, 7, -1, 3, -1, 6, -1, 2, -1, 5, -1, 1, -1, 4, -1, 0); + + const auto mask_low128_c3 = _mm_set_epi8( + -1, -1, -1, -1, -1, 5, -1, 2, -1, 4, -1, 1, -1, 3, -1, 0); + const auto mask_low128_c4 = _mm_set_epi8( + -1, 7, -1, 3, -1, 6, -1, 2, -1, 5, -1, 1, -1, 4, -1, 0); + + const auto mask_low = (num_channels == 3) ? mask_low_c3 : mask_low_c4; + const auto mask_high = (num_channels == 3) ? mask_high_c3 : mask_high_c4; + const auto mask_hl = (num_channels == 3) ? mask_hl_c3 : mask_hl_c4; + const auto mask_low128 = (num_channels == 3) ? mask_low128_c3 : mask_low128_c4; + + // out_xsize = output width, out_x = output x index + // ids_min is the input offset index corresponding to out_x + // ids_size is the interpolation size for out_x + + const auto stride = num_channels * sizeof(uint8_t); + const auto zero = _mm_setzero_si128(); + + TORCH_INTERNAL_ASSERT(stride == 3 || stride == 4); + + // Let's precompute ids_size limits for block 8, block 4 and block 2 + // + // In block 8 (8 means we process 8 weight values together), we read at + // most 32 bytes input data (16 + 16 bytes for RGBA and 12 + 16 bytes for RGB) + // lineIn + stride * (i + ids_min) + 32 <= lineIn + stride * (ids_size + ids_min) + // --> i <= ids_size - 32.0 / stride + // Strict boundary: + // --> i < ids_size + 1 - int(ceil(32.0 / stride)) = ids_size - b8_delta + // Soft boundary for reading inside the buffer except its boundaries: + // --> i < ids_size + 1 - int(32.0 / stride) = ids_size - b8_delta_soft + // RGBA: b8_delta = b8_delta_soft = 7 + // RGB : b8_delta = 10 + // RGB : b8_delta_soft = 9 + const auto b8_delta = (stride == 4) ? 7 : ((is_last_line) ? 10 : 9); + + // In block 4 (4 means we process 4 weight values together), we read + // 16 bytes of input data. + // lineIn + stride * (i + ids_min) + 16 <= lineIn0 + stride * (ids_size + ids_min) + // --> i <= ids_size - 16.0 / stride + // Strict boundary: + // --> i < ids_size + 1 - int(ceil(16.0 / stride)) = ids_size - b4_delta + // Soft boundary for reading inside the buffer except its boundaries: + // --> i < ids_size + 1 - int(16.0 / stride) = ids_size - b4_delta_soft + // RGBA: b4_delta = b4_delta_soft = 3 + // RGB : b4_delta = 5 + // RGB : b4_delta_soft = 4 + const auto b4_delta = (stride == 4) ? 3 : ((is_last_line) ? 5 : 4); + + // In block 2 (2 means we process 2 weight values together), we read + // 8 bytes of input data. + // lineIn0 + stride * (i + ids_min) + 8 <= lineIn0 + stride * (ids_size + ids_min) + // --> i <= ids_size - 8.0 / stride + // Strict boundary: + // --> i < ids_size + 1 - int(ceil(8.0 / stride)) = ids_size - b2_delta + // Soft boundary for reading inside the buffer except its boundaries: + // --> i < ids_size + 1 - int(8.0 / stride) = ids_size - b2_delta_soft + // RGBA: b2_delta = b2_delta_soft = 1 + // RGB : b2_delta = 2 + // RGB : b2_delta_soft = 1 + const auto b2_delta = (stride == 4) ? 1 : ((is_last_line) ? 2 : 1); + + const auto max_out_x_strided = out_xsize * stride; + const auto max_in_x_strided = in_xsize * stride; + + for (const auto out_x : c10::irange(out_xsize)) { + __m128i sss; + const auto ids_min = idx_ptr_xmin[out_x]; + const auto ids_size = idx_ptr_size[out_x]; + const auto * k = &kk[out_x * kmax]; + int64_t i = 0; + + const auto * lineIn_min = lineIn + ids_min; + + if (ids_size < 8) { + sss = _mm_set1_epi32(1 << (coefs_precision - 1)); + } else { + // Lower part will be added to higher, use only half of the error + auto sss256 = _mm256_set1_epi32(1 << (coefs_precision - 2)); + + // block 8 + for (; i < ids_size - b8_delta; i += 8) { + // Load 8 values from weight vector + auto tmp = _mm_loadu_si128((__m128i*)&k[i]); + // ksource = [ + // wl_0 wh_0 wl_1 wh_1 wl_2 wh_2 wl_3 wh_3 wl_4 wh_4 wl_5 wh_5 wl_6 wh_6 wl_7 wh_7 + // wl_0 wh_0 wl_1 wh_1 wl_2 wh_2 wl_3 wh_3 wl_4 wh_4 wl_5 wh_5 wl_6 wh_6 wl_7 wh_7 + // ] + auto ksource = _mm256_insertf128_si256(_mm256_castsi128_si256(tmp), tmp, 1); + + // RGBA: Load 8 pixels from input: + // source = [ + // r0 g0 b0 a0 r1 g1 b1 a1 r2 g2 b2 a2 r3 g3 b3 a3 + // r4 g4 b4 a4 r5 g5 b5 a5 r6 g6 b6 a6 r7 g7 b7 a7 + // ] + // RGB: Load 10 pixels from input (however we can process only 8 pixels): + // source = [ + // r0 g0 b0 r1 g1 b1 r2 g2 b2 r3 g3 b3 r4 g4 b4 r5 + // r4 g4 b4 r5 g5 b5 r6 g6 b6 r7 g7 b7 r8 g8 b8 r9 + // ] + auto source = _mm256_inserti128_si256(_mm256_castsi128_si256( + _mm_loadu_si128((__m128i *) (lineIn_min + stride * i))), + _mm_loadu_si128((__m128i *) (lineIn_min + stride * (i + 4))), 1); + + // Extract lower part of each lane, cast to epi16 and reoder RGBARGBA -> RRGGBBAA + // RGBA: pix1 = [ + // r0 0 r1 0 g0 0 g1 0 b0 0 b1 0 a0 0 a1 0 + // r4 0 r5 0 g4 0 g5 0 b4 0 b5 0 a4 0 a5 0 + // ] + // RGB: pix1 = [ + // r0 0 r1 0 g0 0 g1 0 b0 0 b1 0 0 0 0 0 + // r4 0 r5 0 g4 0 g5 0 b4 0 b5 0 0 0 0 0 + // ] + auto pix1 = _mm256_shuffle_epi8(source, mask_low); + // mmk1 = [ + // wl_0 wh_0 wl_1 wh_1 wl_0 wh_0 wl_1 wh_1 ... ... + // wl_4 wh_4 wl_5 wh_5 wl_4 wh_4 wl_5 wh_5 ... ... + // ] + auto mmk1 = _mm256_shuffle_epi8(ksource, kmask_low); + // Compute output value as + // C += w0 * C0 + w1 * C1 + // C += w4 * C4 + w5 * C5 for each channel in 32-bit precision + sss256 = _mm256_add_epi32(sss256, _mm256_madd_epi16(pix1, mmk1)); + + // Same as above for higher part of each lane + auto pix2 = _mm256_shuffle_epi8(source, mask_high); + auto mmk2 = _mm256_shuffle_epi8(ksource, kmask_high); + // Compute output value as + // C += w2 * C2 + w3 * C3 + // C += w6 * C6 + w7 * C7 for each channel in 32-bit precision + sss256 = _mm256_add_epi32(sss256, _mm256_madd_epi16(pix2, mmk2)); + } + + // block 4 + for (; i < ids_size - b4_delta; i += 4) { + // Load 4 values from weight vector + auto tmp = _mm_loadl_epi64((__m128i *) &k[i]); + // ksource = [ + // wl_0 wh_0 wl_1 wh_1 wl_2 wh_2 wl_3 wh_3 0 0 0 0 0 0 0 0 + // wl_0 wh_0 wl_1 wh_1 wl_2 wh_2 wl_3 wh_3 0 0 0 0 0 0 0 0 + // ] + auto ksource = _mm256_insertf128_si256(_mm256_castsi128_si256(tmp), tmp, 1); + + // Load pixels from input line + tmp = _mm_loadu_si128((__m128i *) (lineIn_min + stride * i)); + // RGBA: source = [ + // r0 g0 b0 a0 r1 g1 b1 a1 r2 g2 b2 a2 r3 g3 b3 a3 + // r0 g0 b0 a0 r1 g1 b1 a1 r2 g2 b2 a2 r3 g3 b3 a3 + // ] + // RGB: source = [ + // r0 g0 b0 r1 g1 b1 r2 g2 b2 r3 g3 b3 r4 g4 b4 r5 + // r0 g0 b0 r1 g1 b1 r2 g2 b2 r3 g3 b3 r4 g4 b4 r5 + // ] + auto source = _mm256_insertf128_si256(_mm256_castsi128_si256(tmp), tmp, 1); + + // Cast source to epi16 and reorder RGBARGBA -> RRGGBBAA + // RGBA: pix = [ + // r0 0 r1 0 g0 0 g1 0 b0 0 b1 0 a0 0 a1 0 + // r2 0 r3 0 g2 0 g3 0 b2 0 b3 0 a2 0 a3 0 + // ] + // RGB: pix = [ + // r0 0 r1 0 g0 0 g1 0 b0 0 b1 0 0 0 0 0 + // r2 0 r3 0 g2 0 g3 0 b2 0 b3 0 0 0 0 0 + // ] + auto pix = _mm256_shuffle_epi8(source, mask_hl); + // mmk = [ + // wl_0 wh_0 wl_1 wh_1 wl_0 wh_0 wl_1 wh_1 ... ... + // wl_2 wh_2 wl_3 wh_3 wl_2 wh_2 wl_3 wh_3 ... ... + // ] + auto mmk = _mm256_shuffle_epi8(ksource, kmask_hl); + // Compute output value as + // C += w0 * C0 + w1 * C1 + // C += w2 * C2 + w3 * C3 for each channel in 32-bit precision + sss256 = _mm256_add_epi32(sss256, _mm256_madd_epi16(pix, mmk)); + } + + // Sum results between the lanes + sss = _mm_add_epi32( + _mm256_extracti128_si256(sss256, 0), + _mm256_extracti128_si256(sss256, 1)); + } + + // block 2 + for (; i < ids_size - b2_delta; i += 2) { + // Load 2 values from weight vector + // mmk = [wl_0 wh_0 wl_1 wh_1 wl_0 wh_0 wl_1 wh_1 ...] + auto mmk = _mm_set1_epi32(*(int32_t*)&k[i]); + // Load pixels from input line + // RGBA: source = [ + // r0 g0 b0 a0 r1 g1 b1 a1 0 0 0 0 0 0 0 0 + // ] + // RGB: source = [ + // r0 g0 b0 r1 g1 b1 r2 g2 0 0 0 0 0 0 0 0 + // ] + auto source = _mm_loadl_epi64((__m128i *) (lineIn_min + stride * i)); + // Cast source to epi16 and reorder RGBARGBA -> RRGGBBAA + auto pix = _mm_shuffle_epi8(source, mask_low128); + // Compute output value as C += w0 * C0 + w1 * C1 for each channel in 32-bit precision + sss = _mm_add_epi32(sss, _mm_madd_epi16(pix, mmk)); + } + + // block 1 + const auto i32_aligned = num_channels == 4; + for (; i < ids_size - 1; i++) { + // Load 1 value from weight vector + // mmk = [wl_0 wh_0 0 0 wl_0 wh_0 0 0 ...] + auto mmk = _mm_set1_epi32(k[i]); + // Load one pixel from input line + // RGBA: pix = [ + // r0 0 0 0 g0 0 0 0 b0 0 0 0 a0 0 0 0 + // ] + // RGB: pix = [ + // r0 0 0 0 g0 0 0 0 b0 0 0 0 r1 0 0 0 + // ] + auto pix = mm_cvtepu8_epi32(lineIn_min + stride * i, i32_aligned); + // Compute output value as C += w0 * C0 for each channel in 32-bit precision + sss = _mm_add_epi32(sss, _mm_madd_epi16(pix, mmk)); + } + + if (i == ids_size - 1) { + // last element + auto mmk = _mm_set1_epi32(k[i]); + __m128i pix; + auto p = lineIn_min + stride * i; + if (num_channels == 3 && C10_UNLIKELY(is_last_line && ids_min + stride * i + 4 >= max_in_x_strided)) { + uint8_t input[4]; + std::memcpy(input, p, 3); + pix = mm_cvtepu8_epi32(input, true); + } else { + pix = mm_cvtepu8_epi32(p, i32_aligned); + } + sss = _mm_add_epi32(sss, _mm_madd_epi16(pix, mmk)); + } + + // Convert fixed point values back to integers (truncating) + sss = _mm_srai_epi32(sss, coefs_precision); + // Convert packed signed 32-bit integers to packed 16-bit integers using signed saturation + // (a a a a b b b b c c c c d d d d) -> (a a b b c c d d 0 0 0 0 0 0 0 0) + sss = _mm_packs_epi32(sss, zero); + // Convert packed signed 16-bit integers to packed 8-bit integers using unsigned saturation + // (a a b b c c d d) -> (a b c d 0 0 0 0) + sss = _mm_packus_epi16(sss, zero); + // Write the output into single uint32 + // (a b c d) -> x_uint32 + auto o = _mm_cvtsi128_si32(sss); + const auto out_x_strided = stride * out_x; + if (num_channels == 3 && C10_UNLIKELY(out_x_strided + 4 >= max_out_x_strided)) { + if (C10_UNLIKELY(is_last_line)) { + // When we handle the last line, we can not access the next 4 bytes + // as they are out of memory bounds. + std::memcpy(lineOut + out_x_strided, (uint8_t *) &o, 3); + } else { + // Memcpy 4-bytes is faster than 3-bytes and this is a boundary case when we want to write + // 4 bytes (R G B | X) to the output buffer (X1 X2 X3 | R1). + // The 4th byte in the register (X) has a garbage value and 4th byte in the output buffer (R1) has a correct + // value which was previously computed by another line. In other words, it means that we can not overwrite + // it by simply writing 4 bytes from the register to the output. We'll do the following: + // v----------| + // Output = [... X1 X2 X3 | R1 G1 B1 R2 ...] + // First, we write R1 value to the 4th byte of (R G B | X) -> (R G B | R1) + // Second, we write 4 bytes from the register to the output: (X1 X2 X3 | R1) -> (R G B | R1) + // Output = [... R G B | R1 G1 B1 R2 ...] + _write_endline_rgb_as_uint32(lineOut + out_x_strided, o); + } + } else if (num_channels == 3) { + // Memcpy 4-bytes is faster than 3-bytes and here + // we simply write 4 bytes (... R G B X 0 0 0 0 0 ...) where X is a garbage value + // that we will overwrite on the next iteration: (... R G B R G B X 0 0 ...) + std::memcpy(lineOut + out_x_strided, (uint8_t *) &o, 4); + } else { + // num_channels = 4 -> lineOut + out_x_strided should be uint32 aligned + *(uint32_t *)(lineOut + out_x_strided) = o; + } + } +} + +void ImagingResampleVerticalConvolution8u( + uint8_t* C10_RESTRICT lineOut, + const uint8_t* C10_RESTRICT lineIn, + int64_t xsize, + int64_t ids_min, + int64_t ids_size, + const int16_t* k, + unsigned int coefs_precision, + int64_t num_channels) { + + // Interpolation vertical pass processing one line. + // - We process x-axis data with blocks of 8, 2 and 1 + // - We split the size of weight vector for a given output index as a sum: K = n * 2 + m. + + // xsize = output width, also equals to input width + // ids_size = interpolation size + // ids_min = input y start index + const auto stride = num_channels * sizeof(uint8_t); + + TORCH_INTERNAL_ASSERT(stride == 3 || stride == 4); + + const int64_t data_size = xsize * stride; + const int64_t data_stride = stride; + constexpr auto vec_size = 256 / 8; + + const auto initial = _mm_set1_epi32(1 << (coefs_precision - 1)); + const auto initial_256 = _mm256_set1_epi32(1 << (coefs_precision - 1)); + const auto zero = _mm_setzero_si128(); + const auto zero_256 = _mm256_setzero_si256(); + + int64_t j = 0; + // block 8 + const auto b8_usable_vec_stride = (vec_size / data_stride) * data_stride; + for (; j < data_size - vec_size; j += b8_usable_vec_stride) { + auto sss0 = initial_256; + auto sss1 = initial_256; + auto sss2 = initial_256; + auto sss3 = initial_256; + int64_t i = 0; + const auto * lineIn_min = lineIn + j + ids_min; + + for (; i < ids_size - 1; i += 2) { + // Load 2 values from weight vector + auto mmk = _mm256_set1_epi32(*(int32_t*)&k[i]); + + // RGBA: Load 8 pixels per line + // source1 = [ + // r0 g0 b0 a0 r1 g1 b1 a1 r2 g2 b2 a2 r3 g3 b3 a3 + // r4 g4 b4 a4 r5 g5 b5 a5 r6 g6 b6 a6 r7 g7 b7 a7 + // ] + // RGB: Load 10 pixels per line (however we can process only 8 pixels): + // source1 = [ + // r0 g0 b0 r1 g1 b1 r2 g2 b2 r3 g3 b3 r4 g4 b4 r5 + // r4 g4 b4 r5 g5 b5 r6 g6 b6 r7 g7 b7 r8 g8 b8 r9 + // ] + auto source1 = + _mm256_loadu_si256((__m256i*)(lineIn_min + data_size * i)); + auto source2 = + _mm256_loadu_si256((__m256i*)(lineIn_min + data_size * (i + 1))); + + // Interleave source1 and source2 from the low half of each 128-bit lane + // and cast the result to epi16 + // RGBA: pix1 = [ + // r0 0 R0 0 g0 0 G0 0 b0 0 B0 0 a0 0 A0 0 + // r1 0 R1 0 g1 0 G1 0 b1 0 B1 0 a1 0 A1 0 + // ] + // RGB: pix1 = [ + // r0 0 R0 0 g0 0 G0 0 b0 0 B0 0 0 0 0 0 + // r1 0 R1 0 g1 0 G1 0 b1 0 B1 0 0 0 0 0 + // ] + auto source_lo = _mm256_unpacklo_epi8(source1, source2); + auto pix1 = _mm256_unpacklo_epi8(source_lo, zero_256); + // Compute output value as + // C += w0 * c0 + w1 * C0 + // C += w0 * c1 + w1 * C1 for each channel in 32-bit precision + sss0 = _mm256_add_epi32(sss0, _mm256_madd_epi16(pix1, mmk)); + + // RGBA: pix2 = [ + // r2 0 R2 0 g2 0 G2 0 b2 0 B2 0 a2 0 A2 0 + // r3 0 R3 0 g3 0 G3 0 b3 0 B3 0 a3 0 A3 0 + // ] + // RGB: pix2 = [ + // r2 0 R2 0 g2 0 G2 0 b2 0 B2 0 0 0 0 0 + // r3 0 R3 0 g3 0 G3 0 b3 0 B3 0 0 0 0 0 + // ] + auto pix2 = _mm256_unpackhi_epi8(source_lo, zero_256); + // Compute output value as + // C += w0 * c2 + w1 * C2 + // C += w0 * c3 + w1 * C3 for each channel in 32-bit precision + sss1 = _mm256_add_epi32(sss1, _mm256_madd_epi16(pix2, mmk)); + + // Same as above for the high half of each 128-bit lane + auto source_hi = _mm256_unpackhi_epi8(source1, source2); + auto pix3 = _mm256_unpacklo_epi8(source_hi, zero_256); + sss2 = _mm256_add_epi32(sss2, _mm256_madd_epi16(pix3, mmk)); + auto pix4 = _mm256_unpackhi_epi8(source_hi, zero_256); + sss3 = _mm256_add_epi32(sss3, _mm256_madd_epi16(pix4, mmk)); + } + // Same processing as above but with a single weight value + for (; i < ids_size; i += 1) { + auto mmk = _mm256_set1_epi32(k[i]); + + auto source1 = _mm256_loadu_si256((__m256i*)(lineIn_min + i * data_size)); + + auto source_lo = _mm256_unpacklo_epi8(source1, zero_256); + auto pix1 = _mm256_unpacklo_epi8(source_lo, zero_256); + sss0 = _mm256_add_epi32(sss0, _mm256_madd_epi16(pix1, mmk)); + auto pix2 = _mm256_unpackhi_epi8(source_lo, zero_256); + sss1 = _mm256_add_epi32(sss1, _mm256_madd_epi16(pix2, mmk)); + + auto source_hi = _mm256_unpackhi_epi8(source1, zero_256); + auto pix3 = _mm256_unpacklo_epi8(source_hi, _mm256_setzero_si256()); + sss2 = _mm256_add_epi32(sss2, _mm256_madd_epi16(pix3, mmk)); + auto pix4 = _mm256_unpackhi_epi8(source_hi, _mm256_setzero_si256()); + sss3 = _mm256_add_epi32(sss3, _mm256_madd_epi16(pix4, mmk)); + } + // Convert fixed point values back to integers (truncating) + sss0 = _mm256_srai_epi32(sss0, coefs_precision); + sss1 = _mm256_srai_epi32(sss1, coefs_precision); + sss2 = _mm256_srai_epi32(sss2, coefs_precision); + sss3 = _mm256_srai_epi32(sss3, coefs_precision); + // Convert packed signed 32-bit integers to packed 16-bit integers using signed saturation + // (a a a a b b b b c c c c d d d d) -> (a a b b c c d d) + sss0 = _mm256_packs_epi32(sss0, sss1); + sss2 = _mm256_packs_epi32(sss2, sss3); + // Convert packed signed 16-bit integers to packed 8-bit integers using unsigned saturation + // (a a b b c c d d) -> (a b c d) + sss0 = _mm256_packus_epi16(sss0, sss2); + + // Stores 32 bytes + _mm256_storeu_si256((__m256i*)(lineOut + j), sss0); + } + + // TODO: Do we also need block 4 ??? + // block 2 + const auto b2_usable_vec_stride = (8 / data_stride) * data_stride; + for (; j < data_size - vec_size / 4; j += b2_usable_vec_stride) { + auto sss0 = initial; + auto sss1 = initial; + int64_t i = 0; + const auto * lineIn_min = lineIn + j + ids_min; + + for (; i < ids_size - 1; i += 2) { + // Load 2 values from weight vector + // mmk = [wl_0 wh_0 wl_1 wh_1 wl_0 wh_0 wl_1 wh_1 ... ] + auto mmk = _mm_set1_epi32(*(int32_t*)&k[i]); + + // Load 2 pixels per line + // RGBA: source1 = [ + // r0 g0 b0 a0 r1 g1 b1 a1 0 0 0 0 0 0 0 0 + // ] + // RGB: source1 = [ + // r0 g0 b0 r1 g1 b1 r2 g2 0 0 0 0 0 0 0 0 + // ] + auto source1 = _mm_loadl_epi64((__m128i *) (lineIn_min + i * data_size)); + auto source2 = _mm_loadl_epi64((__m128i *) (lineIn_min + (i + 1) * data_size)); + // Interleave source1 and source2 and cast the result to epi16 + // RGBA: pix = [ + // r0 0 R0 0 g0 0 G0 0 b0 0 B0 0 a0 0 A0 0 + // ] + // RGB: pix = [ + // r0 0 R0 0 g0 0 G0 0 b0 0 B0 0 0 0 0 0 + // ] + auto source = _mm_unpacklo_epi8(source1, source2); + auto pix = _mm_unpacklo_epi8(source, zero); + // Compute output value as C += w0 * c0 + w1 * C0 for each channel in 32-bit precision + sss0 = _mm_add_epi32(sss0, _mm_madd_epi16(pix, mmk)); + // RGBA: pix = [ + // r1 0 R1 0 g1 0 G1 0 b1 0 B1 0 a1 0 A1 0 + // ] + // RGB: pix = [ + // r1 0 R1 0 g1 0 G1 0 b1 0 B1 0 0 0 0 0 + // ] + pix = _mm_unpackhi_epi8(source, zero); + // Compute output value as C += w0 * c1 + w1 * C1 for each channel in 32-bit precision + sss1 = _mm_add_epi32(sss1, _mm_madd_epi16(pix, mmk)); + } + // Same processing as above but with a single weight value + for (; i < ids_size; i += 1) { + auto mmk = _mm_set1_epi32(k[i]); + + auto source1 = _mm_loadl_epi64((__m128i*) (lineIn_min + i * data_size)); + + auto source = _mm_unpacklo_epi8(source1, zero); + auto pix1 = _mm_unpacklo_epi8(source, zero); + sss0 = _mm_add_epi32(sss0, _mm_madd_epi16(pix1, mmk)); + auto pix2 = _mm_unpackhi_epi8(source, zero); + sss1 = _mm_add_epi32(sss1, _mm_madd_epi16(pix2, mmk)); + } + // Convert fixed point values back to integers (truncating) + sss0 = _mm_srai_epi32(sss0, coefs_precision); + sss1 = _mm_srai_epi32(sss1, coefs_precision); + // Convert packed signed 32-bit integers to packed 16-bit integers using signed saturation + // (a a a a b b b b c c c c d d d d) -> (a a b b c c d d) + sss0 = _mm_packs_epi32(sss0, sss1); + // Convert packed signed 16-bit integers to packed 8-bit integers using unsigned saturation + // (a a b b c c d d) -> (a b c d) + sss0 = _mm_packus_epi16(sss0, sss0); + // Store 2 pixels to the output + _mm_storel_epi64((__m128i*)(lineOut + j), sss0); + } + + // block 1 + const auto b1_usable_vec_stride = (4 / data_stride) * data_stride; + const auto i32_aligned = num_channels == 4; + for (; j < data_size - 4; j += b1_usable_vec_stride) { + auto sss = initial; + int64_t i = 0; + const auto * lineIn_min = lineIn + j + ids_min; + + for (; i < ids_size - 1; i += 2) { + // Load 2 values from weight vector + // mmk = [wl_0 wh_0 wl_1 wh_1 wl_0 wh_0 wl_1 wh_1 ... ] + auto mmk = _mm_set1_epi32(*(int32_t*)&k[i]); + + // Load one pixel per line + // RGBA: source1 = [ + // r0 g0 b0 a0 0 0 0 0 0 0 0 0 0 0 0 0 + // ] + // RGB: source1 = [ + // r0 g0 b0 r1 0 0 0 0 0 0 0 0 0 0 0 0 + // ] + auto source1 = mm_cvtsi32_si128(lineIn_min + i * data_size, i32_aligned); + auto source2 = mm_cvtsi32_si128(lineIn_min + (i + 1) * data_size, i32_aligned); + + // Interleave source1 and source2 and cast the result to epi16 + // RGBA: pix = [ + // r0 0 R0 0 g0 0 G0 0 b0 0 B0 0 a0 0 A0 0 + // ] + // RGB: pix = [ + // r0 0 R0 0 g0 0 G0 0 b0 0 B0 0 0 0 0 0 + // ] + auto source = _mm_unpacklo_epi8(source1, source2); + auto pix = _mm_unpacklo_epi8(source, zero); + // Compute output value as C += w0 * c0 + w1 * C0 for each channel in 32-bit precision + sss = _mm_add_epi32(sss, _mm_madd_epi16(pix, mmk)); + } + + for (; i < ids_size; i++) { + auto mmk = _mm_set1_epi32(k[i]); + auto pix = mm_cvtepu8_epi32(lineIn_min + i * data_size, i32_aligned); + sss = _mm_add_epi32(sss, _mm_madd_epi16(pix, mmk)); + } + sss = _mm_srai_epi32(sss, coefs_precision); + sss = _mm_packs_epi32(sss, zero); + sss = _mm_packus_epi16(sss, zero); + + auto o = _mm_cvtsi128_si32(sss); + + // Here we write 4 bytes to the output even if num_channels < 4, e.g o = {r,g,b,X} for num_channels=3 + // It is OK to write 4th byte (e.g. X) as on the next step we will overwrite it with new data. + // We also wont go out of bounds of lineOut memory allocation + std::memcpy(lineOut + j, (uint8_t *) &o, 4); + } + + for (; j < data_size; j += data_stride) { + auto sss = initial; + int64_t i = 0; + const auto * lineIn_min = lineIn + j + ids_min; + // For RGBA we can use (ids_size - 1) as tighter limit but for RGB we can read outside memory boundary + // for the last remaining line + for (; i < ids_size - 2; i += 2) { + // Load two coefficients at once + auto mmk = _mm_set1_epi32(*(int32_t*)&k[i]); + + // Load 2 lines + auto source1 = mm_cvtsi32_si128(lineIn_min + i * data_size, i32_aligned); + auto source2 = mm_cvtsi32_si128(lineIn_min + (i + 1) * data_size, i32_aligned); + + auto source = _mm_unpacklo_epi8(source1, source2); + auto pix = _mm_unpacklo_epi8(source, zero); + sss = _mm_add_epi32(sss, _mm_madd_epi16(pix, mmk)); + } + + // Same processing as above but with a single weight value + for (; i < ids_size; i++) { + auto mmk = _mm_set1_epi32(k[i]); + + const uint8_t * p = lineIn_min + i * data_size; + __m128i pix; + // There is no much perf gain using more detailed condition like + // num_channels == 3 && ids_min + j + data_size * i + 4 >= in_max_size + // const int64_t in_max_size = data_size * in_ysize; + if (num_channels == 3) { + uint8_t input[4]; + std::memcpy(input, p, 3); + pix = mm_cvtepu8_epi32(input, true); + } else { + pix = mm_cvtepu8_epi32(p, true); + } + sss = _mm_add_epi32(sss, _mm_madd_epi16(pix, mmk)); + } + + // Convert fixed point values back to integers (truncating) + sss = _mm_srai_epi32(sss, coefs_precision); + // Convert packed signed 32-bit integers to packed 16-bit integers using signed saturation + // (a a a a b b b b c c c c d d d d) -> (a a b b c c d d) + sss = _mm_packs_epi32(sss, zero); + // Convert packed signed 16-bit integers to packed 8-bit integers using unsigned saturation + // (a a b b c c d d) -> (a b c d) + sss = _mm_packus_epi16(sss, zero); + // Store one pixel to the output + auto o = _mm_cvtsi128_si32(sss); + if (num_channels == 3 && C10_UNLIKELY(j + 4 >= data_size)) { + std::memcpy(lineOut + j, (uint8_t *) &o, 3); + } else { + std::memcpy(lineOut + j, (uint8_t *) &o, 4); + } + } +} + +} // anonymous namespace +#endif // CPU_CAPABILITY_AVX2 diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/WeightNormKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/WeightNormKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..efcaf4d1c7aa1df4cff5f78faa35d63c7831236c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/WeightNormKernel.h @@ -0,0 +1,20 @@ +#pragma once +#include +#include + +namespace at { +class TensorBase; +} + +namespace at::native { + +using weight_norm_fn = void(*)( + TensorBase&, TensorBase&, const TensorBase&, const TensorBase&, int64_t); +using weight_norm_backward_fn = void(*)( + TensorBase&, TensorBase&, const TensorBase&, const TensorBase&, + const TensorBase&, const TensorBase&, int64_t); + +DECLARE_DISPATCH(weight_norm_fn, weight_norm_stub) +DECLARE_DISPATCH(weight_norm_backward_fn, weight_norm_backward_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/avx_mathfun.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/avx_mathfun.h new file mode 100644 index 0000000000000000000000000000000000000000..f4fd3b7bc461fbf82e8b4a16dd9453e46e124efa --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/avx_mathfun.h @@ -0,0 +1,522 @@ +#pragma once +/* + AVX implementation of sin, cos, sincos, exp and log + + Based on "sse_mathfun.h", by Julien Pommier + http://gruntthepeon.free.fr/ssemath/ + + Copyright (C) 2012 Giovanni Garberoglio + Interdisciplinary Laboratory for Computational Science (LISC) + Fondazione Bruno Kessler and University of Trento + via Sommarive, 18 + I-38123 Trento (Italy) + + This software is provided 'as-is', without any express or implied + warranty. In no event will the authors be held liable for any damages + arising from the use of this software. + + Permission is granted to anyone to use this software for any purpose, + including commercial applications, and to alter it and redistribute it + freely, subject to the following restrictions: + + 1. The origin of this software must not be misrepresented; you must not + claim that you wrote the original software. If you use this software + in a product, an acknowledgment in the product documentation would be + appreciated but is not required. + 2. Altered source versions must be plainly marked as such, and must not be + misrepresented as being the original software. + 3. This notice may not be removed or altered from any source distribution. + + (this is the zlib license) +*/ + +#include + +/* The original source of this file has been modified. */ +#if defined(CPU_CAPABILITY_AVX2) + +#if defined(__GNUC__) +# define ALIGN32_BEG __attribute__((aligned(32))) +#elif defined(_WIN32) +# define ALIGN32_BEG __declspec(align(32)) +#endif + +typedef __m256 v8sf; // vector of 8 float (avx2) +typedef __m256i v8si; // vector of 8 int (avx2) + +/* declare some AVX constants -- why can't I figure a better way to do that? */ +#define _PS256_CONST(Name, Val) \ + static const ALIGN32_BEG float _ps256_##Name[8] = { Val, Val, Val, Val, Val, Val, Val, Val } +#define _PI32_CONST256(Name, Val) \ + static const ALIGN32_BEG int _pi32_256_##Name[8] = { Val, Val, Val, Val, Val, Val, Val, Val } +#define _PS256_CONST_TYPE(Name, Type, Val) \ + static const ALIGN32_BEG Type _ps256_##Name[8] = { Val, Val, Val, Val, Val, Val, Val, Val } + +_PS256_CONST(1 , 1.0f); +_PS256_CONST(0p5, 0.5f); +/* the smallest non denormalized float number */ +_PS256_CONST_TYPE(min_norm_pos, int, 0x00800000); +_PS256_CONST_TYPE(mant_mask, int, 0x7f800000); +_PS256_CONST_TYPE(inv_mant_mask, int, ~0x7f800000); + +_PS256_CONST_TYPE(sign_mask, int, (int)0x80000000); +_PS256_CONST_TYPE(inv_sign_mask, int, ~0x80000000); + +_PI32_CONST256(0, 0); +_PI32_CONST256(1, 1); +_PI32_CONST256(inv1, ~1); +_PI32_CONST256(2, 2); +_PI32_CONST256(4, 4); +_PI32_CONST256(0x7f, 0x7f); + +_PS256_CONST(cephes_SQRTHF, 0.707106781186547524); +_PS256_CONST(cephes_log_p0, 7.0376836292E-2); +_PS256_CONST(cephes_log_p1, - 1.1514610310E-1); +_PS256_CONST(cephes_log_p2, 1.1676998740E-1); +_PS256_CONST(cephes_log_p3, - 1.2420140846E-1); +_PS256_CONST(cephes_log_p4, + 1.4249322787E-1); +_PS256_CONST(cephes_log_p5, - 1.6668057665E-1); +_PS256_CONST(cephes_log_p6, + 2.0000714765E-1); +_PS256_CONST(cephes_log_p7, - 2.4999993993E-1); +_PS256_CONST(cephes_log_p8, + 3.3333331174E-1); +_PS256_CONST(cephes_log_q1, -2.12194440e-4); +_PS256_CONST(cephes_log_q2, 0.693359375); + + +/* natural logarithm computed for 8 simultaneous float + return NaN for x <= 0 +*/ +inline v8sf log256_ps(v8sf x) { + v8si imm0; + v8sf one = *(v8sf*)_ps256_1; + + //v8sf invalid_mask = _mm256_cmple_ps(x, _mm256_setzero_ps()); + v8sf invalid_mask = _mm256_cmp_ps(x, _mm256_setzero_ps(), _CMP_LE_OS); + + x = _mm256_max_ps(x, *(v8sf*)_ps256_min_norm_pos); /* cut off denormalized stuff */ + + // can be done with AVX2 + imm0 = _mm256_srli_epi32(_mm256_castps_si256(x), 23); + + /* keep only the fractional part */ + x = _mm256_and_ps(x, *(v8sf*)_ps256_inv_mant_mask); + x = _mm256_or_ps(x, *(v8sf*)_ps256_0p5); + + // this is again another AVX2 instruction + imm0 = _mm256_sub_epi32(imm0, *(v8si*)_pi32_256_0x7f); + v8sf e = _mm256_cvtepi32_ps(imm0); + + e = _mm256_add_ps(e, one); + + /* part2: + if( x < SQRTHF ) { + e -= 1; + x = x + x - 1.0; + } else { x = x - 1.0; } + */ + //v8sf mask = _mm256_cmplt_ps(x, *(v8sf*)_ps256_cephes_SQRTHF); + v8sf mask = _mm256_cmp_ps(x, *(v8sf*)_ps256_cephes_SQRTHF, _CMP_LT_OS); + v8sf tmp = _mm256_and_ps(x, mask); + x = _mm256_sub_ps(x, one); + e = _mm256_sub_ps(e, _mm256_and_ps(one, mask)); + x = _mm256_add_ps(x, tmp); + + v8sf z = _mm256_mul_ps(x,x); + + v8sf y = *(v8sf*)_ps256_cephes_log_p0; + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_log_p1); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_log_p2); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_log_p3); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_log_p4); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_log_p5); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_log_p6); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_log_p7); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_log_p8); + y = _mm256_mul_ps(y, x); + + y = _mm256_mul_ps(y, z); + + tmp = _mm256_mul_ps(e, *(v8sf*)_ps256_cephes_log_q1); + y = _mm256_add_ps(y, tmp); + + + tmp = _mm256_mul_ps(z, *(v8sf*)_ps256_0p5); + y = _mm256_sub_ps(y, tmp); + + tmp = _mm256_mul_ps(e, *(v8sf*)_ps256_cephes_log_q2); + x = _mm256_add_ps(x, y); + x = _mm256_add_ps(x, tmp); + x = _mm256_or_ps(x, invalid_mask); // negative arg will be NAN + return x; +} + +_PS256_CONST(exp_hi, 88.3762626647949f); +_PS256_CONST(exp_lo, -88.3762626647949f); + +_PS256_CONST(cephes_LOG2EF, 1.44269504088896341); +_PS256_CONST(cephes_exp_C1, 0.693359375); +_PS256_CONST(cephes_exp_C2, -2.12194440e-4); + +_PS256_CONST(cephes_exp_p0, 1.9875691500E-4); +_PS256_CONST(cephes_exp_p1, 1.3981999507E-3); +_PS256_CONST(cephes_exp_p2, 8.3334519073E-3); +_PS256_CONST(cephes_exp_p3, 4.1665795894E-2); +_PS256_CONST(cephes_exp_p4, 1.6666665459E-1); +_PS256_CONST(cephes_exp_p5, 5.0000001201E-1); + +inline v8sf exp256_ps(v8sf x) { + v8sf tmp = _mm256_setzero_ps(), fx; + v8si imm0; + v8sf one = *(v8sf*)_ps256_1; + + x = _mm256_min_ps(x, *(v8sf*)_ps256_exp_hi); + x = _mm256_max_ps(x, *(v8sf*)_ps256_exp_lo); + + /* express exp(x) as exp(g + n*log(2)) */ + fx = _mm256_mul_ps(x, *(v8sf*)_ps256_cephes_LOG2EF); + fx = _mm256_add_ps(fx, *(v8sf*)_ps256_0p5); + + /* how to perform a floorf with SSE: just below */ + //imm0 = _mm256_cvttps_epi32(fx); + //tmp = _mm256_cvtepi32_ps(imm0); + + tmp = _mm256_floor_ps(fx); + + /* if greater, subtract 1 */ + //v8sf mask = _mm256_cmpgt_ps(tmp, fx); + v8sf mask = _mm256_cmp_ps(tmp, fx, _CMP_GT_OS); + mask = _mm256_and_ps(mask, one); + fx = _mm256_sub_ps(tmp, mask); + + tmp = _mm256_mul_ps(fx, *(v8sf*)_ps256_cephes_exp_C1); + v8sf z = _mm256_mul_ps(fx, *(v8sf*)_ps256_cephes_exp_C2); + x = _mm256_sub_ps(x, tmp); + x = _mm256_sub_ps(x, z); + + z = _mm256_mul_ps(x,x); + + v8sf y = *(v8sf*)_ps256_cephes_exp_p0; + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_exp_p1); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_exp_p2); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_exp_p3); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_exp_p4); + y = _mm256_mul_ps(y, x); + y = _mm256_add_ps(y, *(v8sf*)_ps256_cephes_exp_p5); + y = _mm256_mul_ps(y, z); + y = _mm256_add_ps(y, x); + y = _mm256_add_ps(y, one); + + /* build 2^n */ + imm0 = _mm256_cvttps_epi32(fx); + // another two AVX2 instructions + imm0 = _mm256_add_epi32(imm0, *(v8si*)_pi32_256_0x7f); + imm0 = _mm256_slli_epi32(imm0, 23); + v8sf pow2n = _mm256_castsi256_ps(imm0); + y = _mm256_mul_ps(y, pow2n); + return y; +} + +_PS256_CONST(minus_cephes_DP1, -0.78515625); +_PS256_CONST(minus_cephes_DP2, -2.4187564849853515625e-4); +_PS256_CONST(minus_cephes_DP3, -3.77489497744594108e-8); +_PS256_CONST(sincof_p0, -1.9515295891E-4); +_PS256_CONST(sincof_p1, 8.3321608736E-3); +_PS256_CONST(sincof_p2, -1.6666654611E-1); +_PS256_CONST(coscof_p0, 2.443315711809948E-005); +_PS256_CONST(coscof_p1, -1.388731625493765E-003); +_PS256_CONST(coscof_p2, 4.166664568298827E-002); +_PS256_CONST(cephes_FOPI, 1.27323954473516); // 4 / M_PI + + +/* evaluation of 8 sines at onces using AVX intrinsics + + The code is the exact rewriting of the cephes sinf function. + Precision is excellent as long as x < 8192 (I did not bother to + take into account the special handling they have for greater values + -- it does not return garbage for arguments over 8192, though, but + the extra precision is missing). + + Note that it is such that sinf((float)M_PI) = 8.74e-8, which is the + surprising but correct result. + +*/ +inline v8sf sin256_ps(v8sf x) { // any x + v8sf xmm1, xmm2 = _mm256_setzero_ps(), xmm3, sign_bit, y; + v8si imm0, imm2; + + sign_bit = x; + /* take the absolute value */ + x = _mm256_and_ps(x, *(v8sf*)_ps256_inv_sign_mask); + /* extract the sign bit (upper one) */ + sign_bit = _mm256_and_ps(sign_bit, *(v8sf*)_ps256_sign_mask); + + /* scale by 4/Pi */ + y = _mm256_mul_ps(x, *(v8sf*)_ps256_cephes_FOPI); + + /* + Here we start a series of integer operations, which are in the + realm of AVX2. + If we don't have AVX, let's perform them using SSE2 directives + */ + + /* store the integer part of y in mm0 */ + imm2 = _mm256_cvttps_epi32(y); + /* j=(j+1) & (~1) (see the cephes sources) */ + // another two AVX2 instruction + imm2 = _mm256_add_epi32(imm2, *(v8si*)_pi32_256_1); + imm2 = _mm256_and_si256(imm2, *(v8si*)_pi32_256_inv1); + y = _mm256_cvtepi32_ps(imm2); + + /* get the swap sign flag */ + imm0 = _mm256_and_si256(imm2, *(v8si*)_pi32_256_4); + imm0 = _mm256_slli_epi32(imm0, 29); + /* get the polynom selection mask + there is one polynom for 0 <= x <= Pi/4 + and another one for Pi/4 +#include + +namespace at::native { + +using weight_to_int4pack_fn = void (*)(const Tensor&, const Tensor&); +using int4pack_mm_fn = + void (*)(const Tensor&, const Tensor&, const Tensor&, int, const Tensor&); +using int8pack_mm_fn = + void (*)(const Tensor&, const Tensor&, const Tensor&, const Tensor&); +using dyn_quant_pack_4bit_weight_fn = void (*)( + Tensor&, + const Tensor&, + const Tensor&, + const std::optional& bias, + const int64_t, + const int64_t, + const int64_t); +using dyn_quant_matmul_4bit_fn = void (*)( + const Tensor&, + const Tensor&, + const Tensor&, + const int64_t, + const int64_t, + const int64_t, + const int64_t); + +DECLARE_DISPATCH(weight_to_int4pack_fn, weight_to_int4pack_stub) +DECLARE_DISPATCH(int4pack_mm_fn, int4pack_mm_stub) +DECLARE_DISPATCH(int8pack_mm_fn, int8pack_mm_stub) +DECLARE_DISPATCH( + dyn_quant_pack_4bit_weight_fn, + dyn_quant_pack_4bit_weight_stub) +DECLARE_DISPATCH(dyn_quant_matmul_4bit_fn, dyn_quant_matmul_4bit_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/mixed_data_type.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/mixed_data_type.h new file mode 100644 index 0000000000000000000000000000000000000000..13244af3b34a0f36defc69fa7fc219e93aae7757 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/mixed_data_type.h @@ -0,0 +1,41 @@ +#pragma once + +#include + +namespace at::native { + +inline ScalarType first_type() { + return ScalarType::Undefined; +} + +template +inline ScalarType first_type(const Tensor& arg, const Args&... parameters) { + return arg.defined() ? arg.scalar_type() : first_type(parameters...); +} + +template +inline bool is_mixed_type(const Tensor& input, const Args&... parameters) { + const auto parameter_type = first_type(parameters...); + return ((parameter_type != ScalarType::Undefined) && + (parameter_type != input.scalar_type())); +} + +// currently on CPU, mixed data type is only supported +// when input is 'BFloat16' or 'Half' and parameters are 'Float' +inline void check_mixed_data_type(const Tensor& input) { + TORCH_CHECK(at::isReducedFloatingType(input.scalar_type()), + "mixed dtype (CPU): all inputs must share same datatype."); +} + +template +inline void check_mixed_data_type(const Tensor& input, const Tensor& parameter, const Args&... parameters) { + TORCH_CHECK(!parameter.defined() || parameter.scalar_type() == ScalarType::Float, + "mixed dtype (CPU): expect parameter to have scalar type of Float"); + check_mixed_data_type(input, parameters...); +} + +inline ScalarType param_scalar_type(const Tensor& t, bool is_mixed_type) { + return is_mixed_type ? ScalarType::Float : t.scalar_type(); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/moments_utils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/moments_utils.h new file mode 100644 index 0000000000000000000000000000000000000000..6f403d60ea7c09849e1ea9d48625532aa51117c3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/moments_utils.h @@ -0,0 +1,202 @@ +#pragma once + +#include +#include +#include + +#include +#include +#include +#include +#include +#include + +namespace at::native { +inline namespace CPU_CAPABILITY { + +template using opmath_t = at::opmath_type; + +constexpr int64_t kChunkSize = 16; + +template +void AddMoments( + int64_t m0_add, + const T& m1_add, + const T& m2_add, + int64_t& m0, + T& m1, + T& m2) { + const int64_t n = m0 + m0_add; + const T c = n == 0 ? static_cast(0) : static_cast(m0_add) / static_cast(n); + const T delta = m1_add - m1; + m1 += c * delta; + m2 += m2_add + delta * delta * c * static_cast(m0); + m0 = n; +} + +template +C10_ALWAYS_INLINE void AddMomentsVec( + int64_t m0_add, + const vec::Vectorized& m1_add, + const vec::Vectorized& m2_add, + int64_t& m0, + vec::Vectorized& m1, + vec::Vectorized& m2) { + using Vec = vec::Vectorized; + const int64_t n = m0 + m0_add; + const T c = n == 0 ? static_cast(0) : static_cast(m0_add) / static_cast(n); + const Vec c_vec(c); + const Vec delta = m1_add - m1; + m1 += c_vec * delta; + m2 += m2_add + delta * delta * c_vec * Vec(static_cast(m0)); + m0 = n; +} + +template +inline std::enable_if_t>, void> +UpdateMomentsVec( + int64_t m0, + const T* X_ptr, + const std::array>, kChunkSize>& c_vecs, + int64_t& m0_stk0, + vec::Vectorized>& m1_stk0, + vec::Vectorized>& m2_stk0) { + using Vec = vec::Vectorized>; + Vec m1_vec(0); + Vec m2_vec(0); + for (const auto j : c10::irange(m0)) { + const Vec x_vec = Vec::loadu(X_ptr + j * Vec::size()); + const Vec delta_vec = x_vec - m1_vec; + m1_vec += delta_vec * c_vecs[j]; + m2_vec += delta_vec * (x_vec - m1_vec); + } + AddMomentsVec(m0, m1_vec, m2_vec, m0_stk0, m1_stk0, m2_stk0); +} + +// each bfloat16/half vector will be converted to two float vectors, +// and accumulated successively on m1_stk0/m2_stk0. +template +inline std::enable_if_t>, void> +UpdateMomentsVec( + int64_t m0, + const T* X_ptr, + const std::array>, kChunkSize>& c_vecs, + int64_t& m0_stk0, + vec::Vectorized>& m1_stk0, + vec::Vectorized>& m2_stk0) { + using Vec = vec::Vectorized; + using fVec = vec::Vectorized>; + fVec m1_fvec0(0), m1_fvec1(0); + fVec m2_fvec0(0), m2_fvec1(0); + for (const auto j : c10::irange(m0)) { + const Vec x_bvec = Vec::loadu(X_ptr + j * Vec::size()); + auto [x_fvec0, x_fvec1] = convert_to_float(x_bvec); + const fVec delta_fvec0 = x_fvec0 - m1_fvec0; + const fVec delta_fvec1 = x_fvec1 - m1_fvec1; + m1_fvec0 += delta_fvec0 * c_vecs[j]; + m1_fvec1 += delta_fvec1 * c_vecs[j]; + m2_fvec0 += delta_fvec0 * (x_fvec0 - m1_fvec0); + m2_fvec1 += delta_fvec1 * (x_fvec1 - m1_fvec1); + } + AddMomentsVec(m0, m1_fvec0, m2_fvec0, m0_stk0, m1_stk0, m2_stk0); + AddMomentsVec(m0, m1_fvec1, m2_fvec1, m0_stk0, m1_stk0, m2_stk0); +} + +// Compute rowwise moments by Welford algorithm and cascade sum to improve +// numerical stability. +// https://en.wikipedia.org/wiki/Algorithms_for_calculating_variance +// https://en.wikipedia.org/wiki/Pairwise_summation +template +std::pair, opmath_t> RowwiseMomentsImpl(const T* X, int64_t N, int64_t ddof = 0) { + using math_t = opmath_t; + + constexpr int64_t kVecSize = vec::Vectorized::size(); + constexpr int64_t kAccVecSize = vec::Vectorized::size(); + const int64_t n = N / kVecSize; + const int64_t m = divup(n, kChunkSize); + const int64_t depth = utils::CeilLog2(m); + + using Vec = vec::Vectorized; + const Vec kZeroVec(math_t(0)); + c10::SmallVector m0_stk(depth, 0); + c10::SmallVector m1_stk(depth, kZeroVec); + c10::SmallVector m2_stk(depth, kZeroVec); + + for (const auto i : c10::irange(m)) { + const T* X_ptr = X + i * kChunkSize * kVecSize; + const int64_t m0 = std::min(kChunkSize, n - i * kChunkSize); + static std::array c_vecs = ([]() { + std::array result; + for (const auto i : c10::irange(kChunkSize)) { + result[i] = Vec(math_t(1) / static_cast(i + 1)); + } + return result; + })(); + UpdateMomentsVec(m0, X_ptr, c_vecs, m0_stk[0], m1_stk[0], m2_stk[0]); + + int64_t mask = i + 1; + for (int64_t j = 1; j < depth && (mask & 1) == 0; ++j) { + AddMomentsVec( + m0_stk[j - 1], + m1_stk[j - 1], + m2_stk[j - 1], + m0_stk[j], + m1_stk[j], + m2_stk[j]); + m0_stk[j - 1] = 0; + m1_stk[j - 1] = kZeroVec; + m2_stk[j - 1] = kZeroVec; + mask >>= 1; + } + } + for (const auto i : c10::irange(1, depth)) { + AddMomentsVec( + m0_stk[i], m1_stk[i], m2_stk[i], m0_stk[0], m1_stk[0], m2_stk[0]); + } + + std::array m1_arr{}; + std::array m2_arr{}; + m1_stk[0].store(m1_arr.data()); + m2_stk[0].store(m2_arr.data()); + + int64_t m0 = 0; + math_t m1 = 0; + math_t m2 = 0; + for (int64_t i = n * kVecSize; i < N; ++i) { + math_t x = static_cast(X[i]); + const math_t delta = x - m1; + ++m0; + m1 += delta / static_cast(m0); + m2 += delta * (x - m1); + } + // for BFloat16, each vector in m1_arr/m2_arr holds 2*n accumulated result + int64_t m0_add = n * kVecSize / kAccVecSize; + for (const auto i : c10::irange(kAccVecSize)) { + AddMoments(m0_add, m1_arr[i], m2_arr[i], m0, m1, m2); + } + + return std::make_pair(m1, m2 / static_cast(N - ddof)); +} + +template +std::pair, opmath_t> RowwiseMoments(const T* X, int64_t N, int64_t ddof = 0) { + using Vec = vec::Vectorized; + constexpr int64_t kVecSize = Vec::size(); + const int64_t n = N / kVecSize; + const int64_t m = divup(n, kChunkSize); + const int64_t depth = utils::CeilLog2(m); + if (depth <= 4) { + return RowwiseMomentsImpl(X, N, ddof); + } else if (depth <= 8) { + return RowwiseMomentsImpl(X, N, ddof); + } else if (depth <= 16) { + return RowwiseMomentsImpl(X, N, ddof); + } else if (depth <= 32) { + return RowwiseMomentsImpl(X, N, ddof); + } else { + return RowwiseMomentsImpl(X, N, ddof); + } +} + +} // namespace CPU_CAPABILITY +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/utils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/utils.h new file mode 100644 index 0000000000000000000000000000000000000000..3d4c39afe3c75c8887c34142fcefe63e7dc940cb --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/utils.h @@ -0,0 +1,212 @@ +#pragma once + +#include +#include +#include +#include + +#ifdef USE_FBGEMM +#include +#endif + +namespace at::native { + +template +inline void _store(T* dst, at::vec::Vectorized src) { + src.store(dst); +} + +inline void _store(at::BFloat16* dst, at::vec::Vectorized src) { + auto res = at::vec::convert_float_bfloat16(src, src); + res.store(dst, at::vec::Vectorized::size()); +} + +inline void _store(at::Half* dst, at::vec::Vectorized src) { + auto res = at::vec::convert_float_half(src, src); + res.store(dst, at::vec::Vectorized::size()); +} + +inline namespace CPU_CAPABILITY { + +template +inline T data_index_init(T offset) { + return offset; +} + +template +inline T data_index_init(T offset, T& x, const T& X, Args&&... args) { + offset = data_index_init(offset, std::forward(args)...); + x = offset % X; + return offset / X; +} + +inline bool data_index_step() { + return true; +} + +template +inline bool data_index_step(T& x, const T& X, Args&&... args) { + if (data_index_step(std::forward(args)...)) { + x = ((x + 1) == X) ? 0 : (x + 1); + return x == 0; + } + return false; +} + +// Helper struct for bfloat16/float16 vectorization +// Useful when you need float as immediate dtype or accumulate dtype +using namespace vec; +struct Vec2 { + Vectorized val0, val1; + Vec2(Vectorized v0, Vectorized v1) : val0(v0), val1(v1) {} + Vec2(float v) : val0(v), val1(v) {} + static Vec2 loadu(const BFloat16* ptr) { + auto [v0, v1] = convert_bfloat16_float(Vectorized::loadu(ptr)); + return {v0, v1}; + } + static Vec2 loadu(const Half* ptr) { + auto [v0, v1] = convert_half_float(Vectorized::loadu(ptr)); + return {v0, v1}; + } + static Vec2 loadu(const float* ptr) { + return {Vectorized::loadu(ptr), Vectorized::loadu(ptr + Vectorized::size())}; + } + void store(BFloat16* ptr) const { + Vectorized val = convert_float_bfloat16(val0, val1); + val.store(ptr); + } + void store(Half* ptr) const { + Vectorized val = convert_float_half(val0, val1); + val.store(ptr); + } + void store(float* ptr) const { + val0.store(ptr); + val1.store(ptr + Vectorized::size()); + } +}; +inline Vec2 operator+(const Vec2& a, const Vec2& b) { return {a.val0 + b.val0, a.val1 + b.val1}; } +inline Vec2 operator*(const Vec2& a, const Vec2& b) { return {a.val0 * b.val0, a.val1 * b.val1}; } +inline Vec2 operator-(const Vec2& a, const Vec2& b) { return {a.val0 - b.val0, a.val1 - b.val1}; } +inline Vec2 operator/(const Vec2& a, const Vec2& b) { return {a.val0 / b.val0, a.val1 / b.val1}; } +inline Vec2 maximum(const Vec2& a, const Vec2& b) { return {vec::maximum(a.val0, b.val0), vec::maximum(a.val1, b.val1)}; } +inline Vec2 minimum(const Vec2& a, const Vec2& b) { return {vec::minimum(a.val0, b.val0), vec::minimum(a.val1, b.val1)}; } + +template struct VectorizedType { using type = Vectorized; }; +template <> struct VectorizedType { using type = Vec2; }; +template <> struct VectorizedType { using type = Vec2; }; +template using VecType = typename VectorizedType::type; + +// Helper for mixed data type parameter Vec::load +inline std::tuple, Vectorized> load2f(const BFloat16* ptr) { + return convert_bfloat16_float(Vectorized::loadu(ptr)); +} + +inline std::tuple, Vectorized> load2f(const Half* ptr) { + return convert_half_float(Vectorized::loadu(ptr)); +} + +inline std::tuple, Vectorized> load2f(const float* ptr) { + using Vec = Vectorized; + return std::make_tuple(Vec::loadu(ptr), Vec::loadu(ptr + Vec::size())); +} + +inline std::tuple, Vectorized> load2f(const BFloat16* ptr, int64_t count) { + return convert_bfloat16_float(Vectorized::loadu(ptr, count)); +} + +inline std::tuple, Vectorized> load2f(const Half* ptr, int64_t count) { + return convert_half_float(Vectorized::loadu(ptr, count)); +} + +inline std::tuple, Vectorized> load2f(const float* ptr, int64_t count) { + using Vec = Vectorized; + if (count > Vec::size()) { + return std::make_tuple(Vec::loadu(ptr), Vec::loadu(ptr + Vec::size(), count - Vec::size())); + } else { + return std::make_tuple(Vec::loadu(ptr, count), Vec(0)); + } +} + +} // namespace + +namespace utils { + +template +T CeilLog2(const T& x) { + if (x <= 2) { + return 1; + } + // Last set bit is floor(log2(x)), floor + 1 is ceil + // except when x is an exact powers of 2, so subtract 1 first + return static_cast(llvm::findLastSet(static_cast(x) - 1)) + 1; +} + +// matrix transpose: +// src has shape of M by N, with leading dimension of ld_src +// dst has shape of N by M, with leading dimension of ld_dst +template +inline void transpose(int64_t M, int64_t N, const T* src, int64_t ld_src, T* dst, int64_t ld_dst) { + for (int64_t j = 0; j < N; j++) { + for (int64_t i = 0; i < M; i++) { + dst[j * ld_dst + i] = c10::load(&(src[i * ld_src + j])); + } + } +} + +#ifdef USE_FBGEMM +template <> +inline void transpose(int64_t M, int64_t N, const float* src, int64_t ld_src, float* dst, int64_t ld_dst) { + TORCH_CHECK(fbgemm::fbgemmSupportedCPU(), "Your CPU does not support FBGEMM."); + fbgemm::transpose_simd(M, N, src, ld_src, dst, ld_dst); +} + +template <> +inline void transpose(int64_t M, int64_t N, const uint16_t* src, int64_t ld_src, uint16_t* dst, int64_t ld_dst) { + TORCH_CHECK(fbgemm::fbgemmSupportedCPU(), "Your CPU does not support FBGEMM."); + fbgemm::transpose_simd(M, N, src, ld_src, dst, ld_dst); +} +#endif + +template +inline void parallel_sparse_csr( + const TensorAccessor& crow_acc, + const int64_t M, + const int64_t nnz, + const F& f) { + TORCH_CHECK(crow_acc.size(0) == M + 1); + + // directly parallel on `M` may lead to load imbalance, + // statically determine thread partition here to average payload + // for each thread. + int num_threads = at::get_num_threads(); + std::vector thread_splits(num_threads + 1, M); + + int64_t thread_averge_payload = std::max((int64_t)1, divup(nnz, num_threads)); + + thread_splits[0] = 0; + int64_t sum = 0; + int64_t t = 1; + for (const auto m : c10::irange(M)) { + int64_t row_start = crow_acc[m]; + int64_t row_end = crow_acc[m + 1]; + sum += row_end - row_start; + if (sum > t * thread_averge_payload) { + thread_splits[t] = m; + t++; + } + } + // need to restore the last index, + // due to rounding error when calculating `thread_averge_payload`. + thread_splits[num_threads] = M; + + at::parallel_for(0, num_threads, 1, [&](int64_t cbegin, int64_t cend) { + int tid = at::get_thread_num(); + int64_t begin = thread_splits[tid]; + int64_t end = thread_splits[tid + 1]; + f(begin, end); + }); +} + +} // namespace utils + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/zmath.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/zmath.h new file mode 100644 index 0000000000000000000000000000000000000000..2b4f44db085c997f9fdadd49eb078f3cc67a36f2 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cpu/zmath.h @@ -0,0 +1,250 @@ +#pragma once + +// Complex number math operations that act as no-ops for other dtypes. +#include +#include +#include + +namespace at::native { +inline namespace CPU_CAPABILITY { + +template +inline VALUE_TYPE zabs (SCALAR_TYPE z) { + return z; +} + +template<> +inline c10::complex zabs > (c10::complex z) { + return c10::complex(std::abs(z)); +} + +template<> +inline float zabs , float> (c10::complex z) { + return std::abs(z); +} + +template<> +inline c10::complex zabs > (c10::complex z) { + return c10::complex(std::abs(z)); +} + +template<> +inline double zabs , double> (c10::complex z) { + return std::abs(z); +} + +// This overload corresponds to non-complex dtypes. +// The function is consistent with its NumPy equivalent +// for non-complex dtypes where `pi` is returned for +// negative real numbers and `0` is returned for 0 or positive +// real numbers. +// Note: `nan` is propagated. +template +inline VALUE_TYPE angle_impl (SCALAR_TYPE z) { + if (at::_isnan(z)) { + return z; + } + return z < 0 ? c10::pi : 0; +} + +template<> +inline c10::complex angle_impl > (c10::complex z) { + return c10::complex(std::arg(z), 0.0); +} + +template<> +inline float angle_impl , float> (c10::complex z) { + return std::arg(z); +} + +template<> +inline c10::complex angle_impl > (c10::complex z) { + return c10::complex(std::arg(z), 0.0); +} + +template<> +inline double angle_impl , double> (c10::complex z) { + return std::arg(z); +} + +template +constexpr VALUE_TYPE real_impl (SCALAR_TYPE z) { + return z; //No-Op +} + +template<> +constexpr c10::complex real_impl > (c10::complex z) { + return c10::complex(z.real(), 0.0); +} + +template<> +constexpr float real_impl , float> (c10::complex z) { + return z.real(); +} + +template<> +constexpr c10::complex real_impl > (c10::complex z) { + return c10::complex(z.real(), 0.0); +} + +template<> +constexpr double real_impl , double> (c10::complex z) { + return z.real(); +} + +template +constexpr VALUE_TYPE imag_impl (SCALAR_TYPE /*z*/) { + return 0; +} + +template<> +constexpr c10::complex imag_impl > (c10::complex z) { + return c10::complex(z.imag(), 0.0); +} + +template<> +constexpr float imag_impl , float> (c10::complex z) { + return z.imag(); +} + +template<> +constexpr c10::complex imag_impl > (c10::complex z) { + return c10::complex(z.imag(), 0.0); +} + +template<> +constexpr double imag_impl , double> (c10::complex z) { + return z.imag(); +} + +template +inline TYPE conj_impl (TYPE z) { + return z; //No-Op +} + +template<> +inline c10::complex conj_impl > (c10::complex z) { + return c10::complex{z.real(), -z.imag()}; +} + +template<> +inline c10::complex conj_impl > (c10::complex z) { + return c10::complex(z.real(), -z.imag()); +} + +template<> +inline c10::complex conj_impl > (c10::complex z) { + return c10::complex(z.real(), -z.imag()); +} + +template +inline TYPE ceil_impl (TYPE z) { + return std::ceil(z); +} + +template <> +inline c10::complex ceil_impl (c10::complex z) { + return c10::complex(std::ceil(z.real()), std::ceil(z.imag())); +} + +template <> +inline c10::complex ceil_impl (c10::complex z) { + return c10::complex(std::ceil(z.real()), std::ceil(z.imag())); +} + +template +inline c10::complex sgn_impl (c10::complex z) { + if (z == c10::complex(0, 0)) { + return c10::complex(0, 0); + } else { + return z / zabs(z); + } +} + +template +inline TYPE floor_impl (TYPE z) { + return std::floor(z); +} + +template <> +inline c10::complex floor_impl (c10::complex z) { + return c10::complex(std::floor(z.real()), std::floor(z.imag())); +} + +template <> +inline c10::complex floor_impl (c10::complex z) { + return c10::complex(std::floor(z.real()), std::floor(z.imag())); +} + +template +inline TYPE round_impl (TYPE z) { + return std::nearbyint(z); +} + +template <> +inline c10::complex round_impl (c10::complex z) { + return c10::complex(std::nearbyint(z.real()), std::nearbyint(z.imag())); +} + +template <> +inline c10::complex round_impl (c10::complex z) { + return c10::complex(std::nearbyint(z.real()), std::nearbyint(z.imag())); +} + +template +inline TYPE trunc_impl (TYPE z) { + return std::trunc(z); +} + +template <> +inline c10::complex trunc_impl (c10::complex z) { + return c10::complex(std::trunc(z.real()), std::trunc(z.imag())); +} + +template <> +inline c10::complex trunc_impl (c10::complex z) { + return c10::complex(std::trunc(z.real()), std::trunc(z.imag())); +} + +template ::value, int> = 0> +inline TYPE max_impl (TYPE a, TYPE b) { + if (_isnan(a) || _isnan(b)) { + return std::numeric_limits::quiet_NaN(); + } else { + return std::max(a, b); + } +} + +template ::value, int> = 0> +inline TYPE max_impl (TYPE a, TYPE b) { + if (_isnan(a)) { + return a; + } else if (_isnan(b)) { + return b; + } else { + return std::abs(a) > std::abs(b) ? a : b; + } +} + +template ::value, int> = 0> +inline TYPE min_impl (TYPE a, TYPE b) { + if (_isnan(a) || _isnan(b)) { + return std::numeric_limits::quiet_NaN(); + } else { + return std::min(a, b); + } +} + +template ::value, int> = 0> +inline TYPE min_impl (TYPE a, TYPE b) { + if (_isnan(a)) { + return a; + } else if (_isnan(b)) { + return b; + } else { + return std::abs(a) < std::abs(b) ? a : b; + } +} + +} // end namespace +} //end at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Activation.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Activation.h new file mode 100644 index 0000000000000000000000000000000000000000..37425a166de31e206ab2b0d4d5c0188c6e92349e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Activation.h @@ -0,0 +1,20 @@ +#pragma once +#include +#include + +namespace at { +struct TensorIteratorBase; +class TensorBase; +} + +namespace at::native { + +void launch_glu_backward_kernel(const TensorIteratorBase& iter, + int64_t gI_stride, int64_t I_stride); + +void launch_log_sigmoid_forward_kernel(TensorIteratorBase& iter); + +void GeluCUDAKernelImpl(TensorIteratorBase& it, GeluType approximate); +void GeluBackwardCUDAKernelImpl(TensorIteratorBase& it, GeluType approximate); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/BinaryInternal.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/BinaryInternal.h new file mode 100644 index 0000000000000000000000000000000000000000..8efb8f98b1220e52077ab2d4bbcef62d7d91b3c2 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/BinaryInternal.h @@ -0,0 +1,44 @@ +// DON'T include this except from Binary*.cu files. It should not leak into +// headers. +#pragma once +#define TORCH_ASSERT_NO_OPERATORS +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include + +namespace at::native::binary_internal { + +template +struct DivFunctor { + __device__ scalar_t operator()(scalar_t a, scalar_t b) const { + return a / b; + } +}; + +template +struct MulFunctor { + __device__ T operator()(T a, T b) const { + return a * b; + } +}; + +// Workaround for the error: '*' in boolean context, suggest '&&' instead +// [-Werror=int-in-bool-context] +template <> +struct MulFunctor { + __device__ bool operator()(bool a, bool b) const { + return a && b; + } +}; +void div_true_kernel_cuda(TensorIteratorBase& iter); +void div_trunc_kernel_cuda(TensorIteratorBase& iter); +} // namespace at::native::binary_internal diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CUDAJitLoops.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CUDAJitLoops.cuh new file mode 100644 index 0000000000000000000000000000000000000000..c4c3af83ccd80739b293a307da686bd78eabf35d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CUDAJitLoops.cuh @@ -0,0 +1,327 @@ +#pragma once +#include + +// Jiterator functions are guarded behind this macro +#if AT_USE_JITERATOR() + +#include +#include +#include +#include +#include +#include +#include + +#include + +#include +#include +#include + +#include +#include +#include +#include +#include + +namespace at::native { + +template +// warning : unused parameter when tuple is empty. +constexpr auto tuple_to_array_helper(const Tuple& t [[maybe_unused]], std::index_sequence seq) { + constexpr auto size = seq.size(); + return std::array{static_cast(&std::get(t))...}; +} + +// Helper function convert tuple to std::array +// for passing the arguments to CUDA Kernel +// NOTE: We capture tuple by reference, +// so the pointers in returned array are only valid +// till tuple is alive. +template +constexpr auto tuple_to_array(const std::tuple& extra_args) { + constexpr auto tuple_size = sizeof...(Args); + return tuple_to_array_helper(extra_args, std::make_index_sequence{}); +} + +struct JittedVecKernelCache { + // Different kernels are compiled depending on what we're vectorizing up to (1, 2 or 4 elements) + at::cuda::jit::NvrtcFunction vec1; + at::cuda::jit::NvrtcFunction vec2; + at::cuda::jit::NvrtcFunction vec4; + at::cuda::jit::NvrtcFunction vec8; +#ifdef USE_ROCM + at::cuda::jit::NvrtcFunction vec16; +#endif + +}; + +struct JittedKernelVariantCache { + JittedVecKernelCache vec; + at::cuda::jit::NvrtcFunction noncontiguous; + at::cuda::jit::NvrtcFunction dynamic_contiguous; + at::cuda::jit::NvrtcFunction dynamic_noncontiguous; +}; + +inline c10::SmallBuffer pack_kernel_args( + std::initializer_list args, + c10::ArrayRef extra_args) { + c10::SmallBuffer ret(args.size() + extra_args.size()); + std::copy(args.begin(), args.end(), ret.data()); + std::copy(extra_args.begin(), extra_args.end(), ret.data() + args.size()); + return ret; +} + +template +void launch_jitted_unrolled_kernel( + std::mutex &jiterator_mutex, + at::cuda::jit::NvrtcFunction &fn_cache, + const at::cuda::jit::KernelDescriptor &desc, + int64_t N, + array_t data, + inp_calc_t ic, + out_calc_t oc, + loader_t l, + storer_t s, + bool contiguous, + at::cuda::jit::BinaryFuncVariant scalar_pos, + const void* scalar_val, + c10::ArrayRef extra_args) { + + TORCH_INTERNAL_ASSERT(N > 0 && N <= std::numeric_limits::max()); + + int tws = at::cuda::jit::calc_thread_work_size(desc.nInputs, desc.nOutputs, desc.f_inputs_type, desc.result_type); + int bws = tws * num_threads(); + //casting result to int is always safe, intermediate is int64 and won't overflow + const uint32_t grid = (N + bws - 1) / bws; + + if (!fn_cache.function) { + const std::lock_guard lock{jiterator_mutex}; + if (!fn_cache.function) { + constexpr bool dynamic_casting = !std::is_same() || + !std::is_same(); + auto code = at::cuda::jit::generate_code( + desc, contiguous, dynamic_casting, scalar_pos, tws); + fn_cache = at::cuda::jit::jit_pwise_function(code, desc.name); + } + } + + auto args = pack_kernel_args({&N, &data, &ic, &oc, &l, &s, scalar_val}, extra_args); + at::cuda::jit::launch_jitted_pwise_function(fn_cache, args.data(), {grid, 1u, 1u}, + {num_threads(), 1u, 1u}); +} + +template +void launch_jitted_vectorized_kernel( + std::mutex &jiterator_mutex, JittedVecKernelCache &fn_cache, + const at::cuda::jit::KernelDescriptor &desc, int64_t N, array_t data, + at::cuda::jit::BinaryFuncVariant scalar_pos, + const void *scalar_val, c10::ArrayRef extra_args) { + TORCH_INTERNAL_ASSERT(N > 0 && N <= std::numeric_limits::max()); + + int tws = at::cuda::jit::calc_thread_work_size(desc.nInputs, desc.nOutputs, desc.f_inputs_type, desc.result_type); + int bws = tws * num_threads(); + // N is still int64_t for the computation, but it's always safe to cast result to int + const uint32_t grid = (N + bws - 1) / bws; + + int vec_size = at::cuda::jit::can_vectorize_up_to( + desc, c10::ArrayRef(data.data(), data.size())); + +#ifndef USE_ROCM + const auto input_size = c10::scalarTypeToTypeMeta(desc.f_inputs_type).itemsize(); + const int optimal_vec_size = 16 / static_cast(input_size); + vec_size = std::min(optimal_vec_size, vec_size); + // Here we purposely omit vec8 for 1-byte data because of a bug in NVCC + // that causes some numerical mismatches with uint8 on sm80 and sm90. + // TODO: Revisit this after CUDA 12.8 update. + if (input_size < 2) { + vec_size = std::min(vec_size, 4); + } +#endif + + // Different kernels are compiled depending on what we're vectorizing up to (1, 2 or 4 elements) + // fn_ptr is set to the appropriate function based on the vec size and GPU used + at::cuda::jit::NvrtcFunction* fn_ptr = nullptr; + +#ifdef USE_ROCM + if (vec_size == 16) { + fn_ptr = &fn_cache.vec16; + } else +#endif + if (vec_size == 8) { + fn_ptr = &fn_cache.vec8; + } else if (vec_size == 4) { + fn_ptr = &fn_cache.vec4; + } else if (vec_size == 2) { + fn_ptr = &fn_cache.vec2; + } else if (vec_size ==1) { + fn_ptr = &fn_cache.vec1; + } else { + TORCH_INTERNAL_ASSERT(false, "unexpected vec_size for jitter vectorized kernel"); + } + + bool vectorized = vec_size > 1; + + if (!fn_ptr->function) { + const std::lock_guard lock{jiterator_mutex}; + if (!fn_ptr->function) { // cache miss! + + // Generates program + auto code = at::cuda::jit::generate_code( + desc, /*contiguous=*/true, /*dynamic_casting=*/false, + scalar_pos, tws, vectorized, vec_size); + std::string kernel_name = vectorized ? desc.name + "_vectorized" + std::to_string(vec_size) : desc.name; + + // Acquires the program + *fn_ptr = at::cuda::jit::jit_pwise_function(code, kernel_name); + } + } + + if (vectorized) { + auto args = pack_kernel_args({&N, &data, scalar_val}, extra_args); + at::cuda::jit::launch_jitted_pwise_function( + *fn_ptr, args.data(), {grid, 1u, 1u}, {num_threads(), 1u, 1u}); + } else { +// NVCC complains about unused variables l and s. +// It should be false positive in most cases, so we suppress the warnings. +#pragma nv_diagnostic push +#pragma nv_diag_suppress 177 + auto ic = TrivialOffsetCalculator(); + auto oc = TrivialOffsetCalculator<1>(); + auto l = memory::LoadWithoutCast(); + auto s = memory::StoreWithoutCast(); + + auto args = pack_kernel_args( + {&N, &data, &ic, &oc, &l, &s, scalar_val}, extra_args); + at::cuda::jit::launch_jitted_pwise_function( + *fn_ptr, args.data(), {grid, 1u, 1u}, {num_threads(), 1u, 1u}); +#pragma nv_diagnostic pop + } +} + +template +void jitted_gpu_kernel_generic( + std::mutex &jiterator_mutex, + JittedKernelVariantCache &cache, + const at::cuda::jit::KernelDescriptor &desc, + at::cuda::jit::BinaryFuncVariant scalar_pos, + c10::ArrayRef extra_args, + TensorIteratorBase& iter, + const bool dynamic_casting, + const void *scalar_val) { + TORCH_INTERNAL_ASSERT(iter.can_use_32bit_indexing()); + TORCH_INTERNAL_ASSERT(iter.ninputs() == arity); + TORCH_INTERNAL_ASSERT(iter.noutputs() == 1); + + constexpr int ntensors = arity + 1; + std::array data; + for (auto i : c10::irange(ntensors)) { + data[i] = (char*)iter.data_ptr(i); + } + + int64_t numel = iter.numel(); + bool contiguous = iter.is_contiguous(); + + // Decides which of 4 kernel types to launch + // Variations are: + // - Case 1: no dynamic casting and contiguous + // - Case 2: no dynamic casting and noncontiguous + // - Case 3: dynamic casting and contiguous + // - Case 4: dynamic casting and noncontiguous + // These cases align with the non-jitted CUDALoops.cuh cases in gpu_kernel_impl + + if (!dynamic_casting) { + if (contiguous) { + // Case 1: no dynamic casting and contiguous + launch_jitted_vectorized_kernel( + jiterator_mutex, cache.vec, desc, + numel, data, scalar_pos, scalar_val, extra_args); + return; + } + + // Case 2: no dynamic casting and noncontiguous + auto input_offset_calculator = make_input_offset_calculator(iter); + auto output_offset_calculator = make_output_offset_calculator(iter); + auto loader = memory::LoadWithoutCast(); + auto storer = memory::StoreWithoutCast(); + launch_jitted_unrolled_kernel( + jiterator_mutex, cache.noncontiguous, desc, numel, data, + input_offset_calculator, output_offset_calculator, loader, + storer, contiguous, scalar_pos, scalar_val, extra_args); + return; + } + + // Cases 3 and 4 are handled below + // Both require construction of a storer (this asserts 1 output) and one or more loaders + + // Creates store cast to output (the zeroth tensor in TensorIterator) + auto storer = memory::StoreWithCast<1>(iter); + + // Creates load casts from inputs (note offset indexing into the iterators 1...n tensors) + auto loader = memory::LoadWithCast(iter); + + if (contiguous) { + // Case 3: dynamic casting and contiguous + auto input_offset_calculator = TrivialOffsetCalculator(); + auto output_offset_calculator = TrivialOffsetCalculator<1>(); + launch_jitted_unrolled_kernel( + jiterator_mutex, cache.dynamic_contiguous, desc, numel, data, input_offset_calculator, + output_offset_calculator, loader, storer, contiguous, scalar_pos, scalar_val, extra_args); + return; + } + + // Case 4: dynamic casting and noncontiguous + auto input_offset_calculator = make_input_offset_calculator(iter); + auto output_offset_calculator = make_output_offset_calculator(iter); + launch_jitted_unrolled_kernel( + jiterator_mutex, cache.dynamic_noncontiguous, desc, numel, data, input_offset_calculator, + output_offset_calculator, loader, storer, contiguous, scalar_pos, scalar_val, extra_args); +} + +// NOTE: static to reduce chances of name collision. +template < + char const* name, + typename result_type, + typename f_inputs_type, + int arity, + at::cuda::jit::BinaryFuncVariant scalar_pos = + at::cuda::jit::BinaryFuncVariant::NoScalar, + typename... ExtraArgs> +static void jitted_gpu_kernel_impl( + TensorIteratorBase& iter, + const std::string &f, + const bool dynamic_casting, + at::opmath_type scalar_val, + const std::tuple& extra_args) { + + // TODO: Memory use can probably be optimized by re-using kernels across GPUs with + // the same compute capability + static std::mutex jiterator_mutex; + static std::vector device_caches(c10::cuda::device_count()); + + constexpr int nInputs = arity; + constexpr int nOutputs = 1; // TODO: Support more than 1 output + static const auto desc = at::cuda::jit::make_kernel_descriptor< + result_type, f_inputs_type, ExtraArgs...>(name, f, nInputs, nOutputs); + + auto &cache = device_caches[iter.device().index()]; + auto extra_args_array = tuple_to_array(extra_args); + return jitted_gpu_kernel_generic( + jiterator_mutex, + cache, + desc, + scalar_pos, + extra_args_array, + iter, + dynamic_casting, + &scalar_val + ); +} + +} // at::native + +#endif // AT_USE_JITERATOR() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CUDALoops.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CUDALoops.cuh new file mode 100644 index 0000000000000000000000000000000000000000..92b77dfb6aeaf41d7b817df266bd5ba602be5dae --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CUDALoops.cuh @@ -0,0 +1,534 @@ +#pragma once + +// This file provides two functions to help write GPU elementwise kernels: +// +// gpu_kernel(TensorIterator iter, ) +// gpu_kernel_with_scalars(TensorIterator iter, ) +// +// The gpu_kernel_with_scalars generates specializations that support a +// single scalar CPU argument, such as from `cuda_tensor + 5`. The CPU scalar +// is lifted to a kernel parameter instead of copying to device memory. +// This should be used in conjunction with TensorIterator::allow_cpu_scalars_, +// which is the default for TensorIterator::binary_op. Otherwise, all inputs +// and the output must be on the GPU. +// +// For example, to write a reciprocal kernel for GPU float Tensors: +// +// gpu_kernel(iter, []GPU_LAMBDA(float a) { +// return 1.0f / a; +// }); +// +// To write a multiplication kernel for GPU float Tensors where one argument +// may be a CPU scalar: +// +// gpu_kernel_with_scalars(iter, []GPU_LAMBDA(float a, float b) { +// return a * b; +// }); +// +// See BinaryOpsKernel.cu for the complete implementation +// + +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include + +#ifdef __NVCC__ +#define ASSERT_HOST_DEVICE_LAMBDA(type) \ + static_assert( \ + __nv_is_extended_host_device_lambda_closure_type(type), \ + #type " must be a __host__ __device__ lambda") +#else +#define ASSERT_HOST_DEVICE_LAMBDA(type) +#endif + +namespace at::native { + + +template +constexpr auto sum_of_sizes(args_t args, std::index_sequence) { + if constexpr (sizeof...(Is) == 0) { + return 0; + } else { + return (sizeof(std::tuple_element_t) + ...); + } +} + +#ifdef USE_ROCM +template +constexpr auto elems_per_thread(){ + if constexpr (io_sizes == 1) { + return 16; + } else if constexpr (io_sizes < 4) { + return 8; + } else { + return 4; + } +} +#else +template +constexpr auto elems_per_thread(){ + if constexpr (io_sizes == 1) { + return 16; + } else { + return 8; + } +} +#endif + + +//thread work size of 8 regresses the perf of elementwise kernel on cuda +//this doesn't change ROCm behavior as thread_work_size is already 4 on ROCm +constexpr int elementwise_thread_work_size() {return 4;} +constexpr int elementwise_block_work_size() { + return elementwise_thread_work_size() * num_threads(); +} + +template +constexpr auto io_block_work_size() { + return num_threads() * elems_per_thread(); +} + +#ifdef USE_ROCM +template +constexpr auto input_size(args_t args, std::index_sequence) { + if constexpr (sizeof...(Is) == 0) { + return 0; + } else { + return sizeof(std::tuple_element_t<0, args_t>); + } +} + +template +constexpr auto calc_optimal_vec_size() { + static_assert(vec_size != 0); + static_assert(io_size != 0); + if constexpr (io_size == 1 && vec_size >= 16) { + return 16; + } else if constexpr (io_size <= 2 && vec_size >= 8) { + return 8; + } else if constexpr (io_size <= 4 && vec_size >= 4) { + return 4; + } else if constexpr (vec_size >= 4) { + return 4; + } else if constexpr (vec_size >= 2) { + return 2; + } else { + return 1; + } +} +#endif + +template +constexpr auto calc_io_size(){ + using traits = function_traits; + using args_t = typename traits::ArgsTuple; +#ifdef USE_ROCM + constexpr auto input_size = at::native::input_size(args_t{}, std::make_index_sequence>{}); + constexpr auto output_size = sizeof(typename traits::result_type); + return (input_size > 0) ? ((input_size < output_size) ? input_size : output_size) : output_size; +#else + constexpr auto input_size = at::native::sum_of_sizes(args_t{}, std::make_index_sequence>{}); + constexpr auto output_size = sizeof(typename traits::result_type); + return input_size + output_size; +#endif +} + +#ifndef USE_ROCM +// To save on binary size of libtorch_cuda.so, we split the vectorized_elementwise_kernel +// into two: one for vec_size=8 and one for vec_size=[2, 4], since vec8 is going to be +// used on sm_90 and sm_100 exclusively. +template +C10_LAUNCH_BOUNDS_1(num_threads()) +__global__ void vectorized_elementwise_kernel(int N, func_t f, array_t data) { + if constexpr (vec_size == 8) { +#if __CUDA_ARCH__ == 900 || __CUDA_ARCH__ == 1000 + using traits = function_traits; + constexpr auto io_size = calc_io_size(); + int remaining = N - io_block_work_size() * blockIdx.x; + + if (remaining < io_block_work_size()) { // if this block handles the reminder, + // just do a naive unrolled loop + auto input_calc = TrivialOffsetCalculator(); + auto output_calc = TrivialOffsetCalculator<1>(); + auto loader = memory::LoadWithoutCast(); + auto storer = memory::StoreWithoutCast(); + auto policy = memory::policies::unroll< + array_t, + decltype(input_calc), + decltype(output_calc), + memory::LoadWithoutCast, + memory::StoreWithoutCast, + elems_per_thread()>( + data, remaining, input_calc, output_calc, loader, storer); + elementwise_kernel_helper(f, policy); + } else { // if this block has a full `block_work_size` data to handle, use + // vectorized memory access + elementwise_kernel_helper( + f, memory::policies::vectorized()>(data)); + } +#endif // __CUDA_ARCH__ == 900 || __CUDA_ARCH__ == 1000 + } else { + using traits = function_traits; + constexpr auto io_size = calc_io_size(); + int remaining = N - io_block_work_size() * blockIdx.x; + + if (remaining < io_block_work_size()) { // if this block handles the reminder, + // just do a naive unrolled loop + auto input_calc = TrivialOffsetCalculator(); + auto output_calc = TrivialOffsetCalculator<1>(); + auto loader = memory::LoadWithoutCast(); + auto storer = memory::StoreWithoutCast(); + auto policy = memory::policies::unroll< + array_t, + decltype(input_calc), + decltype(output_calc), + memory::LoadWithoutCast, + memory::StoreWithoutCast, + elems_per_thread()>( + data, remaining, input_calc, output_calc, loader, storer); + elementwise_kernel_helper(f, policy); + } else { // if this block has a full `block_work_size` data to handle, use + // vectorized memory access + elementwise_kernel_helper( + f, memory::policies::vectorized()>(data)); + } + } +} + +#else // USE_ROCM +template +C10_LAUNCH_BOUNDS_1(num_threads()) +__global__ void vectorized_elementwise_kernel(int N, func_t f, array_t data) { + using traits = function_traits; + constexpr auto io_size = calc_io_size(); + int remaining = N - io_block_work_size() * blockIdx.x; + + if (remaining < io_block_work_size()) { // if this block handles the reminder, + // just do a naive unrolled loop + auto input_calc = TrivialOffsetCalculator(); + auto output_calc = TrivialOffsetCalculator<1>(); + auto loader = memory::LoadWithoutCast(); + auto storer = memory::StoreWithoutCast(); + auto policy = memory::policies::unroll< + array_t, + decltype(input_calc), + decltype(output_calc), + memory::LoadWithoutCast, + memory::StoreWithoutCast, + elems_per_thread()>( + data, remaining, input_calc, output_calc, loader, storer); + elementwise_kernel_helper(f, policy); + } else { // if this block has a full `block_work_size` data to handle, use + // vectorized memory access + constexpr auto optimal_vec_size = calc_optimal_vec_size(); + elementwise_kernel_helper( + f, memory::policies::vectorized()>(data)); + } +} +#endif // USE_ROCM + +template < + typename func_t, + typename array_t, + int elems_per_thread, + typename inp_calc_t, + typename out_calc_t, + typename loader_t, + typename storer_t> +C10_LAUNCH_BOUNDS_1(num_threads()) +__global__ void unrolled_elementwise_kernel( + int N, + func_t f, + array_t data, + inp_calc_t ic, + out_calc_t oc, + loader_t l, + storer_t s) { + int remaining = N - elems_per_thread * num_threads() * blockIdx.x; + auto policy = memory::policies:: + unroll( + data, remaining, ic, oc, l, s); + elementwise_kernel_helper(f, policy); +} + +// this function assume trivial 1d and no dynamic casting +template +static inline void launch_vectorized_kernel( + int64_t N, + const func_t& f, + array_t data) { + TORCH_INTERNAL_ASSERT(N > 0 && N <= std::numeric_limits::max()); + using traits = function_traits; + constexpr auto io_size = calc_io_size(); + int64_t grid = (N + io_block_work_size() - 1) / io_block_work_size(); + auto stream = at::cuda::getCurrentCUDAStream(); +#ifdef USE_ROCM + int vec_size = memory::can_vectorize_up_to(data); +#else + using cpp_type = typename function_traits::result_type; + const uint16_t max_vec_size = memory::can_vectorize_up_to(data); + uint16_t vec_size = 16 / static_cast(sizeof(cpp_type)); + vec_size = std::min(vec_size, max_vec_size); + // Here we purposely omit vec8 for 1-byte data because of a bug in NVCC + // that causes some numerical mismatches with uint8 on sm80 and sm90. + // TODO: Revisit this after CUDA 12.8 update. + cudaDeviceProp* p = at::cuda::getDeviceProperties(stream.device().index()); + const int computeCapability = p->major * 10 + p->minor; + if (computeCapability != 90 && computeCapability != 100) { + vec_size = std::min(vec_size, 4); + } + if constexpr (sizeof(cpp_type) < 2) { + vec_size = std::min(vec_size, 4); + } +#endif + switch (vec_size) { +#ifdef USE_ROCM + case 16: + vectorized_elementwise_kernel<16, func_t, array_t> + <<>>(N, f, data); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + break; +#endif + case 8: + vectorized_elementwise_kernel<8, func_t, array_t> + <<>>(N, f, data); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + break; + case 4: + vectorized_elementwise_kernel<4, func_t, array_t> + <<>>(N, f, data); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + break; + case 2: + vectorized_elementwise_kernel<2, func_t, array_t> + <<>>(N, f, data); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + break; + case 1: { + auto input_calc = TrivialOffsetCalculator(); + auto output_calc = TrivialOffsetCalculator<1>(); + auto loader = memory::LoadWithoutCast(); + auto storer = memory::StoreWithoutCast(); + unrolled_elementwise_kernel()> + <<>>( + N, f, data, input_calc, output_calc, loader, storer); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + break; + } + default: + TORCH_INTERNAL_ASSERT(false, "Unexpected vectorization size"); + } +} + +template < + typename func_t, + typename array_t, + typename inp_calc_t, + typename out_calc_t, + typename loader_t, + typename storer_t> +static inline void launch_unrolled_kernel( + int64_t N, + const func_t& f, + array_t data, + inp_calc_t ic, + out_calc_t oc, + loader_t l, + storer_t s) { + TORCH_INTERNAL_ASSERT(N > 0 && N <= std::numeric_limits::max()); + + int64_t grid = (N + elementwise_block_work_size() - 1) / elementwise_block_work_size(); + auto stream = at::cuda::getCurrentCUDAStream(); + unrolled_elementwise_kernel + <<>>(N, f, data, ic, oc, l, s); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +C10_LAUNCH_BOUNDS_2(nt, 4) +__global__ void elementwise_kernel(int N, func_t f) { + int tid = threadIdx.x; + int nv = nt * vt; + int idx = nv * blockIdx.x + tid; +#pragma unroll + for (int i = 0; i < vt; i++) { + if (idx < N) { + f(idx); + idx += nt; + } + } +} + +template +static void launch_legacy_kernel(int64_t N, const func_t& f) { + TORCH_INTERNAL_ASSERT(N >= 0 && N <= std::numeric_limits::max()); + if (N == 0) { + return; + } + dim3 block(nt); + dim3 grid((N + block.x * vt - 1) / (block.x * vt)); + auto stream = at::cuda::getCurrentCUDAStream(); + elementwise_kernel<<>>(N, f); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +C10_HOST_DEVICE typename traits::result_type invoke_impl( + const func_t& f, + char* const C10_RESTRICT data[], + const index_t strides[], + int i, + std::index_sequence) { + (void)strides; + (void)i; + return f(c10::load::type>( + data[INDEX] + i * strides[INDEX])...); +} + +template < + typename func_t, + typename index_t, + typename traits = function_traits> +C10_HOST_DEVICE typename traits::result_type invoke( + const func_t& f, + char* const C10_RESTRICT data[], + const index_t strides[], + int i) { + using Indices = std::make_index_sequence; + return invoke_impl(f, data, strides, i, Indices{}); +} + +template +C10_HOST_DEVICE typename traits::result_type invoke_impl( + const func_t& f, + char* const C10_RESTRICT data[], + const index_t strides[], + const ScalarType dtypes[], + int i, + std::index_sequence) { + (void)strides; + (void)i; + return f(c10::fetch_and_cast::type>( + dtypes[I], data[I] + i * strides[I])...); +} + +template < + typename func_t, + typename index_t, + typename traits = function_traits> +C10_HOST_DEVICE typename traits::result_type invoke( + const func_t& f, + char* const C10_RESTRICT data[], + const index_t strides[], + const ScalarType dtypes[], + int i) { + using Indices = std::make_index_sequence; + return invoke_impl(f, data, strides, dtypes, i, Indices{}); +} + +template +void gpu_kernel_impl_nocast(TensorIteratorBase& iter, const func_t& f) { + using traits = function_traits; + using arg0_t = typename traits::result_type; + constexpr int ntensors = traits::arity + 1; + + TORCH_INTERNAL_ASSERT(iter.can_use_32bit_indexing()); + TORCH_INTERNAL_ASSERT(iter.ninputs() == traits::arity); + TORCH_INTERNAL_ASSERT(iter.noutputs() == 1); + TORCH_INTERNAL_ASSERT(!needs_dynamic_casting::check(iter)); + + std::array data; + for (int i = 0; i < ntensors; i++) { + data[i] = (char*)iter.data_ptr(i); + } + + int64_t numel = iter.numel(); + + bool contiguous = iter.is_contiguous(); + + if (contiguous) { + return launch_vectorized_kernel(numel, f, data); + } + auto offset_calc = ::make_offset_calculator(iter); + constexpr int unroll_factor = sizeof(arg0_t) >= 4 ? 2 : 4; + launch_legacy_kernel<128, unroll_factor>(numel, [=] GPU_LAMBDA(int idx) { + auto offsets = offset_calc.get(idx); + arg0_t* out = (arg0_t*)(data[0] + offsets[0]); + *out = invoke(f, &data[1], &offsets[1], 1); + }); +} + +template +void gpu_kernel_impl(TensorIteratorBase& iter, const func_t& f) { + if (!needs_dynamic_casting::check(iter)) { + return gpu_kernel_impl_nocast(iter, f); + } + using traits = function_traits; + using arg0_t = typename traits::result_type; + constexpr int ntensors = traits::arity + 1; + + TORCH_INTERNAL_ASSERT(iter.can_use_32bit_indexing()); + TORCH_INTERNAL_ASSERT(iter.ninputs() == traits::arity); + TORCH_INTERNAL_ASSERT(iter.noutputs() == 1); + + std::array data; + for (int i = 0; i < ntensors; i++) { + data[i] = (char*)iter.data_ptr(i); + } + + int64_t numel = iter.numel(); + + bool contiguous = iter.is_contiguous(); + + if (contiguous) { +#ifdef USE_ROCM + std::array dtypes; + auto inner_strides = iter.get_inner_strides(); + std::array strides; + for (int i = 0; i < ntensors; i++) { + dtypes[i] = iter.dtype(i); + strides[i] = inner_strides[i]; + } + launch_legacy_kernel<512, 1>(numel, [=]GPU_LAMBDA(int idx) { + void* out = data[0] + strides[0] * idx; + arg0_t result = invoke(f, &data[1], &strides[1], &dtypes[1], idx); + c10::cast_and_store(dtypes[0], out, result); + }); +#else + auto loader = memory::LoadWithCast(iter); + auto storer = memory::StoreWithCast<1>(iter); + auto input_offset_calculator = TrivialOffsetCalculator(); + auto output_offset_calculator = TrivialOffsetCalculator<1>(); + launch_unrolled_kernel( + numel, + f, + data, + input_offset_calculator, + output_offset_calculator, + loader, + storer); +#endif + } else { + std::array dtypes; + for (int i = 0; i < ntensors; i++) { + dtypes[i] = iter.dtype(i); + } + auto offset_calc = ::make_offset_calculator(iter); + launch_legacy_kernel<128, 4>(numel, [=] GPU_LAMBDA(int idx) { + auto offsets = offset_calc.get(idx); + void* out = data[0] + offsets[0]; + arg0_t result = invoke(f, &data[1], &offsets[1], &dtypes[1], 1); + c10::cast_and_store(dtypes[0], out, result); + }); + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CompositeRandomAccessor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CompositeRandomAccessor.h new file mode 100644 index 0000000000000000000000000000000000000000..d47a7fa776f1b681b26dc5ec8b4548604d359946 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CompositeRandomAccessor.h @@ -0,0 +1,35 @@ +#pragma once + +#include +#include + +namespace at { namespace native { + +struct TupleInfoCPU { + template + using tuple = thrust::tuple; + + template + static constexpr auto tie(Types&... args) noexcept { + return thrust::tie(args...); + } +}; + +template +using CompositeRandomAccessorCPU = + CompositeRandomAccessor; + +template +void swap( + references_holder rh1, + references_holder rh2 +) { + return thrust::swap(rh1.data(), rh2.data()); +} + +template +auto get(references_holder rh) -> decltype(thrust::get(rh.data())) { + return thrust::get(rh.data()); +} + +}} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Copy.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Copy.h new file mode 100644 index 0000000000000000000000000000000000000000..f4b90b7b513235d3c25d966ac049d9a63a8fa1da --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Copy.h @@ -0,0 +1,11 @@ +#pragma once + +namespace at { +struct TensorIteratorBase; + +namespace native { + +void direct_copy_kernel_cuda(TensorIteratorBase& iter); + +} +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CuFFTPlanCache.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CuFFTPlanCache.h new file mode 100644 index 0000000000000000000000000000000000000000..08d07c4b45a5a5b3c493064a1ed767194de1cfcf --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CuFFTPlanCache.h @@ -0,0 +1,494 @@ +#include +#include +#include +#include +#include +#include +#include + +#include +#include + +#include +#include +#include +#include +#include +#include + +namespace at { namespace native { namespace detail { + +// Enum representing the FFT type +enum class CuFFTTransformType : int8_t { + C2C, // Complex-to-complex + R2C, // Real-to-complex + C2R, // Complex-to-real +}; + +// This struct is used to let us easily compute hashes of the +// parameters. +// It will be the **key** to the plan cache. +struct CuFFTParams +{ + int64_t signal_ndim_; // between 1 and max_rank, i.e., 1 <= signal_ndim <= 3 + // These include additional batch dimension as well. + int64_t sizes_[max_rank + 1]; + int64_t input_strides_[max_rank + 1]; + int64_t output_strides_[max_rank + 1]; + CuFFTTransformType fft_type_; + ScalarType value_type_; + + CuFFTParams() = default; + + CuFFTParams(IntArrayRef in_strides, IntArrayRef out_strides, + IntArrayRef signal_sizes, CuFFTTransformType fft_type, ScalarType value_type) { + // Padding bits must be zeroed for hashing + memset(this, 0, sizeof(*this)); + signal_ndim_ = signal_sizes.size() - 1; + fft_type_ = fft_type; + value_type_ = value_type; + + TORCH_INTERNAL_ASSERT(in_strides.size() == signal_sizes.size()); + TORCH_INTERNAL_ASSERT(out_strides.size() == signal_sizes.size()); + TORCH_INTERNAL_ASSERT(1 <= signal_ndim_ && signal_ndim_ <= max_rank); + + std::copy(signal_sizes.cbegin(), signal_sizes.cend(), sizes_); + std::copy(in_strides.cbegin(), in_strides.cend(), input_strides_); + std::copy(out_strides.cbegin(), out_strides.cend(), output_strides_); + } +}; + +static_assert(std::is_trivial_v, ""); + +// Returns true if the transform type has complex input +inline bool cufft_complex_input(CuFFTTransformType type) { + switch (type) { + case CuFFTTransformType::C2C: + case CuFFTTransformType::C2R: + return true; + + case CuFFTTransformType::R2C: + return false; + } + TORCH_INTERNAL_ASSERT(false); +} + +// Returns true if the transform type has complex output +inline bool cufft_complex_output(CuFFTTransformType type) { + switch (type) { + case CuFFTTransformType::C2C: + case CuFFTTransformType::R2C: + return true; + + case CuFFTTransformType::C2R: + return false; + } + TORCH_INTERNAL_ASSERT(false); +} + +// Create transform type enum from bools representing if input and output are complex +inline CuFFTTransformType GetCuFFTTransformType(bool complex_input, bool complex_output) { + if (complex_input && complex_output) { + return CuFFTTransformType::C2C; + } else if (complex_input && !complex_output) { + return CuFFTTransformType::C2R; + } else if (!complex_input && complex_output) { + return CuFFTTransformType::R2C; + } + TORCH_INTERNAL_ASSERT(false, "Real to real FFTs are not supported"); +} + + +class CuFFTHandle { + ::cufftHandle handle_; +public: + + CuFFTHandle() { + CUFFT_CHECK(cufftCreate(&handle_)); + } + + ::cufftHandle & get() { return handle_; } + const ::cufftHandle & get() const { return handle_; } + + ~CuFFTHandle() { +// Not using fftDestroy() for rocFFT to work around double freeing of handles +#if !defined(USE_ROCM) + cufftDestroy(handle_); +#endif + } +}; + +__forceinline__ +static bool is_pow_of_two(int64_t x) { + return (x & (x - 1)) == 0; +} + +using cufft_size_type = long long int; + +using CuFFTDimVector = c10::SmallVector; + +// Struct representing a tensor in CuFFT's data layout for planning transforms +// See NOTE [ cuFFT Embedded Strides ]. +struct CuFFTDataLayout { + CuFFTDimVector embed; + cufft_size_type stride, dist; + bool must_clone, simple; +}; + +// Returns a cufft embedding for a contiguous signal of the given size. +// e.g. if the input is cloned, this will be the resulting data layout +// See NOTE [ cuFFT Embedded Strides ]. +inline CuFFTDataLayout cufft_simple_embed(IntArrayRef sizes, bool onesided) { + CuFFTDataLayout layout; + layout.simple = true; + layout.must_clone = false; + layout.embed.assign(sizes.cbegin() + 1, sizes.cend()); + if (onesided) { + layout.embed.back() = sizes.back() / 2 + 1; + } + layout.stride = 1; + layout.dist = 1; + for (const auto& len : layout.embed) { + layout.dist *= len; + } + return layout; +} + +// Convert strides to a CuFFT embedded representation. +// If strides cannot be embedded, returns a simple layout and sets must_clone flag +// See NOTE [ cuFFT Embedded Strides ]. +inline CuFFTDataLayout as_cufft_embed(IntArrayRef strides, IntArrayRef sizes, bool onesided) { + const auto signal_ndim = strides.size() - 1; + CuFFTDataLayout layout; + auto last_stride = strides[signal_ndim]; + layout.must_clone = (last_stride <= 0); + + const auto last_dim_size = onesided ? + sizes[signal_ndim] / 2 + 1 : sizes[signal_ndim]; + const auto signal_numel = c10::multiply_integers(sizes.slice(1, sizes.size() - 2)) * last_dim_size; + + // Zero stides are not allowed, even if the batch size is one. + // If that happens just set a dummy case + if (sizes[0] == 1) { + layout.dist = signal_numel; + } else if (strides[0] == 0) { + layout.must_clone = true; + } else { + layout.dist = strides[0]; + } + + // Calculate the embedding shape, or set must_clone if the strides cannot be embedded + layout.embed.resize(signal_ndim); + for (auto i = signal_ndim - 1; !layout.must_clone && i > 0; i--) { + auto stride = strides[i]; + if (sizes[i] == 1) { + layout.embed[i] = 1; + } else if (stride > 0 && stride % last_stride == 0) { + layout.embed[i] = stride / last_stride; + last_stride = stride; + } else { + layout.must_clone = true; + } + } + + if (layout.must_clone) { + // If the input needs to be cloned, assume it will be contiguous + layout = cufft_simple_embed(sizes, onesided); + layout.must_clone = true; + } else { + layout.embed[0] = sizes[1]; + layout.stride = strides[signal_ndim]; + // Determine if layout represents a simple embedding (contiguous data) + layout.simple = [&] { + for (const auto i : c10::irange(1, signal_ndim - 1)) { + if (layout.embed[i] != sizes[i + 1]) { + return false; + } + } + + return (layout.stride == 1 && layout.dist == signal_numel && + layout.embed.back() == last_dim_size); + }(); + } + return layout; +} + +// This class contains all the information needed to execute a cuFFT plan: +// 1. the plan +// 2. whether to clone input before executing the plan +// 3. the workspace size needed +// +// This class will be the **value** in the plan cache. +// It **owns** the raw plan via a unique_ptr. +class CuFFTConfig { +public: + + // Only move semantics is enought for this class. Although we already use + // unique_ptr for the plan, still remove copy constructor and assignment op so + // we don't accidentally copy and take perf hit. + CuFFTConfig(const CuFFTConfig&) = delete; + CuFFTConfig& operator=(CuFFTConfig const&) = delete; + + explicit CuFFTConfig(const CuFFTParams& params): + CuFFTConfig( + IntArrayRef(params.input_strides_, params.signal_ndim_ + 1), + IntArrayRef(params.output_strides_, params.signal_ndim_ + 1), + IntArrayRef(params.sizes_, params.signal_ndim_ + 1), + params.fft_type_, + params.value_type_) {} + + // For complex types, strides are in units of 2 * element_size(dtype) + // sizes are for the full signal, including batch size and always two-sided + CuFFTConfig(IntArrayRef in_strides, IntArrayRef out_strides, + IntArrayRef sizes, CuFFTTransformType fft_type, ScalarType dtype): + fft_type_(fft_type), value_type_(dtype) { + + // signal sizes (excluding batch dim) + CuFFTDimVector signal_sizes(sizes.begin() + 1, sizes.end()); + + // input batch size + const int64_t batch = sizes[0]; + const int64_t signal_ndim = sizes.size() - 1; + + // Since cuFFT has limited non-unit stride support and various constraints, we + // use a flag to keep track throughout this function to see if we need to + // input = input.clone(); + +#if defined(USE_ROCM) + // clone input to avoid issues with hipfft clobering the input and failing tests + clone_input = true; +#else + clone_input = false; +#endif + + // For half, base strides on the real part of real-to-complex and + // complex-to-real transforms are not supported. Since our output is always + // contiguous, only need to check real-to-complex case. + if (dtype == ScalarType::Half) { + // cuFFT on half requires compute capability of at least SM_53 + auto dev_prop = at::cuda::getCurrentDeviceProperties(); + TORCH_CHECK(dev_prop->major >= 5 && !(dev_prop->major == 5 && dev_prop->minor < 3), + "cuFFT doesn't support signals of half type with compute " + "capability less than SM_53, but the device containing input half " + "tensor only has SM_", dev_prop->major, dev_prop->minor); + for (const auto i : c10::irange(signal_ndim)) { + TORCH_CHECK(is_pow_of_two(sizes[i + 1]), + "cuFFT only supports dimensions whose sizes are powers of two when" + " computing in half precision, but got a signal size of", + sizes.slice(1)); + } + clone_input |= in_strides.back() != 1; + } + + CuFFTDataLayout in_layout; + if (clone_input) { + in_layout = cufft_simple_embed(sizes, fft_type == CuFFTTransformType::C2R); + } else { + in_layout = as_cufft_embed(in_strides, sizes, fft_type == CuFFTTransformType::C2R); + } + auto out_layout = as_cufft_embed(out_strides, sizes, fft_type == CuFFTTransformType::R2C); + TORCH_INTERNAL_ASSERT(!out_layout.must_clone, "Out strides cannot be represented as CuFFT embedding"); + clone_input |= in_layout.must_clone; + + // Check if we can take advantage of simple data layout. + // + // See NOTE [ cuFFT Embedded Strides ] in native/cuda/SpectralOps.cu. + + const bool simple_layout = in_layout.simple && out_layout.simple; + cudaDataType itype, otype, exec_type; + const auto complex_input = cufft_complex_input(fft_type); + const auto complex_output = cufft_complex_output(fft_type); + if (dtype == ScalarType::Float) { + itype = complex_input ? CUDA_C_32F : CUDA_R_32F; + otype = complex_output ? CUDA_C_32F : CUDA_R_32F; + exec_type = CUDA_C_32F; + } else if (dtype == ScalarType::Double) { + itype = complex_input ? CUDA_C_64F : CUDA_R_64F; + otype = complex_output ? CUDA_C_64F : CUDA_R_64F; + exec_type = CUDA_C_64F; + } else if (dtype == ScalarType::Half) { + itype = complex_input ? CUDA_C_16F : CUDA_R_16F; + otype = complex_output ? CUDA_C_16F : CUDA_R_16F; + exec_type = CUDA_C_16F; + } else { + TORCH_CHECK(false, "cuFFT doesn't support tensor of type: ", dtype); + } + + // disable auto allocation of workspace to use THC allocator + CUFFT_CHECK(cufftSetAutoAllocation(plan(), /* autoAllocate */ 0)); + + size_t ws_size_t; + + // make plan + if (simple_layout) { + // If with unit-stride, we tell cuFFT by setting inembed == onembed == NULL. + // In such case, cuFFT ignores istride, ostride, idist, and odist + // by assuming istride = ostride = 1. + // + // See NOTE [ cuFFT Embedded Strides ] in native/cuda/SpectralOps.cu. + CUFFT_CHECK(cufftXtMakePlanMany(plan(), signal_ndim, signal_sizes.data(), + /* inembed */ nullptr, /* base_istride */ 1, /* idist */ 1, itype, + /* onembed */ nullptr, /* base_ostride */ 1, /* odist */ 1, otype, + batch, &ws_size_t, exec_type)); + } else { + CUFFT_CHECK(cufftXtMakePlanMany(plan(), signal_ndim, signal_sizes.data(), + in_layout.embed.data(), in_layout.stride, in_layout.dist, itype, + out_layout.embed.data(), out_layout.stride, out_layout.dist, otype, + batch, &ws_size_t, exec_type)); + } + ws_size = static_cast(ws_size_t); + } + + const cufftHandle &plan() const { return plan_ptr.get(); } + + CuFFTTransformType transform_type() const { return fft_type_; } + ScalarType data_type() const { return value_type_; } + bool should_clone_input() const { return clone_input; } + int64_t workspace_size() const { return ws_size; } + +private: + CuFFTHandle plan_ptr; + bool clone_input; + int64_t ws_size; + CuFFTTransformType fft_type_; + ScalarType value_type_; +}; + +#if defined(USE_ROCM) + // Note that the max plan number for CUDA version < 10 has to be 1023 + // due to a bug that fails on the 1024th plan + constexpr int64_t CUFFT_MAX_PLAN_NUM = 1023; + constexpr int64_t CUFFT_DEFAULT_CACHE_SIZE = CUFFT_MAX_PLAN_NUM; +#else + constexpr int64_t CUFFT_MAX_PLAN_NUM = std::numeric_limits::max(); + // The default max cache size chosen for CUDA version > 10 is arbitrary. + // This number puts a limit on how big of a plan cache should we maintain by + // default. Users can always configure it via cufft_set_plan_cache_max_size. + constexpr int64_t CUFFT_DEFAULT_CACHE_SIZE = 4096; +#endif +static_assert(0 <= CUFFT_MAX_PLAN_NUM && CUFFT_MAX_PLAN_NUM <= std::numeric_limits::max(), + "CUFFT_MAX_PLAN_NUM not in size_t range"); +static_assert(CUFFT_DEFAULT_CACHE_SIZE >= 0 && CUFFT_DEFAULT_CACHE_SIZE <= CUFFT_MAX_PLAN_NUM, + "CUFFT_DEFAULT_CACHE_SIZE not in [0, CUFFT_MAX_PLAN_NUM] range"); + +// This cache assumes that the mapping from key to value never changes. +// This is **NOT** thread-safe. Please use a mutex when using it **AND** the +// value returned from try_emplace_value. +// The contract of using this cache is that try_emplace_value should only be +// used when the max_size is positive. +class CuFFTParamsLRUCache { +public: + using kv_t = typename std::pair; + using map_t = typename std::unordered_map, + typename std::list::iterator, + ParamsHash, + ParamsEqual>; + using map_kkv_iter_t = typename map_t::iterator; + + + CuFFTParamsLRUCache() : CuFFTParamsLRUCache(CUFFT_DEFAULT_CACHE_SIZE) {} + + CuFFTParamsLRUCache(int64_t max_size) { + _set_max_size(max_size); + } + + CuFFTParamsLRUCache(CuFFTParamsLRUCache&& other) noexcept : + _usage_list(std::move(other._usage_list)), + _cache_map(std::move(other._cache_map)), + _max_size(other._max_size) {} + + CuFFTParamsLRUCache& operator=(CuFFTParamsLRUCache&& other) noexcept { + _usage_list = std::move(other._usage_list); + _cache_map = std::move(other._cache_map); + _max_size = other._max_size; + return *this; + } + + // If key is in this cache, return the cached config. Otherwise, emplace the + // config in this cache and return it. + // Return const reference because CuFFTConfig shouldn't be tampered with once + // created. + const CuFFTConfig &lookup(CuFFTParams params) { + AT_ASSERT(_max_size > 0); + + map_kkv_iter_t map_it = _cache_map.find(params); + // Hit, put to list front + if (map_it != _cache_map.end()) { + _usage_list.splice(_usage_list.begin(), _usage_list, map_it->second); + return map_it->second->second; + } + + // Miss + // remove if needed + if (_usage_list.size() >= _max_size) { + auto last = _usage_list.end(); + last--; + _cache_map.erase(last->first); + _usage_list.pop_back(); + } + + // construct new plan at list front, then insert into _cache_map + _usage_list.emplace_front(std::piecewise_construct, + std::forward_as_tuple(params), + std::forward_as_tuple(params)); + auto kv_it = _usage_list.begin(); + _cache_map.emplace(std::piecewise_construct, + std::forward_as_tuple(kv_it->first), + std::forward_as_tuple(kv_it)); + return kv_it->second; + } + + void clear() { + _cache_map.clear(); + _usage_list.clear(); + } + + void resize(int64_t new_size) { + _set_max_size(new_size); + auto cur_size = _usage_list.size(); + if (cur_size > _max_size) { + auto delete_it = _usage_list.end(); + for (size_t i = 0; i < cur_size - _max_size; i++) { + delete_it--; + _cache_map.erase(delete_it->first); + } + _usage_list.erase(delete_it, _usage_list.end()); + } + } + + size_t size() const { return _cache_map.size(); } + + size_t max_size() const noexcept { return _max_size; } + + std::mutex mutex; + +private: + // Only sets size and does value check. Does not resize the data structures. + void _set_max_size(int64_t new_size) { + // We check that 0 <= new_size <= CUFFT_MAX_PLAN_NUM here. Since + // CUFFT_MAX_PLAN_NUM is of type size_t, we need to do non-negativity check + // first. + TORCH_CHECK(new_size >= 0, + "cuFFT plan cache size must be non-negative, but got ", new_size); + TORCH_CHECK(new_size <= CUFFT_MAX_PLAN_NUM, + "cuFFT plan cache size can not be larger than ", CUFFT_MAX_PLAN_NUM, ", but got ", new_size); + _max_size = static_cast(new_size); + } + + std::list _usage_list; + map_t _cache_map; + size_t _max_size; +}; + +// Since ATen is separated into CPU build and CUDA build, we need a way to call +// these functions only when CUDA is loaded. We use CUDA hooks for this purpose +// (at cuda/detail/CUDAHooks.cpp), and call the hooked functions from the actual +// native function counterparts (at native/SpectralOps.cpp), i.e., +// _cufft_get_plan_cache_max_size, _cufft_set_plan_cache_max_size +// _cufft_get_plan_cache_size, and _cufft_clear_plan_cache. +int64_t cufft_get_plan_cache_max_size_impl(DeviceIndex device_index); +void cufft_set_plan_cache_max_size_impl(DeviceIndex device_index, int64_t max_size); +int64_t cufft_get_plan_cache_size_impl(DeviceIndex device_index); +void cufft_clear_plan_cache_impl(DeviceIndex device_index); + +}}} // namespace at::native::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CuFFTUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CuFFTUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..f20baa9568661037954ccd6e8c425018969175a4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/CuFFTUtils.h @@ -0,0 +1,73 @@ +#pragma once + +#include + +#include +#include +#include +#include +#include + +namespace at { namespace native { + +// This means that max dim is 3 + 2 = 5 with batch dimension and possible +// complex dimension +constexpr int max_rank = 3; + +static inline std::string _cudaGetErrorEnum(cufftResult error) +{ + switch (error) + { + case CUFFT_SUCCESS: + return "CUFFT_SUCCESS"; + case CUFFT_INVALID_PLAN: + return "CUFFT_INVALID_PLAN"; + case CUFFT_ALLOC_FAILED: + return "CUFFT_ALLOC_FAILED"; + case CUFFT_INVALID_TYPE: + return "CUFFT_INVALID_TYPE"; + case CUFFT_INVALID_VALUE: + return "CUFFT_INVALID_VALUE"; + case CUFFT_INTERNAL_ERROR: + return "CUFFT_INTERNAL_ERROR"; + case CUFFT_EXEC_FAILED: + return "CUFFT_EXEC_FAILED"; + case CUFFT_SETUP_FAILED: + return "CUFFT_SETUP_FAILED"; + case CUFFT_INVALID_SIZE: + return "CUFFT_INVALID_SIZE"; + case CUFFT_UNALIGNED_DATA: + return "CUFFT_UNALIGNED_DATA"; + case CUFFT_INCOMPLETE_PARAMETER_LIST: + return "CUFFT_INCOMPLETE_PARAMETER_LIST"; + case CUFFT_INVALID_DEVICE: + return "CUFFT_INVALID_DEVICE"; + case CUFFT_PARSE_ERROR: + return "CUFFT_PARSE_ERROR"; + case CUFFT_NO_WORKSPACE: + return "CUFFT_NO_WORKSPACE"; + case CUFFT_NOT_IMPLEMENTED: + return "CUFFT_NOT_IMPLEMENTED"; +#if !defined(USE_ROCM) + case CUFFT_LICENSE_ERROR: + return "CUFFT_LICENSE_ERROR"; +#endif + case CUFFT_NOT_SUPPORTED: + return "CUFFT_NOT_SUPPORTED"; + default: + std::ostringstream ss; + ss << "unknown error " << error; + return ss.str(); + } +} + +static inline void CUFFT_CHECK(cufftResult error) +{ + if (error != CUFFT_SUCCESS) { + std::ostringstream ss; + ss << "cuFFT error: " << _cudaGetErrorEnum(error); + TORCH_CHECK(false, ss.str()); + } +} + +}} // at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/DeviceSqrt.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/DeviceSqrt.cuh new file mode 100644 index 0000000000000000000000000000000000000000..15db32850d989a7b5e781500e525356834b44e13 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/DeviceSqrt.cuh @@ -0,0 +1,25 @@ +#pragma once + +namespace at::native { +#if defined(USE_ROCM) +// take these out when ROCm implements std:: math functions +#include +template +static __forceinline__ __device__ scalar_t device_sqrt(scalar_t val); + +template <> +__forceinline__ __device__ float device_sqrt(float val) { + return ::sqrtf(val); +} + +template <> +__forceinline__ __device__ double device_sqrt(double val) { + return ::sqrt(val); +} +#else +template +__forceinline__ __device__ double device_sqrt(scalar_t val) { + return std::sqrt(val); +} +#endif +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/DistributionTemplates.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/DistributionTemplates.h new file mode 100644 index 0000000000000000000000000000000000000000..1fc9195ac53769ff06d85fbd990c542bd34593da --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/DistributionTemplates.h @@ -0,0 +1,697 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at { +namespace native { +namespace { + +// launch bounds used for kernels utilizing TensorIterator +const uint32_t block_size_bound = 256; +const uint32_t grid_size_bound = 4; +// At the time of writing, there is no curand_* call that increments the offset by more than 4. +// See: https://docs.nvidia.com/cuda/archive/11.8.0/curand/group__DEVICE.html +const uint32_t max_generator_offsets_per_curand_call = 4; + +// utility function that calculates proper philox_offset +// for distributions utilizing TensorIterator. For distributions using +// TensorIterator, we are using a grid-stride loop with each +// thread yielding one element per thread. For the edge of the grid-stride +// loop, if the tensor size is large, the unroll loop will kick in and the float4 +// from curand4 will start getting utilized (for common tensor sizes, we end up +// using rand.x from each thread). The philox_offset calculation was changed to +// (number of elements per thread * maximum generator increment per "curand_*" call), which makes +// sure that philox offset increment is not less than the number of randoms used +// in each thread. +std::tuple calc_execution_policy(const int64_t total_elements, const uint32_t unroll_factor) { + const uint64_t numel = static_cast(total_elements); + const uint32_t block_size = block_size_bound; + dim3 dim_block(block_size); + dim3 grid((numel + block_size - 1) / block_size); + uint32_t blocks_per_sm = at::cuda::getCurrentDeviceProperties()->maxThreadsPerMultiProcessor / block_size; + grid.x = std::min( + static_cast(at::cuda::getCurrentDeviceProperties()->multiProcessorCount) * blocks_per_sm, + grid.x); + //number of times random will be generated per thread, to offset philox counter in thc random state + uint64_t counter_offset = ((numel - 1) / (block_size * grid.x * unroll_factor) + 1) * max_generator_offsets_per_curand_call; + return std::make_tuple(counter_offset, grid, dim_block); +} + +// grid stride loop kernel for distributions +template +C10_LAUNCH_BOUNDS_2(block_size_bound, grid_size_bound) +__global__ void distribution_elementwise_grid_stride_kernel(int64_t numel, + PhiloxCudaState philox_args, + const dist_t dist_func, + const transform_t transform_func) { + auto [seed, offset] = at::cuda::philox::unpack(philox_args); + int64_t idx = ((int64_t) blockIdx.x) * blockDim.x + threadIdx.x; + curandStatePhilox4_32_10_t state; + curand_init(seed, idx, offset, &state); + + int64_t rounded_size = ((numel - 1)/(blockDim.x * gridDim.x * unroll_factor)+1) * + blockDim.x * gridDim.x * unroll_factor; + for(int64_t linear_index = idx; linear_index < rounded_size; linear_index += blockDim.x * gridDim.x * unroll_factor) { + auto rand = dist_func(&state); + #pragma unroll + for (int ii = 0; ii < unroll_factor; ii++) { + int64_t li = linear_index + blockDim.x * gridDim.x * ii; + if (li < numel) { + transform_func(li, static_cast((&rand.x)[ii])); + } + } + __syncthreads(); + } +} + +/** + * distribution_nullary_kernel is analogous to gpu_kernel in + * ATen/native/cuda/Loops.cuh. Like gpu_kernel, it uses + * TensorIterator to launch a kernel. However, the differences are + * - it launches a grid-stride loop based kernel. The kernel is not + * generic like elementwise_kernel in Loops.cuh and is specialized + * for the distribution kernels here. + * - For big size tensors, we can launch multiple kernels recursively + * (i.e. if (!iter.can_use_32bit_indexing())) and hence, the philox + * offset calculation is done in this function. + * + * FIXME: Can we specialize elementwise_kernel and launch_kernel in Loops.cuh + * to have grid-stride loop kernel and then use that to launch our distribution + * kernels? Note that we need a grid-stride loop kernel because, we found by testing + * that it achieves peak effective bandwidth. + */ +template +void distribution_nullary_kernel(at::TensorIteratorBase& iter, + RNG gen, + const dist_t& dist_func, + const transform_t transform_func) { + const int unroll_factor = sizeof(dist_func_return_t) / sizeof(accscalar_t); + TORCH_CHECK(unroll_factor >= 1, "unroll_factor must be >= 1."); + int64_t numel = iter.numel(); + if (numel == 0) { + return; + } + + auto [counter_offset, grid, block] = calc_execution_policy(numel, unroll_factor); + PhiloxCudaState rng_engine_inputs; + { + // See Note [Acquire lock when using random generators] + std::lock_guard lock(gen->mutex_); + rng_engine_inputs = gen->philox_cuda_state(counter_offset); + } + + if (!iter.can_use_32bit_indexing()) { + for (auto& sub_iter : iter.with_32bit_indexing()) { + distribution_nullary_kernel(sub_iter, + gen, dist_func, transform_func); + } + return; + } + + char* out_data = (char*)iter.data_ptr(0); + + auto stream = at::cuda::getCurrentCUDAStream(); + if (iter.is_trivial_1d()) { + auto strides = iter.get_inner_strides(); + int stride0 = strides[0]; + distribution_elementwise_grid_stride_kernel<<>>( + numel, + rng_engine_inputs, + dist_func, + [=]__device__(int idx, accscalar_t rand) { + scalar_t* out = (scalar_t*)&out_data[stride0 * idx]; + *out = transform_func(rand); + } + ); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } else { + auto offset_calc = make_offset_calculator<1>(iter); + distribution_elementwise_grid_stride_kernel<<>>( + numel, + rng_engine_inputs, + dist_func, + [=]__device__(int idx, accscalar_t rand) { + auto offsets = offset_calc.get(idx); + scalar_t* out = (scalar_t*)&out_data[offsets[0]]; + *out = transform_func(rand); + } + ); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } +} + +// Binary kernel +template +__global__ void distribution_binary_elementwise_kernel( + int numel, + func_t f, + PhiloxCudaState philox_args, + typename function_traits::result_type *output_data, + const typename function_traits::template arg<1>::type *input_data_1, + const typename function_traits::template arg<2>::type *input_data_2, + inp_offset_calc_t inp_calc, + out_offset_calc_t out_calc) { + auto seeds = at::cuda::philox::unpack(philox_args); + + using input_t_1 = typename function_traits::template arg<1>::type; + using input_t_2 = typename function_traits::template arg<2>::type; + + input_t_1 inputs_1[thread_work_size()]; + input_t_2 inputs_2[thread_work_size()]; + + int base_index = block_work_size() * blockIdx.x; + int remaining = std::min(numel - base_index, block_work_size()); + + curandStatePhilox4_32_10_t state; + curand_init(std::get<0>(seeds), + blockIdx.x * blockDim.x + threadIdx.x, + std::get<1>(seeds), + &state); + + // load data into registers + int thread_idx = threadIdx.x; + #pragma unroll + for (int i = 0; i < thread_work_size(); i++) { + if (thread_idx >= remaining) { + break; + } + int input_idx = thread_idx + base_index; + auto offsets = inp_calc.get(input_idx); + inputs_1[i] = input_data_1[offsets[0]]; + inputs_2[i] = input_data_2[offsets[1]]; + + thread_idx += num_threads(); + } + + // compute and store + thread_idx = threadIdx.x; + #pragma unroll + for (int i = 0; i < thread_work_size(); i++) { + if (thread_idx >= remaining) { + break; + } + int input_idx = thread_idx + base_index; + auto offsets = out_calc.get(input_idx); + output_data[offsets[0]] = f(state, inputs_1[i], inputs_2[i]); + thread_idx += num_threads(); + } +} + +template +void distribution_binary_kernel(TensorIteratorBase &iter, PhiloxCudaState philox_args, const func_t &f) { + static_assert(std::is_same_v::template arg<0>::type, curandStatePhilox4_32_10_t&>, "the first argument of functor must be curandStatePhilox4_32_10_t"); + using input_t_1 = typename function_traits::template arg<1>::type; + using input_t_2 = typename function_traits::template arg<2>::type; + using output_t = typename function_traits::result_type; + + if (!iter.can_use_32bit_indexing()) { + for (auto& sub_iter : iter.with_32bit_indexing()) { + distribution_binary_kernel(sub_iter, philox_args, f); + } + return; + } + + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(iter.can_use_32bit_indexing()); + + int64_t numel = iter.numel(); + if (numel == 0) { + return; + } + + output_t *output_data = static_cast(iter.data_ptr(0)); + const input_t_1 *input_data_1 = static_cast(iter.data_ptr(1)); + const input_t_2 *input_data_2 = static_cast(iter.data_ptr(2)); + + int64_t grid = (numel + block_work_size() - 1) / block_work_size(); + auto stream = at::cuda::getCurrentCUDAStream(); + + if (iter.is_contiguous()) { + distribution_binary_elementwise_kernel<<>>( + numel, f, philox_args, output_data, input_data_1, input_data_2, + TrivialOffsetCalculator<2>(), TrivialOffsetCalculator<1>()); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } else { + distribution_binary_elementwise_kernel<<>>( + numel, f, philox_args, output_data, input_data_1, input_data_2, + make_input_offset_calculator<2>(iter), make_output_offset_calculator(iter)); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } +} + +} // namespace +}} // namespace at::native + + +namespace at { +namespace native { +namespace templates { +namespace cuda { + +// ==================================================== Random ======================================================== + +template +void random_from_to_kernel(TensorIteratorBase& iter, uint64_t range, int64_t base, RNG gen) { +#ifdef FBCODE_CAFFE2 + AT_DISPATCH_V2(iter.dtype(), "random_from_to_kernel_cuda", AT_WRAP([&] { + if (( + std::is_same_v || + std::is_same_v || + std::is_same_v || + std::is_same_v) && range >= 1ULL << 32) + { + // define lambda to mod with range and add base + auto random_func = [range, base] __device__ (uint64_t rand) { + return transformation::uniform_int_from_to(rand, range, base); + }; + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> ulonglong2 { + ulonglong2 ret; + uint4 rand_val = curand4(state); + ret.x = (static_cast(rand_val.x) << 32) | rand_val.y; + ret.y = (static_cast(rand_val.z) << 32) | rand_val.w; + return ret; + }, + random_func); + } else { + auto random_func = [range, base] __device__ (uint32_t rand) { + return transformation::uniform_int_from_to(rand, range, base); + }; + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> uint4 { + return curand4(state); + }, + random_func); + } + }), AT_EXPAND(AT_ALL_TYPES), kBool, kHalf, kBFloat16, AT_EXPAND(AT_BAREBONES_UNSIGNED_TYPES)); +#else + AT_DISPATCH_V2(iter.dtype(), "random_from_to_kernel_cuda", AT_WRAP([&] { + if (range >= 1ULL << 28) // allow approx 5% skew in uniform int generation using % + { + // define lambda to mod with range and add base + auto random_func = [range, base] __device__ (uint64_t rand) { + return transformation::uniform_int_from_to(rand, range, base); + }; + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> ulonglong2 { + ulonglong2 ret; + uint4 rand_val = curand4(state); + ret.x = (static_cast(rand_val.x) << 32) | rand_val.y; + ret.y = (static_cast(rand_val.z) << 32) | rand_val.w; + return ret; + }, + random_func); + } else { + auto random_func = [range, base] __device__ (uint32_t rand) { + return transformation::uniform_int_from_to(rand, range, base); + }; + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> uint4 { + return curand4(state); + }, + random_func); + } + }), AT_EXPAND(AT_ALL_TYPES), kBool, kHalf, kBFloat16, AT_EXPAND(AT_BAREBONES_UNSIGNED_TYPES)); +#endif +} + +// This is the special kernel to handle single specific case: +// from(inclusive) = std::numeric_limits::lowest() +// to(exclusive) = None (= std::numeric_limits::max() + 1) +template +void random_full_64_bits_range_kernel(TensorIteratorBase& iter, RNG gen) { + AT_DISPATCH_ALL_TYPES_AND(at::ScalarType::BFloat16, iter.dtype(), "random_full_64_bits_range_kernel_cuda", [&] { + if (std::is_same_v || + std::is_same_v || + std::is_same_v || + std::is_same_v) { + auto random_func = [] __device__ (uint64_t rand) { + return transformation::uniform_int_full_range(rand); + }; + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> ulonglong2 { + ulonglong2 ret; + uint4 rand_val = curand4(state); + ret.x = (static_cast(rand_val.x) << 32) | rand_val.y; + ret.y = (static_cast(rand_val.z) << 32) | rand_val.w; + return ret; + }, + random_func); + } else { + TORCH_CHECK(false, "random_full_64_bits_range_kernel_cuda handles only int64, double, float and bfloat16"); + } + }); +} + +template +struct RandomFromToKernel { + void operator()(TensorIteratorBase& iter, uint64_t range, int64_t base, std::optional gen) { + random_from_to_kernel(iter, range, base, check_generator(gen)); + } + void operator()(TensorIteratorBase& iter, std::optional gen) { + random_full_64_bits_range_kernel(iter, check_generator(gen)); + } +}; + +template +void random_kernel(TensorIteratorBase& iter, RNG gen) { + AT_DISPATCH_ALL_TYPES_AND3(at::ScalarType::Half, at::ScalarType::BFloat16, at::ScalarType::Bool, iter.dtype(), "random_kernel_cuda", [&] { + if (std::is_same_v || std::is_same_v) { + auto random_func = [] __device__ (uint64_t rand) { + return transformation::uniform_int(rand); + }; + distribution_nullary_kernel(iter, gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> ulonglong2 { + ulonglong2 ret; + uint4 rand_val = curand4(state); + ret.x = (static_cast(rand_val.x) << 32) | rand_val.y; + ret.y = (static_cast(rand_val.z) << 32) | rand_val.w; + return ret; + }, + random_func); + } else { + auto random_func = [] __device__ (uint32_t rand) { + return transformation::uniform_int(rand); + }; + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> uint4 { + return curand4(state); + }, + random_func); + } + }); +} + +template +struct RandomKernel { + void operator()(TensorIteratorBase& iter, RNG gen) { + random_kernel(iter, gen); + } +}; + +// ==================================================================================================================== + +template +void uniform_and_transform(TensorIteratorBase& iter, RNG gen, transform_t transform) { + if (std::is_same_v) { + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> double2 { return curand_uniform2_double(state); }, + transform); + } else { + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> float4 { return curand_uniform4(state); }, + transform); + } +} + +template +void normal_and_transform(TensorIteratorBase& iter, RNG gen, transform_t transform) { + if (std::is_same_v) { + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> double2 { return curand_normal2_double(state); }, + transform); + } else { + distribution_nullary_kernel(iter, + gen, + [] __device__ (curandStatePhilox4_32_10_t* state) -> float4 { return curand_normal4(state); }, + transform); + } +} + +// ==================================================== Normal ======================================================== + +template +void normal_kernel(const TensorBase &self, double mean_, double std_, RNG gen) { + auto iter = TensorIterator::borrowing_nullary_op(self); + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "normal_kernel_cuda", [&] { + using accscalar_t = at::acc_type; + auto mean = static_cast(mean_); + auto std = static_cast(std_); + // define lambda to multiply std and add mean + auto normal_func = [mean, std] __device__ (accscalar_t rand) { + return static_cast(transformation::normal(rand, mean, std)); + }; + normal_and_transform(iter, gen, normal_func); + }); +} + +template +struct NormalKernel { + void operator()(const TensorBase &self, double mean, double std, std::optional gen) { + normal_kernel(self, mean, std, check_generator(gen)); + } +}; + +// ==================================================== Uniform ======================================================== + +template +void uniform_kernel(TensorIteratorBase& iter, double from_, double to_, RNG gen) { + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "uniform_kernel_cuda", [&] { + auto from = static_cast(from_); + auto to = static_cast(to_); + using opmath_t = at::opmath_type; + auto range = static_cast(to-from); + // define lambda to reverse bounds, multiply 'range' and add 'from_' + auto uniform_func = [range, from, to] __device__ (opmath_t rand) { + // Compute output value before reversing the bounds + // BEFORE TOUCHING THIS CODE READ: https://github.com/pytorch/pytorch/issues/96947 + auto value = static_cast(rand * range + from); + // reverse the bounds of curand4 from (0, 1] to [0, 1) + // Note that this method is from legacy THCTensorRandom and is likely to give + // you more 0-s, since, the probability of gettings 1-s is higher than 0-s and + // by reversing the bounds, we are flipping the probabilities of 1-s and 0-s. + // BEFORE TOUCHING THIS CODE READ: https://github.com/pytorch/pytorch/issues/16706 + auto reverse_bound_value = value == to ? from : value; + return reverse_bound_value; + }; + uniform_and_transform(iter, gen, uniform_func); + }); +} + +template +struct UniformKernel { + void operator()(TensorIteratorBase& iter, double from, double to, std::optional gen) { + uniform_kernel(iter, from, to, check_generator(gen)); + } +}; + +// ================================================== LogNormal ======================================================= + +template +void log_normal_kernel(TensorIteratorBase& iter, double mean_, double std_, RNG gen) { + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "log_normal_cuda", [&] { + using accscalar_t = at::acc_type; + auto mean = static_cast(mean_); + auto std = static_cast(std_); + // define lambda for log_normal transformation + auto log_normal_func = [mean, std] __device__ (accscalar_t rand) { + return static_cast(transformation::log_normal(transformation::normal(rand, mean, std))); + }; + normal_and_transform(iter, gen, log_normal_func); + }); +} + +template +struct LogNormalKernel { + void operator()(TensorIteratorBase& iter, double mean, double std, std::optional gen) { + log_normal_kernel(iter, mean, std, check_generator(gen)); + } +}; + +// =================================================== Geometric ====================================================== + +template +void geometric_kernel(TensorIteratorBase& iter, double p, RNG gen) { + AT_DISPATCH_ALL_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "geometric_cuda", [&] { + using accscalar_t = at::DiscreteDistributionType::type; + // define lambda for geometric transformation + auto geometric_func = [p] __device__ (accscalar_t rand) { + return static_cast(transformation::geometric(rand, p)); + }; + uniform_and_transform(iter, gen, geometric_func); + }); +} + +template +struct GeometricKernel { + void operator()(TensorIteratorBase& iter, double p, std::optional gen) { + geometric_kernel(iter, p, check_generator(gen)); + } +}; + +// ================================================== Exponential ===================================================== + +template +void exponential_kernel(TensorIteratorBase& iter, double lambda_, RNG gen) { + TORCH_CHECK(isFloatingType(iter.dtype()), "Exponential distribution is a continuous probability distribution. dtype must be a floating point but you specified ", iter.dtype()); + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "exponential_cuda", [&] { + using accscalar_t = at::acc_type; + auto lambda = static_cast(lambda_); + // define lambda for exponential transformation + auto exponential_func = [lambda] __device__ (accscalar_t rand) { + return static_cast(transformation::exponential(rand, lambda)); + }; + uniform_and_transform(iter, gen, exponential_func); + }); +} + +template +struct ExponentialKernel { + void operator()(TensorIteratorBase& iter, double lambda, std::optional gen) { + exponential_kernel(iter, lambda, check_generator(gen)); + } +}; + +// ==================================================== Cauchy ======================================================== + +template +void cauchy_kernel(TensorIteratorBase& iter, double median_, double sigma_, RNG gen) { + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "cauchy_cuda", [&] { + using accscalar_t = at::acc_type; + auto median = static_cast(median_); + auto sigma = static_cast(sigma_); + // define lambda for cauchy transformation + auto cauchy_func = [median, sigma] __device__ (accscalar_t rand) { + return static_cast(transformation::cauchy(rand, median, sigma)); + }; + uniform_and_transform(iter, gen, cauchy_func); + }); +} + +template +struct CauchyKernel { + void operator()(TensorIteratorBase& iter, double median, double sigma, std::optional gen) { + cauchy_kernel(iter, median, sigma, check_generator(gen)); + } +}; + +// ==================================================== Bernoulli ===================================================== + +template +void bernoulli_tensor_cuda_kernel( + const TensorBase &ret, const at::TensorBase &p, + PhiloxCudaState philox_args) { + auto functor = [philox_args] __device__( + int n, scalar_t& v1, scalar_t& v2, scalar_t& v3, scalar_t& v4, + const prob_t& p1, const prob_t& p2, const prob_t& p3, const prob_t& p4) { + auto seeds = at::cuda::philox::unpack(philox_args); + curandStatePhilox4_32_10_t state; + curand_init(std::get<0>(seeds), + blockIdx.x * blockDim.x + threadIdx.x, + std::get<1>(seeds), + &state); + + // See Note [Register spilling in curand call for CUDA < 10] + float4 rand = curand_uniform4(&state); + switch (n) { + case 4: { + CUDA_KERNEL_ASSERT(0 <= p4 && p4 <= 1); + v4 = static_cast(rand.w <= p4); + [[fallthrough]]; + } + case 3: { + CUDA_KERNEL_ASSERT(0 <= p3 && p3 <= 1); + v3 = static_cast(rand.z <= p3); + [[fallthrough]]; + } + case 2: { + CUDA_KERNEL_ASSERT(0 <= p2 && p2 <= 1); + v2 = static_cast(rand.y <= p2); + [[fallthrough]]; + } + case 1: { + CUDA_KERNEL_ASSERT(0 <= p1 && p1 <= 1); + v1 = static_cast(rand.x <= p1); + } + } + }; + // The template argument `4` below indicates that we want to operate on four + // element at each time. See NOTE [ CUDA_tensor_applyN helpers ] for details. + at::cuda::CUDA_tensor_apply2(ret, p, functor); +} + +template +void bernoulli_kernel(const TensorBase &self, const TensorBase &p_, RNG gen) { + PhiloxCudaState rng_engine_inputs; + { + // See Note [Acquire lock when using random generators] + std::lock_guard lock(gen->mutex_); + rng_engine_inputs = gen->philox_cuda_state(10); + } + TORCH_CHECK(at::isFloatingType(p_.scalar_type()), "expected probabilities tensor to have floating type, got ", p_.scalar_type()); + // cast probabilities tensor to double for double `self` tensor, and to `float` for everything else + const auto p_type = self.dtype() == at::kDouble ? at::kDouble : at::kFloat; + auto p_cuda = p_.to(TensorOptions().device(self.device()).dtype(p_type)); + auto p = expand_inplace(self, p_cuda); + AT_DISPATCH_ALL_TYPES_AND3( + at::ScalarType::Half, at::ScalarType::BFloat16, at::ScalarType::Bool, self.scalar_type(), "bernoulli_tensor_cuda_self_", [&] { + if (std::is_same_v) { + return bernoulli_tensor_cuda_kernel(self, *p, rng_engine_inputs); + } else { + return bernoulli_tensor_cuda_kernel(self, *p, rng_engine_inputs); + } + }); +} + +template +void bernoulli_kernel(TensorIteratorBase& iter, double p, RNG gen) { + AT_DISPATCH_ALL_TYPES_AND3( + at::ScalarType::Half, at::ScalarType::BFloat16, at::ScalarType::Bool, iter.dtype(), "bernoulli_scalar_cuda_", [&] { + using accscalar_t = at::DiscreteDistributionType::type; + // define lambda for bernoulli transformation + auto bernoulli_func = [p] __device__ (accscalar_t rand) { + return static_cast(transformation::bernoulli(rand, p)); + }; + uniform_and_transform(iter, gen, bernoulli_func); + }); +} + +template +struct BernoulliKernel { + void operator()(TensorIteratorBase& iter, double p, std::optional gen) { + bernoulli_kernel(iter, p, check_generator(gen)); + } + void operator()(const TensorBase &self, const TensorBase &p_, std::optional gen) { + bernoulli_kernel(self, p_, check_generator(gen)); + } +}; + +}}}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Distributions.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Distributions.h new file mode 100644 index 0000000000000000000000000000000000000000..1a34fdfdf31494faab439544578be8aaf950dc32 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Distributions.h @@ -0,0 +1,25 @@ +#pragma once + +namespace at { +struct CUDAGeneratorImpl; +struct TensorIteratorBase; +class TensorBase; + +namespace native { + +void launch_poisson_cuda_kernel( + const TensorBase &ret, const TensorBase &lambda, CUDAGeneratorImpl *gen); + +void launch_gamma_kernel( + const TensorBase &ret, const TensorBase &alpha, CUDAGeneratorImpl *gen); + +void launch_binomial_cuda_kernel( + TensorIteratorBase &iter, CUDAGeneratorImpl *gen); + +void launch_dirichlet_kernel(TensorIteratorBase &iter); + +void launch_standard_gamma_grad_kernel(TensorIteratorBase &iter); + +void launch_dirichlet_grad_kernel(TensorIteratorBase &iter); + +}} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/EmbeddingBackwardKernel.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/EmbeddingBackwardKernel.cuh new file mode 100644 index 0000000000000000000000000000000000000000..54e9be9f7c7c559d2dade6b237cd880fdac48717 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/EmbeddingBackwardKernel.cuh @@ -0,0 +1,21 @@ +#pragma once +#include +#include +#include +#include + +namespace at::native { + +Tensor embedding_backward_cuda_kernel( + const Tensor &grad, + const Tensor &orig_indices, + const Tensor &sorted_indices, + const Tensor &count, + int64_t num_weights, + int padding_idx = -1, + bool mode_mean = false, + const Tensor &offset2bag = Tensor(), + const Tensor &bag_size = Tensor(), + const Tensor &per_sample_weights = Tensor()); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ForeachFunctors.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ForeachFunctors.cuh new file mode 100644 index 0000000000000000000000000000000000000000..645b095c5a6e5074069a636574b925c25c9c28f5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ForeachFunctors.cuh @@ -0,0 +1,738 @@ +#pragma once +#include +#include +#include +#include + +namespace at::native { + +namespace { + +// TODO(crcrpar): Handle version bump in codegen. +// rel: +// https://github.com/pytorch/pytorch/blob/9cf84347767c8abb8feba18a9a1baba321eeb8b9/tools/autograd/gen_inplace_or_view_type.py#L481-L482 +inline void increment_version(TensorList tensors) { + for (const auto& t : tensors) { + t.unsafeGetTensorImpl()->bump_version(); + } +} + +// Initializes args and checks if all args are aligned +template +__device__ bool init_args( + T** args, + TensorListMetadata& tl, + const int64_t chunk_idx, + const int64_t chunk_size, + const int64_t tensor_loc) { + bool all_aligned = true; + for (int i = 0; i < depth; i++) { + args[i] = (T*)tl.addresses[i][tensor_loc]; + args[i] += chunk_idx * chunk_size; + + if (!is_aligned(args[i])) { + all_aligned = false; + } + } + return all_aligned; +} + +// Initializes args and checks if all args are aligned +template +__device__ bool init_args( + T** args, + TensorListScalarListMetadata& tl, + const int64_t chunk_idx, + const int64_t chunk_size, + const int64_t tensor_loc) { + bool all_aligned = true; + for (int i = 0; i < depth; i++) { + args[i] = (T*)tl.addresses[i][tensor_loc]; + args[i] += chunk_idx * chunk_size; + + if (!is_aligned(args[i])) { + all_aligned = false; + } + } + return all_aligned; +} + +template +__device__ bool init_args( + T** args, + FusedOptimizerTensorListMetadata& tl, + const int64_t chunk_idx, + const int64_t chunk_size, + const int64_t tensor_loc) { + bool all_aligned = true; + for (int i = 0; i < depth; i++) { + args[i] = (T*)tl.addresses[i][tensor_loc]; + args[i] += chunk_idx * chunk_size; + + if (!is_aligned(args[i])) { + all_aligned = false; + } + } + return all_aligned; +} + +template +__device__ void load_args( + T r_args[][kILP], + T** args, + const int64_t i_start, + const int64_t chunk_size, + const int64_t n) { +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + const auto i = i_start + threadIdx.x + ii * blockDim.x; + for (int r_index = 0; r_index < depth; r_index++) { + r_args[r_index][ii] = 0; + if (i < n && i < chunk_size) { + r_args[r_index][ii] = args[r_index][i]; + } + } + } +} + +template +__device__ void store_args( + T* dst, + T* src, + const int64_t i_start, + const int64_t chunk_size, + const int64_t n) { +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + const int64_t i = i_start + threadIdx.x + ii * blockDim.x; + if (i < n && i < chunk_size) + dst[i] = src[ii]; + } +} + +template +__device__ __forceinline__ void binary_op_scalar( + T r_args[][kILP], + T** args, + opmath_t scalar, + const int64_t n, + const int64_t chunk_size, + const bool all_aligned, + Op op) { + // to make things simple, we put aligned case in a different code path + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { + // load + load_store(r_args[0], args[0], 0, i_start); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast( + op(static_cast(r_args[0][ii]), + static_cast(scalar))); + } + // store + load_store(args[res_arg_index], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + // Regardless if depth is 1 (for inplace) or 2 (for out of place), r_args + // has depth 1 + load_args<1>(r_args, args, i_start, chunk_size, n); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast( + op(static_cast(r_args[0][ii]), + static_cast(scalar))); + } + store_args(args[res_arg_index], r_args[0], i_start, chunk_size, n); + } + } +} + +template +__device__ __forceinline__ void pointwise_op_scalar( + T r_args[][kILP], + T** args, + opmath_t scalar, + const int64_t n, + const int64_t chunk_size, + const bool all_aligned, + Op op) { + // to make things simple, we put aligned case in a different code path + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { + // load + load_store(r_args[0], args[0], 0, i_start); + load_store(r_args[1], args[1], 0, i_start); + load_store(r_args[2], args[2], 0, i_start); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast( + static_cast(r_args[0][ii]) + + scalar * + op(static_cast(r_args[1][ii]), + static_cast(r_args[2][ii]))); + } + // store + load_store(args[res_arg_index], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + // Regardless if depth is 3 (for inplace) or 4 (for out of place), r_args + // has depth 3 + load_args<3>(r_args, args, i_start, chunk_size, n); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast( + static_cast(r_args[0][ii]) + + scalar * + op(static_cast(r_args[1][ii]), + static_cast(r_args[2][ii]))); + } + store_args(args[res_arg_index], r_args[0], i_start, chunk_size, n); + } + } +} + +// +// Binary Functors +// +template +struct BinaryOpScalarFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListMetadata& tl, + Op op, + opmath_t scalar) { + const int tensor_loc = tl.block_to_tensor[blockIdx.x]; + const int chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + binary_op_scalar( + r_args, args, scalar, n, chunk_size, all_aligned, op); + } +}; + +template +struct BinaryOpScalarListFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListScalarListMetadata& tl, + Op op) { + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + opmath_t scalar = tl.scalar_vals[tensor_loc]; + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + binary_op_scalar( + r_args, args, scalar, n, chunk_size, all_aligned, op); + } +}; + +template +struct BinaryOpListAlphaFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListMetadata& tl, + Op op, + opmath_t alpha) { + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + // to make things simple, we put aligned case in a different code path + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { + // load + load_store(r_args[0], args[0], 0, i_start); + load_store(r_args[1], args[1], 0, i_start); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast( + op(static_cast(r_args[0][ii]), + alpha * static_cast(r_args[1][ii]))); + } + // store + load_store(args[res_arg_index], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + load_args(r_args, args, i_start, chunk_size, n); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast( + op(static_cast(r_args[0][ii]), + alpha * static_cast(r_args[1][ii]))); + } + store_args(args[res_arg_index], r_args[0], i_start, chunk_size, n); + } + } + } +}; + +template +struct BinaryOpScalarTensorFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListMetadata& tl, + Op op, + T* scalar, + opmath_t alpha) { + const int tensor_loc = tl.block_to_tensor[blockIdx.x]; + const int chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + // to make things simple, we put aligned case in a different code path + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { + // load + load_store(r_args[0], args[0], 0, i_start); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast(op( + static_cast(r_args[0][ii]), + static_cast(alpha) * static_cast(*scalar))); + } + // store + load_store(args[res_arg_index], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + // Regardless if depth is 1 (for inplace) or 2 (for out of place), + // r_args has depth 1 + load_args<1>(r_args, args, i_start, chunk_size, n); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast(op( + static_cast(r_args[0][ii]), + static_cast(alpha) * static_cast(*scalar))); + } + store_args(args[res_arg_index], r_args[0], i_start, chunk_size, n); + } + } + } +}; + +// +// Unary Functors +// + +template +struct ZeroFunctor { + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListMetadata<1>& tl) { + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const auto all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + // to make things simple, we put aligned case in a different code path + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = 0; + } + // store + load_store(args[0], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = 0; + } + store_args(args[res_arg_index], r_args[0], i_start, chunk_size, n); + } + } + } +}; + +template +struct UnaryOpFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListMetadata& tl, + Op op) { + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + // to make things simple, we put aligned case in a different code path + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { + // load + load_store(r_args[0], args[0], 0, i_start); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = + static_cast(op(static_cast(r_args[0][ii]))); + } + // store + load_store(args[res_arg_index], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + load_args(r_args, args, i_start, chunk_size, n); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = + static_cast(op(static_cast(r_args[0][ii]))); + } + store_args(args[res_arg_index], r_args[0], i_start, chunk_size, n); + } + } + } +}; + +// +// Pointwise Functors +// + +template +struct PointwiseOpScalarFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListMetadata& tl, + Op op, + opmath_t scalar) { + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + pointwise_op_scalar( + r_args, args, scalar, n, chunk_size, all_aligned, op); + } +}; + +template +struct PointwiseOpScalarListFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListScalarListMetadata& tl, + Op op) { + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + opmath_t scalar = tl.scalar_vals[tensor_loc]; + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + pointwise_op_scalar( + r_args, args, scalar, n, chunk_size, all_aligned, op); + } +}; + +template +struct PointwiseOpListFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListMetadata& tl, + Op op) { + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[depth - 1][kILP]; + + // to make things simple, we put aligned case in a different code path + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { + // load + load_store(r_args[0], args[0], 0, i_start); + load_store(r_args[1], args[1], 0, i_start); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast( + op(static_cast(r_args[0][ii]), + static_cast(r_args[1][ii]))); + } + // store + load_store(args[2], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + load_args(r_args, args, i_start, chunk_size, n); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = static_cast( + op(static_cast(r_args[0][ii]), + static_cast(r_args[1][ii]))); + } + store_args(args[2], r_args[0], i_start, chunk_size, n); + } + } + } +}; + +template +struct TernaryOpListFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListMetadata& tl, + Op op) { + static_assert(depth == 3 || depth == 4, ""); + static_assert(depth >= r_args_depth, ""); + static_assert(res_arg_index == depth - 1 || res_arg_index == 0, ""); + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { + load_store(r_args[0], args[0], 0, i_start); + load_store(r_args[1], args[1], 0, i_start); + load_store(r_args[2], args[2], 0, i_start); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = + op(static_cast(r_args[0][ii]), + static_cast(r_args[1][ii]), + static_cast(r_args[2][ii])); + } + load_store(args[res_arg_index], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + load_args(r_args, args, i_start, chunk_size, n); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = + op(static_cast(r_args[0][ii]), + static_cast(r_args[1][ii]), + static_cast(r_args[2][ii])); + } + store_args(args[res_arg_index], r_args[0], i_start, chunk_size, n); + } + } + } +}; + +template +struct TernaryOpScalarFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListMetadata& tl, + Op op, + opmath_t alpha) { + static_assert(depth == 2 || depth == 3, ""); + static_assert(depth >= r_args_depth, ""); + static_assert(res_arg_index == depth - 1 || res_arg_index == 0, ""); + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + + // to make things simple, we put aligned case in a different code path + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { + // load + load_store(r_args[0], args[0], 0, i_start); + load_store(r_args[1], args[1], 0, i_start); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = + op(static_cast(r_args[0][ii]), + static_cast(r_args[1][ii]), + alpha); + } + // store + load_store(args[res_arg_index], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + load_args(r_args, args, i_start, chunk_size, n); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = + op(static_cast(r_args[0][ii]), + static_cast(r_args[1][ii]), + alpha); + } + store_args(args[res_arg_index], r_args[0], i_start, chunk_size, n); + } + } + } +}; + +template +struct TernaryOpScalarListFunctor { + using opmath_t = at::opmath_type; + template + __device__ __forceinline__ void operator()( + int chunk_size, + TensorListScalarListMetadata& tl, + Op op) { + static_assert(depth == 2 || depth == 3, ""); + static_assert(depth >= r_args_depth, ""); + static_assert(res_arg_index == depth - 1 || res_arg_index == 0, ""); + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + auto n = tl.numel_for_tensor[tensor_loc]; + + T* args[depth]; + const bool all_aligned = + init_args(args, tl, chunk_idx, chunk_size, tensor_loc); + n -= chunk_idx * chunk_size; + T r_args[r_args_depth][kILP]; + const opmath_t scalar = tl.scalar_vals[tensor_loc]; + + // to make things simple, we put aligned case in a different code path + if (n % kILP == 0 && chunk_size % kILP == 0 && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { + // load + load_store(r_args[0], args[0], 0, i_start); + load_store(r_args[1], args[1], 0, i_start); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = + op(static_cast(r_args[0][ii]), + static_cast(r_args[1][ii]), + scalar); + } + // store + load_store(args[res_arg_index], r_args[0], i_start, 0); + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + load_args(r_args, args, i_start, chunk_size, n); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + r_args[0][ii] = + op(static_cast(r_args[0][ii]), + static_cast(r_args[1][ii]), + scalar); + } + store_args(args[res_arg_index], r_args[0], i_start, chunk_size, n); + } + } + } +}; + +template +struct power_functor { + C10_DEVICE T operator()(const T& a, const T& b) const { + return at::native::pow_(a, b); + } +}; + +template +struct reverse_power_functor { + C10_DEVICE T operator()(const T& a, const T& b) const { + return at::native::pow_(b, a); + } +}; + +} // namespace +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ForeachMinMaxFunctors.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ForeachMinMaxFunctors.cuh new file mode 100644 index 0000000000000000000000000000000000000000..9b08911b1d9500f200d55e031ffff7658d5491f0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ForeachMinMaxFunctors.cuh @@ -0,0 +1,22 @@ +#pragma once + +#include + +namespace at::native { + +// std:: does not have clamp functors +template +struct minimum { + __device__ T operator()(const T& a, const T& b) const { + return (_isnan(a) || a < b) ? a : b; + } +}; + +template +struct maximum { + __device__ T operator()(const T& a, const T& b) const { + return (_isnan(a) || a > b) ? a : b; + } +}; + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/GridSampler.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/GridSampler.cuh new file mode 100644 index 0000000000000000000000000000000000000000..392b97d7cd48a6566a24035fabd4fa19b5584086 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/GridSampler.cuh @@ -0,0 +1,321 @@ +#pragma once +#include +#include + +namespace at::native { + +using detail::GridSamplerInterpolation; +using detail::GridSamplerPadding; + +// Unnormalizes a coordinate from the -1 to +1 scale to its pixel index value, +// where we view each pixel as an area between (idx - 0.5) and (idx + 0.5). +// if align_corners: -1 and +1 get sent to the centers of the corner pixels +// -1 --> 0 +// +1 --> (size - 1) +// scale_factor = (size - 1) / 2 +// if not align_corners: -1 and +1 get sent to the image edges +// -1 --> -0.5 +// +1 --> (size - 1) + 0.5 == size - 0.5 +// scale_factor = size / 2 +template +__forceinline__ __device__ +scalar_t grid_sampler_unnormalize(scalar_t coord, int size, bool align_corners) { + if (align_corners) { + // unnormalize coord from [-1, 1] to [0, size - 1] + return ((coord + 1.f) / 2) * (size - 1); + } else { + // unnormalize coord from [-1, 1] to [-0.5, size - 0.5] + return ((coord + 1.f) * size - 1) / 2; + } +} + +// grid_sampler_unnormalize_set_grad works the same as grid_sampler_unnormalize +// except that it also returns the `d output / d input` via pointer argument +// `grad_in`. +// This is useful in the backward pass of grid_sampler. +template +__forceinline__ __device__ +scalar_t grid_sampler_unnormalize_set_grad(scalar_t coord, int size, + bool align_corners, scalar_t *grad_in) { + if (align_corners) { + // unnormalize coord from [-1, 1] to [0, size - 1] + *grad_in = static_cast(size - 1) / 2; + return ((coord + 1.f) / 2) * (size - 1); + } else { + // unnormalize coord from [-1, 1] to [-0.5, size - 0.5] + *grad_in = static_cast(size) / 2; + return ((coord + 1.f) * size - 1) / 2; + } +} + +// Clips coordinates to between 0 and clip_limit - 1 +template +__forceinline__ __device__ +scalar_t clip_coordinates(scalar_t in, int clip_limit) { + return ::min(static_cast(clip_limit - 1), ::max(in, static_cast(0))); +} + +// clip_coordinates_set_grad works similarly to clip_coordinates except that +// it also returns the `d output / d input` via pointer argument `grad_in`. +// This is useful in the backward pass of grid_sampler. +template +__forceinline__ __device__ +scalar_t clip_coordinates_set_grad(scalar_t in, int clip_limit, scalar_t *grad_in) { + // Note that it is important for the gradient calculation that borders + // are considered out of bounds. + if (in <= static_cast(0)) { + *grad_in = static_cast(0); + return static_cast(0); + } else { + scalar_t max = static_cast(clip_limit - 1); + if (in >= max) { + *grad_in = static_cast(0); + return max; + } else { + *grad_in = static_cast(1); + return in; + } + } +} + +// Reflects coordinates until they fall between low and high (inclusive). +// The bounds are passed as twice their value so that half-integer values +// can be represented as ints. +template +__forceinline__ __device__ +scalar_t reflect_coordinates(scalar_t in, int twice_low, int twice_high) { + if (twice_low == twice_high) { + return static_cast(0); + } + scalar_t min = static_cast(twice_low) / 2; + scalar_t span = static_cast(twice_high - twice_low) / 2; + in = ::fabs(in - min); + // `fmod` returns same sign as `in`, which is positive after the `fabs` above. + scalar_t extra = ::fmod(in, span); + int flips = static_cast(::floor(in / span)); + if (flips % 2 == 0) { + return extra + min; + } else { + return span - extra + min; + } +} + +// reflect_coordinates_set_grad works similarly to reflect_coordinates except +// that it also returns the `d output / d input` via pointer argument +// `grad_in`. +// This is useful in the backward pass of grid_sampler. +template +__forceinline__ __device__ +scalar_t reflect_coordinates_set_grad(scalar_t in, int twice_low, int twice_high, + scalar_t *grad_in) { + if (twice_low == twice_high) { + *grad_in = static_cast(0); + return static_cast(0); + } + int grad_in_mult_; + scalar_t min = static_cast(twice_low) / 2; + scalar_t span = static_cast(twice_high - twice_low) / 2; + in = in - min; + if (in < static_cast(0)) { + grad_in_mult_ = -1; + in = -in; + } else { + grad_in_mult_ = 1; + } + // `fmod` returns same sign as `in`, which is positive after the `if` above. + scalar_t extra = ::fmod(in, span); + int flips = static_cast(::floor(in / span)); + if (flips % 2 == 0) { + *grad_in = static_cast(grad_in_mult_); + return extra + min; + } else { + *grad_in = static_cast(-grad_in_mult_); + return span - extra + min; + } +} + +template +__forceinline__ __device__ +scalar_t safe_downgrade_to_int_range(scalar_t x){ + // -100.0 does not have special meaning. This is just to make sure + // it's not within_bounds_2d or within_bounds_3d, and does not cause + // undefined behavior. See #35506. + if (x > INT_MAX-1 || x < INT_MIN || !::isfinite(static_cast(x))) + return static_cast(-100.0); + return x; +} + +template +__forceinline__ __device__ +scalar_t compute_coordinates(scalar_t coord, int size, + GridSamplerPadding padding_mode, + bool align_corners) { + if (padding_mode == GridSamplerPadding::Border) { + // clip coordinates to image borders + coord = clip_coordinates(coord, size); + } else if (padding_mode == GridSamplerPadding::Reflection) { + // reflect coordinates by image borders + if (align_corners) { + coord = reflect_coordinates(coord, 0, 2*(size - 1)); + } else { + coord = reflect_coordinates(coord, -1, 2*size - 1); + } + // clip coordinates to image borders + coord = clip_coordinates(coord, size); + } + + coord = safe_downgrade_to_int_range(coord); + return coord; +} + +// Computes the pixel source index value for a grid coordinate +template +__forceinline__ __device__ +scalar_t grid_sampler_compute_source_index( + scalar_t coord, + int size, + GridSamplerPadding padding_mode, + bool align_corners) { + coord = grid_sampler_unnormalize(coord, size, align_corners); + coord = compute_coordinates(coord, size, padding_mode, align_corners); + return coord; +} + +// grid_sampler_compute_source_index_set_grad works similarly to +// grid_sampler_compute_source_index except that it also returns the +// `d output / d input` via pointer argument `grad_in`. +// This is useful in the backward pass of grid_sampler. +template +__forceinline__ __device__ +scalar_t grid_sampler_compute_source_index_set_grad( + scalar_t coord, + int size, + GridSamplerPadding padding_mode, + bool align_corners, + scalar_t *grad_in) { + scalar_t grad_clip, grad_refl; + coord = grid_sampler_unnormalize_set_grad(coord, size, align_corners, grad_in); + if (padding_mode == GridSamplerPadding::Border) { + // clip coordinates to image borders + coord = clip_coordinates_set_grad(coord, size, &grad_clip); + *grad_in = (*grad_in) * grad_clip; + } else if (padding_mode == GridSamplerPadding::Reflection) { + // reflect coordinates by image borders + if (align_corners) { + coord = reflect_coordinates_set_grad(coord, 0, 2*(size - 1), &grad_refl); + } else { + coord = reflect_coordinates_set_grad(coord, -1, 2*size - 1, &grad_refl); + } + // clip coordinates to image borders + coord = clip_coordinates_set_grad(coord, size, &grad_clip); + *grad_in = (*grad_in) * grad_refl * grad_clip; + } + + coord = safe_downgrade_to_int_range(coord); + return coord; +} + +__forceinline__ __device__ +bool within_bounds_2d(int h, int w, int H, int W) { + return h >= 0 && h < H && w >= 0 && w < W; +} + +__forceinline__ __device__ +bool within_bounds_3d(int d, int h, int w, int D, int H, int W) { + return d >= 0 && d < D && h >= 0 && h < H && w >= 0 && w < W; +} + +template +__forceinline__ __device__ +scalar_t get_value_bounded( + const scalar_t *data, scalar_t x, scalar_t y, int W, int H, int sW, int sH, + GridSamplerPadding padding_mode, + bool align_corners) { + + x = compute_coordinates(x, W, padding_mode, align_corners); + y = compute_coordinates(y, H, padding_mode, align_corners); + + int ix = static_cast(x); + int iy = static_cast(y); + + if (within_bounds_2d(iy, ix, H, W)) { + return data[iy * sH + ix * sW]; + } + return static_cast(0); +} + +template +__forceinline__ __device__ +void safe_add_2d(scalar_t *data, int h, int w, + int sH, int sW, int H, int W, + scalar_t delta, + const index_t NC_offset, + const index_t memory_span) { + if (within_bounds_2d(h, w, H, W)) { + fastAtomicAdd(data, + NC_offset + h * sH + w * sW, + memory_span, + delta, + true); + } +} + +template +__forceinline__ __device__ +void safe_add_3d(scalar_t *data, int d, int h, int w, + int sD, int sH, int sW, int D, int H, int W, + scalar_t delta, + const index_t NC_offset, + const index_t memory_span) { + if (within_bounds_3d(d, h, w, D, H, W)) { + fastAtomicAdd(data, + NC_offset + d * sD + h * sH + w * sW, + memory_span, + delta, + true); + } +} + +template +__forceinline__ __device__ +void add_value_bounded( + scalar_t* data, scalar_t x, scalar_t y, int W, int H, int sW, int sH, + scalar_t delta, + GridSamplerPadding padding_mode, + bool align_corners, + const index_t NC_offset, + const index_t memory_span) { + + x = compute_coordinates(x, W, padding_mode, align_corners); + y = compute_coordinates(y, H, padding_mode, align_corners); + + int ix = static_cast(x); + int iy = static_cast(y); + + safe_add_2d(data, iy, ix, sH, sW, H, W, delta, NC_offset, memory_span); +} + +// Calculate the differential of the cubic convolution, i.e. `d coeff / d x` +template +__forceinline__ __device__ +void get_cubic_coefficients_grad( + scalar_t coeffs[4], + scalar_t t) { + + // Must be the same as forward calculation in + // aten/src/ATen/native/cuda/UpSample.cuh:get_cubic_upsample_coefficients + scalar_t A = -0.75; + + scalar_t x; + x = -1 - t; // 1 < x = |-1 - tx| < 2 + coeffs[0] = (-3 * A * x - 10 * A ) * x - 8 * A; + x = -t; // x = |0 - tx| <= 1 + coeffs[1] = (-3 * (A + 2) * x - 2 * (A + 3)) * x; + x = 1 - t; // x = |1 - tx| <= 1 + coeffs[2] = (3 * (A + 2) * x - 2 * (A + 3)) * x; + x = 2 - t; // 1 < x = |2 - tx| < 2 + coeffs[3] = (3 * A * x - 10 * A) * x + 8 * A; +} + + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/GridSampler.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/GridSampler.h new file mode 100644 index 0000000000000000000000000000000000000000..4da630876302696cfb611a2c6d1b19904ffd2383 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/GridSampler.h @@ -0,0 +1,31 @@ +#pragma once +#include +#include + +namespace at { +class TensorBase; +} + +namespace at::native { + +void launch_grid_sampler_2d_forward_kernel( + const TensorBase &output, const TensorBase &input, const TensorBase &grid, + int64_t interpolation_mode, int64_t padding_mode, bool align_corners); + +void launch_grid_sampler_3d_forward_kernel( + const TensorBase &output, const TensorBase &input, const TensorBase &grid, + int64_t interpolation_mode, int64_t padding_mode, bool align_corners); + +void launch_grid_sampler_2d_backward_kernel( + const TensorBase &grad_input, const TensorBase &grad_grid, + const TensorBase &grad_output, const TensorBase &input, + const TensorBase &grid, int64_t interpolation_mode, int64_t padding_mode, + bool align_corners, std::array output_mask); + +void launch_grid_sampler_3d_backward_kernel( + const TensorBase &grad_input, const TensorBase &grad_grid, + const TensorBase &grad_output, const TensorBase &input, + const TensorBase &grid, int64_t interpolation_mode, int64_t padding_mode, + bool align_corners, std::array output_mask); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/IndexKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/IndexKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..49c075b376d4f646dd82a04093df84cd1c602c3b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/IndexKernel.h @@ -0,0 +1,15 @@ +#pragma once +#include +#include + +namespace at { +struct TensorIteratorBase; +class TensorBase; +} + +namespace at::native { +/// @param maskPrefixSum[in,out] +void launch_masked_scatter_kernel( + const TensorBase &self, const TensorBase &mask, + const TensorBase &maskPrefixSum, const TensorBase &source); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/JitLoops.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/JitLoops.cuh new file mode 100644 index 0000000000000000000000000000000000000000..6540342fda5808954e159de06b976cb2f76a8623 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/JitLoops.cuh @@ -0,0 +1,186 @@ +#pragma once + +#include + +#if AT_USE_JITERATOR() + +#include + +#include +#include +#include + +#include + +#include + +namespace at::native { + +/* Note [Jiterator] +The "jiterator" simply just-in-time compiles the same kernels that +Loops.cuh (and CUDALoops.cuh) usually build. This reduces build time, +build size, and initial CUDA context size. + +By default on non-Windows systems, it also caches compiled kernels in ~/.cache/torch/kernels. +This behavior is controlled with two environment variables: + - USE_PYTORCH_KERNEL_CACHE, if set to zero then this will disable all cache use + - PYTORCH_KERNEL_CACHE_PATH, if set specifies the folder to use for cached kernels + +The jiterator currently has some limitations, however. It cannot: + - handle math on complex datatypes + - handle kernels with scalar parameters + +These improvements will likely come soon. + +For examples of how to use the jiterator see the i1 and gcd kernel +implementations, which pass jittable strings implementing their +operations instead of the typical CUDA functors. + +To pass a runtime argument (similar to lambda captures in non-JIT kernels), +we need to pass to additional arguments to `jitted_gpu_kernel` by value. +Currently only primitive C++ types used for computation are valid. +The order of these extra arguments should be same as the order they appear +in kernel's function signature. (look at polygamma for example) + +NOTE: One big restriction being that these arguments should be after the +arguments provided by TensorIterator. Eg. While capturing `n`, where +`scalar_t x` and `scalar_t y` are provided by TensorIterator, +* foo(scalar_t x, scalar_t y, int n) works! +* foo(int n, scalar_t x, scalar_y) doesn't work +* foo(scalar_t x, int n, scalar_y) doesn't work + +*/ + +// Entrypoint for jitted GPU kernels. +// Only handles elementwise unary and binary kernels with a +// common dtype and a single output. +// NOTE: this assumes the op's iterator has a common_dtype. +// NOTE: We use std::tuple instead of parameter pack +// for `extra_args` due to following +// bug on older versions of clang +// https://bugs.llvm.org/show_bug.cgi?id=23029 +template < + char const* name, + typename return_type, + typename f_inputs_type, + int arity, + typename... Args> +void jitted_gpu_kernel( + TensorIteratorBase& iter, + const std::string& f, + at::cuda::jit::BinaryFuncVariant scalar_pos = + at::cuda::jit::BinaryFuncVariant::NoScalar, + at::opmath_type scalar_val = 0, + std::tuple extra_args = std::make_tuple()) { + // TODO: much of preamble is common to both jitted_gpu_kernel and gpu_kernel + // Maybe it could be refactored? + for (int arg = 0; arg < iter.ntensors(); arg++) { + TORCH_INTERNAL_ASSERT( + iter.device(arg).is_cuda(), + "argument ", arg, ": expected a CUDA device but found ", iter.device(arg)); + } + + if (iter.numel() == 0) { + return; + } + + if (!iter.can_use_32bit_indexing()) { + for (auto& sub_iter : iter.with_32bit_indexing()) { + jitted_gpu_kernel( + sub_iter, f, scalar_pos, scalar_val, extra_args); + } + + return; + } + + // Computes if dynamic casting is needed + // Dynamic casting is needed if an input's dtype differs from the common dtype + // or if the result dtype differs from the output's dtype + // Note: this is intentionally divergent from calling needs_dynamic_casting, + // which is more general and inspects a lambda to determine if dynamic + // casting is needed. + bool needs_dynamic_casting = false; + + // Checks output + const ScalarType return_scalar_type = c10::CppTypeToScalarType::value; + const auto dtype0 = iter.dtype(0); + if (dtype0 != return_scalar_type) { + needs_dynamic_casting = true; + } + + // Checks input(s) + const ScalarType inputs_scalar_type = c10::CppTypeToScalarType::value; + for (auto i = decltype(arity){1}; i < (arity + 1); ++i) { + const auto dtypei = iter.dtype(i); + if (dtypei != inputs_scalar_type) { + needs_dynamic_casting = true; + break; + } + } + if (scalar_pos == at::cuda::jit::BinaryFuncVariant::NoScalar) { + // NOTE: With `scalar_pos=NoScalar`,`scalar_val` is not used + // for computation in the generated code and hence we pass a dummy + // value of `0`. + jitted_gpu_kernel_impl< + /*name*/ name, + /*return_type=*/return_type, + /*f_inputs_type=*/f_inputs_type, + arity, + at::cuda::jit::BinaryFuncVariant::NoScalar>( + iter, f, needs_dynamic_casting, /*scalar_val=*/scalar_val, extra_args); + } else if (scalar_pos == at::cuda::jit::BinaryFuncVariant::RhsScalar) { + jitted_gpu_kernel_impl< + /*name*/ name, + /*return_type=*/return_type, + /*f_inputs_type=*/f_inputs_type, + arity, + at::cuda::jit::BinaryFuncVariant::RhsScalar>( + iter, + f, + needs_dynamic_casting, + scalar_val, + extra_args); + + } else { + jitted_gpu_kernel_impl< + /*name*/ name, + /*return_type=*/return_type, + /*f_inputs_type=*/f_inputs_type, + arity, + at::cuda::jit::BinaryFuncVariant::LhsScalar>( + iter, + f, + needs_dynamic_casting, + scalar_val, + extra_args); + } +} + +// TODO: support runtime state capture similar to `jitted_gpu_kernel`. +template +void opmath_jitted_gpu_kernel_with_scalars(TensorIteratorBase& iter, const std::string& f) { + TORCH_INTERNAL_ASSERT(iter.ntensors() == 3); + //currently jiterator only handles binary functions where both inputs are of the same type (f_inputs_type) + using opmath_t = at::opmath_type; + if (iter.is_cpu_scalar(1)) { + auto scalar_val = iter.scalar_value(1); + iter.remove_operand(1); + // TODO: When all kernels that use gpu_kernel_with_scalars are + // ported to structured, this device guard can be deleted. This + // works around incorrect device guard generation for pre-structured + // kernels device guards, but structured kernels do it right and + // we can assume the device is already set correctly + const OptionalDeviceGuard device_guard(iter.device(1)); + jitted_gpu_kernel(iter, f, at::cuda::jit::BinaryFuncVariant::LhsScalar, scalar_val); + } else if (iter.is_cpu_scalar(2)) { + auto scalar_val = iter.scalar_value(2); + iter.remove_operand(2); + jitted_gpu_kernel(iter, f, at::cuda::jit::BinaryFuncVariant::RhsScalar, scalar_val); + } else { + jitted_gpu_kernel(iter, f); + } +} + +} // namespace at::native + +#endif // AT_USE_JITERATOR() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/KernelUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/KernelUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..6f857f90069466349e4cee6253420608ed5e2563 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/KernelUtils.cuh @@ -0,0 +1,228 @@ +#pragma once +#include + +#if !(defined(USE_ROCM) || ((defined(__CUDA_ARCH__) && (__CUDA_ARCH__ < 800)))) +#include +#endif + +// ROCm 6.3 is planned to have these functions, but until then here they are. +#if defined(USE_ROCM) && ROCM_VERSION >= 60201 +#include +#include + +__device__ inline __hip_bfloat162 preview_unsafeAtomicAdd(__hip_bfloat162* address, __hip_bfloat162 value) { +#if (defined(__gfx942__)) && \ + __has_builtin(__builtin_amdgcn_flat_atomic_fadd_v2bf16) + typedef unsigned short __attribute__((ext_vector_type(2))) vec_short2; + static_assert(sizeof(vec_short2) == sizeof(__hip_bfloat162_raw)); + union { + __hip_bfloat162_raw bf162_raw; + vec_short2 vs2; + } u{static_cast<__hip_bfloat162_raw>(value)}; + u.vs2 = __builtin_amdgcn_flat_atomic_fadd_v2bf16((vec_short2*)address, u.vs2); + return static_cast<__hip_bfloat162>(u.bf162_raw); +#else + static_assert(sizeof(unsigned int) == sizeof(__hip_bfloat162_raw)); + union u_hold { + __hip_bfloat162_raw h2r; + unsigned int u32; + }; + u_hold old_val, new_val; + old_val.u32 = __hip_atomic_load((unsigned int*)address, __ATOMIC_RELAXED, __HIP_MEMORY_SCOPE_AGENT); + do { + new_val.h2r = __hadd2(old_val.h2r, value); + } while (!__hip_atomic_compare_exchange_strong( + (unsigned int*)address, &old_val.u32, new_val.u32, + __ATOMIC_RELAXED, __ATOMIC_RELAXED, __HIP_MEMORY_SCOPE_AGENT)); + return old_val.h2r; +#endif +} + +__device__ inline __half2 preview_unsafeAtomicAdd(__half2* address, __half2 value) { +#if (defined(__gfx942__)) && \ + __has_builtin(__builtin_amdgcn_flat_atomic_fadd_v2f16) + // The api expects an ext_vector_type of half + typedef _Float16 __attribute__((ext_vector_type(2))) vec_fp162; + static_assert(sizeof(vec_fp162) == sizeof(__half2_raw)); + union { + __half2_raw h2r; + vec_fp162 fp16; + } u {static_cast<__half2_raw>(value)}; + u.fp16 = __builtin_amdgcn_flat_atomic_fadd_v2f16((vec_fp162*)address, u.fp16); + return static_cast<__half2>(u.h2r); +#else + static_assert(sizeof(__half2_raw) == sizeof(unsigned int)); + union u_hold { + __half2_raw h2r; + unsigned int u32; + }; + u_hold old_val, new_val; + old_val.u32 = __hip_atomic_load((unsigned int*)address, __ATOMIC_RELAXED, __HIP_MEMORY_SCOPE_AGENT); + do { + new_val.h2r = __hadd2(old_val.h2r, value); + } while (!__hip_atomic_compare_exchange_strong( + (unsigned int*)address, &old_val.u32, new_val.u32, + __ATOMIC_RELAXED, __ATOMIC_RELAXED, __HIP_MEMORY_SCOPE_AGENT)); + return old_val.h2r; +#endif +} +#define ATOMICADD preview_unsafeAtomicAdd +#define NATIVE_ZERO_BF16 __float2bfloat16(0.0f) +#else +#define ATOMICADD atomicAdd +#define NATIVE_ZERO_BF16 __int2bfloat16_rz(0) +#endif + +namespace at:: native { + +__device__ __forceinline__ size_t +idx(const size_t nc, + const size_t height, + const size_t width, + const size_t h, + const size_t w) { + return (nc * height + h) * width + w; +} + +// for channels-last +__device__ __forceinline__ size_t +idx_cl( + const size_t n, const size_t h, const size_t w, const size_t c, + const size_t height, const size_t width, const size_t channel +) { + return ((n * height + h) * width + w) * channel + c; +} + +// fastSpecializedAtomicAdd (and fastAtomicAdd) are an optimization +// that speed up half-precision atomics. The situation with half +// precision atomics is that we have a slow __half atomic, and +// a fast vectored __half2 atomic (this can be worth up to a 6x +// speedup, see https://github.com/pytorch/pytorch/pull/21879). +// We can convert a __half atomic into a __half2 atomic by simply +// pairing the __half with a zero entry on the left/right depending +// on alignment... but only if this wouldn't cause an out of bounds +// access! Thus, you must specify tensor and numel so we can check +// if you would be out-of-bounds and use a plain __half atomic if +// you would be. +template < + typename scalar_t, + typename index_t, + typename std::enable_if_t>* = + nullptr> +__device__ __forceinline__ void fastSpecializedAtomicAdd( + scalar_t* tensor, + index_t index, + const index_t numel, + scalar_t value) { +#if ( \ + (defined(USE_ROCM) && ROCM_VERSION < 60201) || \ + (defined(__CUDA_ARCH__) && (__CUDA_ARCH__ < 700))) + gpuAtomicAddNoReturn( + reinterpret_cast(tensor) + index, + static_cast(value)); +#else + // Accounts for the chance tensor falls on an odd 16 bit alignment (ie, not 32 bit aligned) + __half* target_addr = reinterpret_cast<__half*>(tensor + index); + bool low_byte = (reinterpret_cast(target_addr) % sizeof(__half2) == 0); + + if (low_byte && index < (numel - 1)) { + __half2 value2; + value2.x = static_cast<__half>(value); + value2.y = __int2half_rz(0); + ATOMICADD(reinterpret_cast<__half2*>(target_addr), value2); + + } else if (!low_byte && index > 0) { + __half2 value2; + value2.x = __int2half_rz(0); + value2.y = static_cast<__half>(value); + ATOMICADD(reinterpret_cast<__half2*>(target_addr - 1), value2); + + } else { +#ifdef USE_ROCM + gpuAtomicAddNoReturn( + reinterpret_cast(tensor) + index, static_cast(value)); +#else + atomicAdd( + reinterpret_cast<__half*>(tensor) + index, static_cast<__half>(value)); +#endif + } +#endif +} + +template < + typename scalar_t, + typename index_t, + typename std::enable_if_t>* = + nullptr> +__device__ __forceinline__ void fastSpecializedAtomicAdd( + scalar_t* tensor, + index_t index, + const index_t numel, + scalar_t value) { +#if ( \ + (defined(USE_ROCM) && ROCM_VERSION < 60201) || \ + (defined(__CUDA_ARCH__) && (__CUDA_ARCH__ < 800))) + gpuAtomicAddNoReturn( + reinterpret_cast(tensor) + index, + static_cast(value)); +#else + // Accounts for the chance tensor falls on an odd 16 bit alignment (ie, not 32 bit aligned) + __nv_bfloat16* target_addr = reinterpret_cast<__nv_bfloat16*>(tensor + index); + bool low_byte = (reinterpret_cast(target_addr) % sizeof(__nv_bfloat162) == 0); + + if (low_byte && index < (numel - 1)) { + __nv_bfloat162 value2; + value2.x = *reinterpret_cast<__nv_bfloat16*>(&value); + value2.y = NATIVE_ZERO_BF16; + ATOMICADD(reinterpret_cast<__nv_bfloat162*>(target_addr), value2); + + } else if (!low_byte && index > 0) { + __nv_bfloat162 value2; + value2.x = NATIVE_ZERO_BF16; + value2.y = *reinterpret_cast<__nv_bfloat16*>(&value); + ATOMICADD(reinterpret_cast<__nv_bfloat162*>(target_addr - 1), value2); + + } else { +#ifdef USE_ROCM + gpuAtomicAddNoReturn( + reinterpret_cast(tensor) + index, static_cast(value)); +#else + atomicAdd( + reinterpret_cast<__nv_bfloat16*>(tensor) + index, *reinterpret_cast<__nv_bfloat16*>(&value)); +#endif + } +#endif +} + + +template < + typename scalar_t, + typename index_t, + typename std::enable_if_t && !std::is_same_v>* = + nullptr> +__device__ __forceinline__ void fastSpecializedAtomicAdd( + scalar_t* tensor, + index_t index, + const index_t numel, + scalar_t value) { + gpuAtomicAddNoReturn(tensor + index, value); +} + +template +__device__ __forceinline__ void fastAtomicAdd( + scalar_t* tensor, + index_t index, + const index_t numel, + scalar_t value, + bool fast_atomics) { + if (fast_atomics) { + fastSpecializedAtomicAdd(tensor, index, numel, value); + } else { + gpuAtomicAddNoReturn(tensor + index, value); + } +} + +#undef ATOMICADD +#undef NATIVE_ZERO_BF16 + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/LaunchUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/LaunchUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..d10c3fbb446819f01cb0b1e37c51cdb01a79abea --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/LaunchUtils.h @@ -0,0 +1,16 @@ +#pragma once +#include + +namespace at::native { + +// returns 2**floor(log2(n)) +static int lastPow2(unsigned int n) { + n |= (n >> 1); + n |= (n >> 2); + n |= (n >> 4); + n |= (n >> 8); + n |= (n >> 16); + return std::max(1, n - (n >> 1)); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Loops.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Loops.cuh new file mode 100644 index 0000000000000000000000000000000000000000..bb8c6f1b37ac1b33f4cf64d44fa9ccb33a0f7f2b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Loops.cuh @@ -0,0 +1,328 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + +#include + +#include + +#include + +namespace at::native { + +template +static OffsetCalculator make_input_offset_calculator(const TensorIteratorBase& iter) { + // array size can not be 0, this happens when N == 0 + constexpr int array_size = std::max(N, 1); + TORCH_INTERNAL_ASSERT(N == iter.ntensors() - iter.noutputs()); + std::array strides; + int64_t element_sizes[array_size]; + for (int i = 0; i < N; i++) { + strides[i] = iter.strides(i + iter.noutputs()).data(); + element_sizes[i] = iter.element_size(i + iter.noutputs()); + } + return OffsetCalculator(iter.ndim(), iter.shape().data(), strides.data(), element_sizes); +} + +template +static OffsetCalculator make_output_offset_calculator(const TensorIteratorBase& iter) { + TORCH_INTERNAL_ASSERT(num_outputs == iter.noutputs()); + std::array strides; + int64_t element_sizes[num_outputs]; + for (int i = 0; i < num_outputs; i++) { + strides[i] = iter.strides(i).data(); + element_sizes[i] = iter.element_size(i); + } + return OffsetCalculator(iter.ndim(), iter.shape().data(), strides.data(), element_sizes); +} + +template +__device__ inline void elementwise_kernel_helper(func_t f, policy_t policy) { + using traits = function_traits; + using return_t = typename traits::result_type; + using args_t = typename traits::ArgsTuple; + constexpr int elems_per_thread = policy_t::tws; + + int idx = blockIdx.x; + + return_t results[elems_per_thread]; + args_t args[elems_per_thread]; + + // load + policy.load(args, idx); + + // compute + #pragma unroll + for (int i = 0; i < elems_per_thread; i++) { + if (policy.check_inbounds(i)) { + results[i] = c10::guts::apply(f, args[i]); + } + } + + // store + policy.store(results, idx); +} + +} // namespace at::native + +#include + +namespace at:: native { + +template +void gpu_kernel_nocast(TensorIteratorBase& iter, const func_t& f) { + + for (int arg = 0; arg < iter.ntensors(); arg++) { + TORCH_INTERNAL_ASSERT( + iter.device(arg).is_cuda(), + "argument ", arg, ": expected a CUDA device but found ", iter.device(arg)); + } + + if (iter.numel() == 0) { + return; + } + + if (!iter.can_use_32bit_indexing()) { + for (auto& sub_iter : iter.with_32bit_indexing()) { + gpu_kernel_nocast(sub_iter, f); + } + return; + } + + gpu_kernel_impl_nocast(iter, f); +} + +template +void gpu_kernel(TensorIteratorBase& iter, const func_t& f) { + + for (int arg = 0; arg < iter.ntensors(); arg++) { + TORCH_INTERNAL_ASSERT( + iter.device(arg).is_cuda(), + "argument ", arg, ": expected a CUDA device but found ", iter.device(arg)); + } + + if (iter.numel() == 0) { + return; + } + + if (!iter.can_use_32bit_indexing()) { + for (auto& sub_iter : iter.with_32bit_indexing()) { + gpu_kernel(sub_iter, f); + } + return; + } + + gpu_kernel_impl(iter, f); +} + +template +struct AUnaryFunctor { + using traits = function_traits; + using opmath_arg1_t = typename traits::template arg<0>::type; + __device__ return_t operator()(arg2_t b) const { + return f(a, b); + } + // NB: scalar is stored in higher precision! + AUnaryFunctor(func_t f_, opmath_arg1_t a_): f(f_), a(a_) {} + private: + func_t f; + opmath_arg1_t a; +}; + +template +struct BUnaryFunctor { + using traits = function_traits; + using opmath_arg2_t = typename traits::template arg<1>::type; + __device__ return_t operator()(arg1_t a) const { + return f(a, b); + } + // NB: scalar is stored in higher precision! + BUnaryFunctor(func_t f_, opmath_arg2_t b_): f(f_), b(b_) {} + private: + func_t f; + opmath_arg2_t b; +}; + +// Though seemingly noop, this inserts casts from arg1_t to func_t's type +// (which may be higher precision), as well as casts to return_t +template +struct BinaryFunctor { + __device__ return_t operator()(arg1_t a, arg2_t b) const { + return f(a, b); + } + BinaryFunctor(func_t f_): f(f_) {} + private: + func_t f; +}; + +// Unlike gpu_kernel_with_scalars, this allows you to pass a func_t which +// accepts inputs at higher precision (typically opmath_t), but then +// ensure that we load from memory at the correct precision (scalar_t) +// to avoid expensive loads. For the whole sordid story see +// https://dev-discuss.pytorch.org/t/cuda-loops-case-study-code-generation-vs-templates/302 +template +void opmath_gpu_kernel_with_scalars(TensorIteratorBase& iter, const func_t& f) { + TORCH_INTERNAL_ASSERT(iter.ntensors() == 3); + + using traits = function_traits; + using opmath_arg1_t = typename traits::template arg<0>::type; + using opmath_arg2_t = typename traits::template arg<1>::type; + static_assert( + traits::arity == 2, + "gpu_kernel_with_scalars only supports two input arguments"); + + if (iter.is_cpu_scalar(1)) { + AUnaryFunctor af(f, iter.scalar_value(1)); + iter.remove_operand(1); + // TODO: When all kernels that use gpu_kernel_with_scalars are + // ported to structured, this device guard can be deleted. This + // works around incorrect device guard generation for pre-structured + // kernels device guards, but structured kernels do it right and + // we can assume the device is already set correctly + const OptionalDeviceGuard device_guard(iter.device(1)); + gpu_kernel(iter, af); + } else if (iter.is_cpu_scalar(2)) { + BUnaryFunctor bf(f, iter.scalar_value(2)); + iter.remove_operand(2); + gpu_kernel(iter, bf); + } else { + gpu_kernel(iter, BinaryFunctor(f)); + } +} + +template +void opmath_symmetric_gpu_kernel_with_scalars(TensorIteratorBase& iter, const func_t& f) { + // Use symmetric property of the functor to reduce number of kernels, + // requires f(a, b) == f(b, a) + TORCH_INTERNAL_ASSERT(iter.ntensors() == 3); + + using traits = function_traits; + using opmath_arg_t = typename traits::template arg<0>::type; + static_assert( + traits::arity == 2, + "gpu_kernel_with_scalars only supports two input arguments"); + static_assert(std::is_same_v::type>, + "f is not symmetric"); + + OptionalDeviceGuard device_guard; + opmath_arg_t scalar_val{}; + + if (iter.is_cpu_scalar(1)) { + scalar_val = iter.scalar_value(1); + iter.remove_operand(1); + + // TODO: When all kernels that use gpu_kernel_with_scalars are + // ported to structured, this device guard can be deleted. This + // works around incorrect device guard generation for pre-structured + // kernels device guards, but structured kernels do it right and + // we can assume the device is already set correctly + device_guard.reset_device(iter.device(1)); + } else if (iter.is_cpu_scalar(2)) { + scalar_val = iter.scalar_value(2); + iter.remove_operand(2); + } + + if (iter.ninputs() == 2) { + gpu_kernel(iter, BinaryFunctor(f)); + } else { + AUnaryFunctor unary_f(f, scalar_val); + gpu_kernel(iter, unary_f); + } +} + +// Legacy variant that assumes that func_t has the correct types +// that we expect to load from memory +template +void gpu_kernel_with_scalars(TensorIteratorBase& iter, const func_t& f) { + using traits = function_traits; + static_assert( + traits::arity == 2, + "gpu_kernel_with_scalars only supports two input arguments"); + using arg1_t = typename traits::template arg<0>::type; + using arg2_t = typename traits::template arg<1>::type; + using return_t = typename traits::result_type; + opmath_gpu_kernel_with_scalars(iter, f); +} + +namespace { // functions for `gpu_kernel_multiple_outputs`. + +// check the return type is `thrust::tuple`, not `std::tuple`. +template struct is_tuple: std::false_type {}; + +template struct is_tuple>: std::true_type {}; + +template +C10_LAUNCH_BOUNDS_1(num_threads()) +__global__ void unrolled_elementwise_kernel_for_multi_outputs(int N, func_t f, array_t data, inp_calc_t ic, out_calc_t oc) { + int remaining = N - block_work_size() * blockIdx.x; + elementwise_kernel_helper(f, memory::policies::multi_outputs_unroll(data, remaining, ic, oc)); +} + +template +static inline void launch_unrolled_kernel_for_multi_outputs(int64_t N, const func_t& f, array_t data, inp_calc_t ic, out_calc_t oc) { + TORCH_INTERNAL_ASSERT(N > 0 && N <= std::numeric_limits::max()); + int64_t grid = (N + block_work_size() - 1) / block_work_size(); + auto stream = at::cuda::getCurrentCUDAStream(); + unrolled_elementwise_kernel_for_multi_outputs<<>>(N, f, data, ic, oc); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +void gpu_kernel_multiple_outputs_impl(TensorIteratorBase& iter, const func_t& f) { + using traits = function_traits; + using output_t = typename traits::result_type; + static_assert(is_tuple::value, "f's return type must be `thrust::tuple`"); + constexpr int num_outputs = thrust::tuple_size::value; + constexpr int num_inputs = traits::arity; + constexpr int ntensors = num_outputs + num_inputs; + + TORCH_INTERNAL_ASSERT(iter.can_use_32bit_indexing()); + TORCH_INTERNAL_ASSERT(iter.ntensors() == ntensors); + + std::array data; + for (int i = 0; i < ntensors; i++) { + data[i] = (char*)iter.data_ptr(i); + } + + int64_t numel = iter.numel(); + + if (iter.is_contiguous()) { + auto input_calc = TrivialOffsetCalculator(); + auto output_calc = TrivialOffsetCalculator(); + launch_unrolled_kernel_for_multi_outputs(numel, f, data, input_calc, output_calc); + } else { + auto input_calc = make_input_offset_calculator(iter); + auto output_calc = make_output_offset_calculator(iter); + launch_unrolled_kernel_for_multi_outputs(numel, f, data, input_calc, output_calc); + } +} +} // namespace + +template +void gpu_kernel_multiple_outputs(TensorIteratorBase& iter, const func_t& f) { + ASSERT_HOST_DEVICE_LAMBDA(func_t); + + for (int arg = 0; arg < iter.ntensors(); arg++) { + TORCH_INTERNAL_ASSERT(iter.device(arg).is_cuda()); + } + + if (iter.numel() == 0) { + return; + } + + if (!iter.can_use_32bit_indexing()) { + for (auto& sub_iter : iter.with_32bit_indexing()) { + gpu_kernel_multiple_outputs(sub_iter, f); + } + return; + } + + gpu_kernel_multiple_outputs_impl(iter, f); +} + +} //namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Math.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Math.cuh new file mode 100644 index 0000000000000000000000000000000000000000..2fe8f5dd2e3aeb50df50ed5932f4f0cad4fa903e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Math.cuh @@ -0,0 +1,3390 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::native { +// See note [Jiterator] +// TODO: elaborate in this comment on the structure of math.cuh +#if AT_USE_JITERATOR() + +const auto ndtri_string = jiterator_stringify( + /* + * This function is derived from the implementation of the digamma function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + * + * Evaluates polynomial of degree N: + * + * 2 N + * y = C + C x + C x +...+ C x + * 0 1 2 N + * + * Coefficients are stored in reverse order: + * + * coef[0] = C , ..., coef[N] = C . + * N 0 + */ + template + T polevl(const T x, const T A[], const int len) { + // NOTE: This `polevl` is different from other `polevl` + // implementation (in PyTorch) which expect the `len` to be + // `len(A) - 1` instead of `len(A)`. + T result = 0; + for (int i = 0; i < len; ++i) { + result = result * x + A[i]; + } + return result; + } + + /* + * This function is derived from the implementation of the i1e function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + * + * Computes the argument, x, for which the area under the Gaussian probability density function + * (integrated from minus infinity to x) is equal to y. + */ + template + T ndtri(T y0) { + + constexpr T zero = 0; + constexpr T one = 1; + + // Handles special cases + if (y0 == zero) { + return NEG_INFINITY; + } + if (y0 == one) { + return POS_INFINITY; + } + if (y0 < zero || y0 > one) { + return NAN; + } + + bool code = true; + T y = y0; + // Note: the constant 0.135... is equal to exp(-2) + if (y > one - T{0.13533528323661269189}) { + y = one - y; + code = false; + } + + if (y > T{0.13533528323661269189}) { + /* approximation for 0 <= |y - 0.5| <= 3/8 */ + static const T P0[5] = { + -5.99633501014107895267E1, + 9.80010754185999661536E1, + -5.66762857469070293439E1, + 1.39312609387279679503E1, + -1.23916583867381258016E0, + }; + + static const T Q0[9] = { + 1.00000000000000000000E0, + 1.95448858338141759834E0, + 4.67627912898881538453E0, + 8.63602421390890590575E1, + -2.25462687854119370527E2, + 2.00260212380060660359E2, + -8.20372256168333339912E1, + 1.59056225126211695515E1, + -1.18331621121330003142E0, + }; + + /* sqrt(2pi) */ + constexpr T s2pi = 2.50662827463100050242E0; + + y = y - T{0.5}; + const T y2 = y * y; + T x = y + y * (y2 * polevl(y2, P0, int{5}) / polevl(y2, Q0, int{9})); + return x * s2pi; + } + + T x = sqrt(T{-2.} * log(y)); + const T x0 = x - (log(x) / x); + + const T z = one / x; + T x1; + + /* y > exp(-32) = 1.2664165549e-14 */ + if (x < T{8.0}) { + /* Approximation for interval z = sqrt(-2 log y ) between 2 and 8 + * i.e., y between exp(-2) = .135 and exp(-32) = 1.27e-14. + */ + static const T P1[9] = { + 4.05544892305962419923E0, + 3.15251094599893866154E1, + 5.71628192246421288162E1, + 4.40805073893200834700E1, + 1.46849561928858024014E1, + 2.18663306850790267539E0, + -1.40256079171354495875E-1, + -3.50424626827848203418E-2, + -8.57456785154685413611E-4, + }; + + static const T Q1[9] = { + 1.00000000000000000000E0, + 1.57799883256466749731E1, + 4.53907635128879210584E1, + 4.13172038254672030440E1, + 1.50425385692907503408E1, + 2.50464946208309415979E0, + -1.42182922854787788574E-1, + -3.80806407691578277194E-2, + -9.33259480895457427372E-4, + }; + + x1 = z * polevl(z, P1, int{9}) / polevl(z, Q1, int{9}); + } else { + /* Approximation for interval z = sqrt(-2 log y ) between 8 and 64 + * i.e., y between exp(-32) = 1.27e-14 and exp(-2048) = 3.67e-890. + */ + static const T P2[9] = { + 3.23774891776946035970E0, + 6.91522889068984211695E0, + 3.93881025292474443415E0, + 1.33303460815807542389E0, + 2.01485389549179081538E-1, + 1.23716634817820021358E-2, + 3.01581553508235416007E-4, + 2.65806974686737550832E-6, + 6.23974539184983293730E-9, + }; + + static const T Q2[9] = { + 1.00000000000000000000E0, + 6.02427039364742014255E0, + 3.67983563856160859403E0, + 1.37702099489081330271E0, + 2.16236993594496635890E-1, + 1.34204006088543189037E-2, + 3.28014464682127739104E-4, + 2.89247864745380683936E-6, + 6.79019408009981274425E-9, + }; + + x1 = z * polevl(z, P2, int{9}) / polevl(z, Q2, int{9}); + } + + x = x0 - x1; + return (!code) ? x : -x; + } +); // ndtri_string + +const auto log_ndtr_string = jiterator_stringify( + template + T log_ndtr(T x) { + constexpr T SQRT1_2{0.707106781186547524400844362104849039}; // 1/sqrt(2) + T t = x * SQRT1_2; + if (x < T{-1.0}) { + return log(erfcx(-t) / 2) - t * t; + } else { + return log1p(-erfc(t) / 2); + } + } +); // log_ndtr_string + +const auto gcd_string = jiterator_stringify( + template + T gcd(const T a_in, const T b_in) { + T a = abs(a_in); + T b = abs(b_in); + + while (a != T{0}) { + T c = a; + a = b % a; + b = c; + } + + return b; + } +); // gcd_string + +const auto lcm_string = jiterator_stringify( + template + T gcd(const T a_in, const T b_in) { + T a = abs(a_in); + T b = abs(b_in); + + while (a != T{0}) { + T c = a; + a = b % a; + b = c; + } + + return b; + } + + template + T lcm(const T a, const T b) { + T g = gcd(a, b); + return (g == T{0}) ? T{0} : abs(a / g * b); + } +); // lcm_string + +/* + * For licensing information, please refer to the cpu implementation located in "ATen/native/Math.h". + */ +// [C++ Standard Reference: Gamma Function] https://en.cppreference.com/w/cpp/numeric/math/tgamma +const auto digamma_string = jiterator_stringify( + template + T digamma(T x) { + static const double PI_f64 = 3.14159265358979323846; + + // Short-circuits if x is +/- 0 and returns -/+ ∞ per the C++ standard + if (x == 0) { + return copysign(POS_INFINITY, -x); + } + + T result = 0; + if (x < 0) { + // Short-circuits if x is a negative integer and returns NaN + // per the C++ standard + const bool x_is_integer = (x == trunc(x)); + if (x_is_integer) { + return NAN; + } + + // Extracts the fractional part of x as r, since tan(pi * r) is more numerically + // accurate than tan(pi * x). While these operations are mathematically equivalent + // since both x and r are in radians and tan() has a periodicity of pi, in practice + // the computation of pi * x is a source of error (when |x| > 1). + double q, r; + r = modf(static_cast(x), &q); + result = - PI_f64 / tan(PI_f64 * r); + x = 1 - x; + } + + while (x < T{10}) { + result -= T{1} / x; + x += T{1}; + } + + if (x == T{10}) { + return result + T{2.25175258906672110764}; + } + + T y = 0; + if (x < T{1.0e17}) { + const T A[] = { + 8.33333333333333333333E-2, + -2.10927960927960927961E-2, + 7.57575757575757575758E-3, + -4.16666666666666666667E-3, + 3.96825396825396825397E-3, + -8.33333333333333333333E-3, + 8.33333333333333333333E-2, + }; + + + T z = T{1} / (x * x); + + T polevl_result = 0; + for (int i = 0; i <= 6; i++) { + polevl_result = polevl_result * z + A[i]; + } + y = z * polevl_result; + } + + return log(x) - (T{0.5} / x) - y + result; + } +); // digamma_string + +/* + * This function is derived from the implementation of the zeta function in the Cephes Math Library. + * See note [3-Clause BSD License for the Cephes Math Library]. + */ +const auto zeta_string = jiterator_stringify( + template + T zeta(T x, T q) { + const T MACHEP{1.11022302462515654042E-16}; + constexpr T zero{0}; + constexpr T half{0.5}; + constexpr T one{1}; + static const T A[] = { + 12.0, + -720.0, + 30240.0, + -1209600.0, + 47900160.0, + -1.8924375803183791606e9, /*1.307674368e12/691*/ + 7.47242496e10, + -2.950130727918164224e12, /*1.067062284288e16/3617*/ + 1.1646782814350067249e14, /*5.109094217170944e18/43867*/ + -4.5979787224074726105e15, /*8.028576626982912e20/174611*/ + 1.8152105401943546773e17, /*1.5511210043330985984e23/854513*/ + -7.1661652561756670113e18 /*1.6938241367317436694528e27/236364091*/ + }; + + int i = 0; + T a, b, k, s, t, w; + + // Short-circuits x -> +infty + if (x == one) { + return POS_INFINITY; + } + + // Short-circuits x < 1 -> NaN + if (x < one) { + return NAN; + } + + // Short-circuits negative q integers map to +infty, + // negative q non-integers map to NaN + if (q <= zero) { + if (q == floor(q)) { + return POS_INFINITY; + } + if (x != floor(x)) { + return NAN; + } + } + + s = pow(q, -x); + a = q; + i = 0; + b = zero; + while ((i < 9) || (a <= T{9.0})) { + i += 1; + a += one; + b = pow(a, -x); + s += b; + if ((-MACHEP * s < b) && (b < MACHEP * s)) { + return s; + } + }; + + w = a; + s += b * w / (x - one); + s -= half * b; + a = one; + k = zero; + for (int i = 0; i < 12; i++) { + a *= x + k; + b /= w; + t = a * b / A[i]; + s = s + t; + t = fabs(t / s); + + if (t < MACHEP) { + return s; + } + + k += one; + a *= x + k; + b /= w; + k += one; + } + + return s; + } +); // zeta_string + +const auto trigamma_string = jiterator_stringify( + template + T trigamma(T x) { + const T PI{3.14159265358979323846}; + T sign = 1; + T result = 0; + + if (x < T{0.5}) { + sign = -1; + T sin_pi_x = sin(PI * x); + result -= (PI * PI) / (sin_pi_x * sin_pi_x); + x = 1 - x; + } + + for (int i = 0; i < 6; ++i) { + result += T{1} / (x * x); + x += 1; + } + + const T one{1}; + const T ixx = one / (x*x); + result += (one + one / (T{2}*x) + ixx * (one/T{6} - ixx * (one/T{30} - ixx * (one/T{42})))) / x; + return sign * result; +} +); // trigamma_string + +const auto lgamma_string = jiterator_stringify( + template + T lgamma_kernel(T a) { + return lgamma(a); + } +); // lgamma_string + +const auto polygamma_string = zeta_string + jiterator_stringify( + template + T polygamma(T x, int n) { + // already blocked if n <= 1 + const auto one = T{1}; + return ((n % 2) ? one : -one) * exp(lgamma(static_cast(n) + one)) * + zeta(static_cast(n + 1), x); + } +); // polygamma_string + +const auto exp2_string = jiterator_stringify( + template + T exp2_impl(T a) { + return exp2(a); + } + + namespace std { template class complex; } + template + std::complex exp2_impl(std::complex x) { + // There is no std::exp2 overload for complex, so instead + // use the identity 2^x = e^(ln(2) * x) + const auto ln_2 = static_cast(0.693147180559945309417232121458176); + return exp(ln_2 * x); + } + + template + T exp2_kernel(T a) { + return exp2_impl(a); + } +); // exp2_string + +const auto erfc_string = jiterator_stringify( + template + T erfc_kernel(T a) { + return erfc(a); + } +); // erfc_string + +const auto erfinv_string = jiterator_stringify( + template + T erfinv_kernel(T a) { + return erfinv(a); + } +); // erfinv_string + +const auto entr_string = jiterator_stringify( + template + T entr(T a) { + if (a != a) { + return a; + } + + if (a > 0) { + return -a * log(a); + } + + if (a == 0) { + return 0; + } + + return NEG_INFINITY; + } +); // entr_string + +// NOTE: `kaiser_window_string` depends on `i0_string` +// for its implementation. +const auto i0_string = jiterator_stringify( + template + T chbevl(T x, const T array[], const int len) { + + T b0, b1, b2; + + b0 = array[0]; + b1 = 0; + + for (int i = 1; i < len; ++i) { + b2 = b1; + b1 = b0; + b0 = x * b1 - b2 + array[i]; + } + + return T{0.5} * (b0 - b2); + } + + template + T i0(T _x) { + T x = fabs(_x); + + if (x <= T{8.0}) { + /* Chebyshev coefficients for exp(-x) I0(x) + * in the interval [0,8]. + * + * lim(x->0){ exp(-x) I0(x) } = 1. + */ + static const T A[] = { + -4.41534164647933937950E-18, 3.33079451882223809783E-17, + -2.43127984654795469359E-16, 1.71539128555513303061E-15, + -1.16853328779934516808E-14, 7.67618549860493561688E-14, + -4.85644678311192946090E-13, 2.95505266312963983461E-12, + -1.72682629144155570723E-11, 9.67580903537323691224E-11, + -5.18979560163526290666E-10, 2.65982372468238665035E-9, + -1.30002500998624804212E-8, 6.04699502254191894932E-8, + -2.67079385394061173391E-7, 1.11738753912010371815E-6, + -4.41673835845875056359E-6, 1.64484480707288970893E-5, + -5.75419501008210370398E-5, 1.88502885095841655729E-4, + -5.76375574538582365885E-4, 1.63947561694133579842E-3, + -4.32430999505057594430E-3, 1.05464603945949983183E-2, + -2.37374148058994688156E-2, 4.93052842396707084878E-2, + -9.49010970480476444210E-2, 1.71620901522208775349E-1, + -3.04682672343198398683E-1, 6.76795274409476084995E-1}; + + T y = (x / T{2.0}) - T{2.0}; + return exp(x) * chbevl(y, A, int{30}); + } + + // Handles x > 8 case + /* Chebyshev coefficients for exp(-x) sqrt(x) I0(x) + * in the inverted interval [8,infinity]. + * + * lim(x->inf){ exp(-x) sqrt(x) I0(x) } = 1/sqrt(2pi). + */ + const T B[] = { + -7.23318048787475395456E-18, -4.83050448594418207126E-18, + 4.46562142029675999901E-17, 3.46122286769746109310E-17, + -2.82762398051658348494E-16, -3.42548561967721913462E-16, + 1.77256013305652638360E-15, 3.81168066935262242075E-15, + -9.55484669882830764870E-15, -4.15056934728722208663E-14, + 1.54008621752140982691E-14, 3.85277838274214270114E-13, + 7.18012445138366623367E-13, -1.79417853150680611778E-12, + -1.32158118404477131188E-11, -3.14991652796324136454E-11, + 1.18891471078464383424E-11, 4.94060238822496958910E-10, + 3.39623202570838634515E-9, 2.26666899049817806459E-8, + 2.04891858946906374183E-7, 2.89137052083475648297E-6, + 6.88975834691682398426E-5, 3.36911647825569408990E-3, + 8.04490411014108831608E-1}; + + return (exp(x) * chbevl(T{32.0} / x - T{2.0}, B, int{25})) / sqrt(x); + } +); // i0_string + +const auto i1_string = jiterator_stringify( + template + T chbevl(const T x, const T array[], const int len) { + T b0, b1, b2; + + b0 = array[0]; + b1 = 0; + + for (int i = 1; i < len; ++i) { + b2 = b1; + b1 = b0; + b0 = x * b1 - b2 + array[i]; + } + + return T{0.5} * (b0 - b2); + } + + template + T i1(T _x) { + const T x = fabs(_x); + + if (x <= T{8.0}) { + // Chebyshev coefficients for exp(-x) i1(x) in the internal [0, 8] + // lim(x->0){ exp(-x) i1(x) / x } = 1/2 + static const T coefficients[] = { + 2.77791411276104639959E-18, -2.11142121435816608115E-17, + 1.55363195773620046921E-16, -1.10559694773538630805E-15, + 7.60068429473540693410E-15, -5.04218550472791168711E-14, + 3.22379336594557470981E-13, -1.98397439776494371520E-12, + 1.17361862988909016308E-11, -6.66348972350202774223E-11, + 3.62559028155211703701E-10, -1.88724975172282928790E-9, + 9.38153738649577178388E-9, -4.44505912879632808065E-8, + 2.00329475355213526229E-7, -8.56872026469545474066E-7, + 3.47025130813767847674E-6, -1.32731636560394358279E-5, + 4.78156510755005422638E-5, -1.61760815825896745588E-4, + 5.12285956168575772895E-4, -1.51357245063125314899E-3, + 4.15642294431288815669E-3, -1.05640848946261981558E-2, + 2.47264490306265168283E-2, -5.29459812080949914269E-2, + 1.02643658689847095384E-1, -1.76416518357834055153E-1, + 2.52587186443633654823E-1}; + const T y = x / T{2.0} - T{2.0}; + const T out = exp(x) * x * chbevl(y, coefficients, int{29}); + return (_x < T{0.0}) ? -out : out; + } + + // Chebyshev coefficients for exp(-x) sqrt(x) i1(x) + // in the inverted interval [8, infinity] + // lim(x->inf){ exp(-x) sqrt(x) i1(x) } = 1/sqrt(2pi) + static const T coefficients[] = { + 7.51729631084210481353E-18, 4.41434832307170791151E-18, + -4.65030536848935832153E-17, -3.20952592199342395980E-17, + 2.96262899764595013876E-16, 3.30820231092092828324E-16, + -1.88035477551078244854E-15, -3.81440307243700780478E-15, + 1.04202769841288027642E-14, 4.27244001671195135429E-14, + -2.10154184277266431302E-14, -4.08355111109219731823E-13, + -7.19855177624590851209E-13, 2.03562854414708950722E-12, + 1.41258074366137813316E-11, 3.25260358301548823856E-11, + -1.89749581235054123450E-11, -5.58974346219658380687E-10, + -3.83538038596423702205E-9, -2.63146884688951950684E-8, + -2.51223623787020892529E-7, -3.88256480887769039346E-6, + -1.10588938762623716291E-4, -9.76109749136146840777E-3, + 7.78576235018280120474E-1}; + const T out = (exp(x) * chbevl(T{32.} / x - T{2.}, coefficients, int{25})) / sqrt(x); + return (_x < T{0.}) ? -out : out; + } +); // i1_string + +const auto i1e_string = jiterator_stringify( + template + T chbevl(const T x, const T array[], const int len) { + T b0, b1, b2; + + b0 = array[0]; + b1 = 0; + + for (int i = 1; i < len; ++i) { + b2 = b1; + b1 = b0; + b0 = x * b1 - b2 + array[i]; + } + + return T{0.5} * (b0 - b2); + } + + // See double and float instantiations below + template + T i1e(T _x) { } + + // Double specialization (uses different coefficients than the float version) + template<> + double i1e(double _x) { + const double x = fabs(_x); + if (x <= double{8.}) { + // Chebyshev double coefficients for exp(-x) i1(x) in the interval [0,8]. + // Note: lim(x->0){ exp(-x) i1(x) / x } = 1/2. + static const double coefficients[] = { + 2.77791411276104639959E-18, -2.11142121435816608115E-17, + 1.55363195773620046921E-16, -1.10559694773538630805E-15, + 7.60068429473540693410E-15, -5.04218550472791168711E-14, + 3.22379336594557470981E-13, -1.98397439776494371520E-12, + 1.17361862988909016308E-11, -6.66348972350202774223E-11, + 3.62559028155211703701E-10, -1.88724975172282928790E-9, + 9.38153738649577178388E-9, -4.44505912879632808065E-8, + 2.00329475355213526229E-7, -8.56872026469545474066E-7, + 3.47025130813767847674E-6, -1.32731636560394358279E-5, + 4.78156510755005422638E-5, -1.61760815825896745588E-4, + 5.12285956168575772895E-4, -1.51357245063125314899E-3, + 4.15642294431288815669E-3, -1.05640848946261981558E-2, + 2.47264490306265168283E-2, -5.29459812080949914269E-2, + 1.02643658689847095384E-1, -1.76416518357834055153E-1, + 2.52587186443633654823E-1}; + const double y = x / double{2.} - double{2.}; + const double out = chbevl(y, coefficients, int{29}) * x; + return (_x < 0.) ? -out : out; + } + + // Chebyshev coefficients for exp(-x) sqrt(x) i1(x) + // in the inverted interval (8, infinity]. + // Note: lim(x->inf){ exp(-x) sqrt(x) i1(x) } = 1/sqrt(2pi). + // TODO: what's an "inverted interval"? Open on the left + // and closed on the right? + static const double coefficients[] = { + 7.51729631084210481353E-18, 4.41434832307170791151E-18, + -4.65030536848935832153E-17, -3.20952592199342395980E-17, + 2.96262899764595013876E-16, 3.30820231092092828324E-16, + -1.88035477551078244854E-15, -3.81440307243700780478E-15, + 1.04202769841288027642E-14, 4.27244001671195135429E-14, + -2.10154184277266431302E-14, -4.08355111109219731823E-13, + -7.19855177624590851209E-13, 2.03562854414708950722E-12, + 1.41258074366137813316E-11, 3.25260358301548823856E-11, + -1.89749581235054123450E-11, -5.58974346219658380687E-10, + -3.83538038596423702205E-9, -2.63146884688951950684E-8, + -2.51223623787020892529E-7, -3.88256480887769039346E-6, + -1.10588938762623716291E-4, -9.76109749136146840777E-3, + 7.78576235018280120474E-1}; + + const double out = chbevl(double{32.} / x - double{2.}, coefficients, int{25}) / sqrt(x); + return (_x < double{0.}) ? -out : out; + } + + // Float specialization (uses different coefficients than the double version) + template<> + float i1e(float _x) { + const float x = fabsf(_x); + if (x <= float{8.}) { + // Chebyshev double coefficients for exp(-x) i1(x) in the interval [0,8]. + // Note: lim(x->0){ exp(-x) i1(x) / x } = 1/2. + static const float coefficients[] = { + 9.38153738649577178388E-9f, + -4.44505912879632808065E-8f, + 2.00329475355213526229E-7f, + -8.56872026469545474066E-7f, + 3.47025130813767847674E-6f, + -1.32731636560394358279E-5f, + 4.78156510755005422638E-5f, + -1.61760815825896745588E-4f, + 5.12285956168575772895E-4f, + -1.51357245063125314899E-3f, + 4.15642294431288815669E-3f, + -1.05640848946261981558E-2f, + 2.47264490306265168283E-2f, + -5.29459812080949914269E-2f, + 1.02643658689847095384E-1f, + -1.76416518357834055153E-1f, + 2.52587186443633654823E-1f}; + const float y = x / float{2.} - float{2.}; + const float out = chbevl(y, coefficients, int{17}) * x; + return (_x < 0.) ? -out : out; + } + + // Chebyshev coefficients for exp(-x) sqrt(x) i1(x) + // in the inverted interval (8, infinity]. + // Note: lim(x->inf){ exp(-x) sqrt(x) i1(x) } = 1/sqrt(2pi). + // TODO: what's an "inverted interval"? Open on the left + // and closed on the right? + static const float coefficients[] = { + -3.83538038596423702205E-9f, + -2.63146884688951950684E-8f, + -2.51223623787020892529E-7f, + -3.88256480887769039346E-6f, + -1.10588938762623716291E-4f, + -9.76109749136146840777E-3f, + 7.78576235018280120474E-1f}; + + const float out = chbevl(float{32.} / x - float{2.}, coefficients, int{7}) / sqrt(x); + return (_x < float{0.}) ? -out : out; + } +); // i1e_string + +const auto kaiser_window_string = i0_string + jiterator_stringify( + template + T kaiser_window(T a, T inv_alpha, T beta, T inv_i0_beta) { + T x = a * inv_alpha - T{1}; + T y = max(T{0}, T{1} - x * x); + return i0(beta * sqrt(y)) * inv_i0_beta; + } +); // kaiser_window_string + +const auto sinc_string = jiterator_stringify( + template + T sinc(T a) { + if (a == T(0)) { + return T(1); + } + constexpr T pi = T(3.14159265358979323846L); + T product = pi * a; + return std::sin(product) / product; + } +); // sinc_string + +const auto erfcx_string = jiterator_stringify( + /* The next function is taken from http://ab-initio.mit.edu/Faddeev */ + + /* Copyright (c) 2012 Massachusetts Institute of Technology + * + * Permission is hereby granted, free of charge, to any person obtaining + * a copy of this software and associated documentation files (the + * "Software"), to deal in the Software without restriction, including + * without limitation the rights to use, copy, modify, merge, publish, + * distribute, sublicense, and/or sell copies of the Software, and to + * permit persons to whom the Software is furnished to do so, subject to + * the following conditions: + * + * The above copyright notice and this permission notice shall be + * included in all copies or substantial portions of the Software. + * + * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, + * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF + * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND + * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE + * LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION + * OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION + * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. + */ + + /* erfcx(x) = exp(x^2) erfc(x) function, for real x, written by + Steven G. Johnson, October 2012. + + This function combines a few different ideas. + + First, for x > 50, it uses a continued-fraction expansion (same as + for the Faddeeva function, but with algebraic simplifications for z=i*x). + + Second, for 0 <= x <= 50, it uses Chebyshev polynomial approximations, + but with two twists: + + a) It maps x to y = 4 / (4+x) in [0,1]. This simple transformation, + inspired by a similar transformation in the octave-forge/specfun + erfcx by Soren Hauberg, results in much faster Chebyshev convergence + than other simple transformations I have examined. + + b) Instead of using a single Chebyshev polynomial for the entire + [0,1] y interval, we break the interval up into 100 equal + subintervals, with a switch/lookup table, and use much lower + degree Chebyshev polynomials in each subinterval. This greatly + improves performance in my tests. + + For x < 0, we use the relationship erfcx(-x) = 2 exp(x^2) - erfc(x), + with the usual checks for overflow etcetera. + + Performance-wise, it seems to be substantially faster than either + the SLATEC DERFC function [or an erfcx function derived therefrom] + or Cody's CALERF function (from netlib.org/specfun), while + retaining near machine precision in accuracy. + */ + + /* Given y100 = 100 * y, where y = 4 / (4 + x) for x >= 0, compute erfc(x). + + Uses a look-up table of 100 different Chebyshev polynomials + for y intervals [0,0.01], [0.01,0.02], ...., [0.99,1], generated + with the help of Maple and a little shell script. This allows + the Chebyshev polynomials to be of significantly lower degree (about 1/4) + compared to fitting the whole [0,1] interval with a single polynomial. + */ + + // TODO: review if this is computing in double when given a float input + template + T erfcx_y100(T y100) { + switch (static_cast(y100)) { + case 0: { + T t = 2*y100 - 1; + return 0.70878032454106438663e-3 + (0.71234091047026302958e-3 + (0.35779077297597742384e-5 + (0.17403143962587937815e-7 + (0.81710660047307788845e-10 + (0.36885022360434957634e-12 + 0.15917038551111111111e-14 * t) * t) * t) * t) * t) * t; + } + case 1: { + T t = 2*y100 - 3; + return 0.21479143208285144230e-2 + (0.72686402367379996033e-3 + (0.36843175430938995552e-5 + (0.18071841272149201685e-7 + (0.85496449296040325555e-10 + (0.38852037518534291510e-12 + 0.16868473576888888889e-14 * t) * t) * t) * t) * t) * t; + } + case 2: { + T t = 2*y100 - 5; + return 0.36165255935630175090e-2 + (0.74182092323555510862e-3 + (0.37948319957528242260e-5 + (0.18771627021793087350e-7 + (0.89484715122415089123e-10 + (0.40935858517772440862e-12 + 0.17872061464888888889e-14 * t) * t) * t) * t) * t) * t; + } + case 3: { + T t = 2*y100 - 7; + return 0.51154983860031979264e-2 + (0.75722840734791660540e-3 + (0.39096425726735703941e-5 + (0.19504168704300468210e-7 + (0.93687503063178993915e-10 + (0.43143925959079664747e-12 + 0.18939926435555555556e-14 * t) * t) * t) * t) * t) * t; + } + case 4: { + T t = 2*y100 - 9; + return 0.66457513172673049824e-2 + (0.77310406054447454920e-3 + (0.40289510589399439385e-5 + (0.20271233238288381092e-7 + (0.98117631321709100264e-10 + (0.45484207406017752971e-12 + 0.20076352213333333333e-14 * t) * t) * t) * t) * t) * t; + } + case 5: { + T t = 2*y100 - 11; + return 0.82082389970241207883e-2 + (0.78946629611881710721e-3 + (0.41529701552622656574e-5 + (0.21074693344544655714e-7 + (0.10278874108587317989e-9 + (0.47965201390613339638e-12 + 0.21285907413333333333e-14 * t) * t) * t) * t) * t) * t; + } + case 6: { + T t = 2*y100 - 13; + return 0.98039537275352193165e-2 + (0.80633440108342840956e-3 + (0.42819241329736982942e-5 + (0.21916534346907168612e-7 + (0.10771535136565470914e-9 + (0.50595972623692822410e-12 + 0.22573462684444444444e-14 * t) * t) * t) * t) * t) * t; + } + case 7: { + T t = 2*y100 - 15; + return 0.11433927298290302370e-1 + (0.82372858383196561209e-3 + (0.44160495311765438816e-5 + (0.22798861426211986056e-7 + (0.11291291745879239736e-9 + (0.53386189365816880454e-12 + 0.23944209546666666667e-14 * t) * t) * t) * t) * t) * t; + } + case 8: { + T t = 2*y100 - 17; + return 0.13099232878814653979e-1 + (0.84167002467906968214e-3 + (0.45555958988457506002e-5 + (0.23723907357214175198e-7 + (0.11839789326602695603e-9 + (0.56346163067550237877e-12 + 0.25403679644444444444e-14 * t) * t) * t) * t) * t) * t; + } + case 9: { + T t = 2*y100 - 19; + return 0.14800987015587535621e-1 + (0.86018092946345943214e-3 + (0.47008265848816866105e-5 + (0.24694040760197315333e-7 + (0.12418779768752299093e-9 + (0.59486890370320261949e-12 + 0.26957764568888888889e-14 * t) * t) * t) * t) * t) * t; + } + case 10: { + T t = 2*y100 - 21; + return 0.16540351739394069380e-1 + (0.87928458641241463952e-3 + (0.48520195793001753903e-5 + (0.25711774900881709176e-7 + (0.13030128534230822419e-9 + (0.62820097586874779402e-12 + 0.28612737351111111111e-14 * t) * t) * t) * t) * t) * t; + } + case 11: { + T t = 2*y100 - 23; + return 0.18318536789842392647e-1 + (0.89900542647891721692e-3 + (0.50094684089553365810e-5 + (0.26779777074218070482e-7 + (0.13675822186304615566e-9 + (0.66358287745352705725e-12 + 0.30375273884444444444e-14 * t) * t) * t) * t) * t) * t; + } + case 12: { + T t = 2*y100 - 25; + return 0.20136801964214276775e-1 + (0.91936908737673676012e-3 + (0.51734830914104276820e-5 + (0.27900878609710432673e-7 + (0.14357976402809042257e-9 + (0.70114790311043728387e-12 + 0.32252476000000000000e-14 * t) * t) * t) * t) * t) * t; + } + case 13: { + T t = 2*y100 - 27; + return 0.21996459598282740954e-1 + (0.94040248155366777784e-3 + (0.53443911508041164739e-5 + (0.29078085538049374673e-7 + (0.15078844500329731137e-9 + (0.74103813647499204269e-12 + 0.34251892320000000000e-14 * t) * t) * t) * t) * t) * t; + } + case 14: { + T t = 2*y100 - 29; + return 0.23898877187226319502e-1 + (0.96213386835900177540e-3 + (0.55225386998049012752e-5 + (0.30314589961047687059e-7 + (0.15840826497296335264e-9 + (0.78340500472414454395e-12 + 0.36381553564444444445e-14 * t) * t) * t) * t) * t) * t; + } + case 15: { + T t = 2*y100 - 31; + return 0.25845480155298518485e-1 + (0.98459293067820123389e-3 + (0.57082915920051843672e-5 + (0.31613782169164830118e-7 + (0.16646478745529630813e-9 + (0.82840985928785407942e-12 + 0.38649975768888888890e-14 * t) * t) * t) * t) * t) * t; + } + case 16: { + T t = 2*y100 - 33; + return 0.27837754783474696598e-1 + (0.10078108563256892757e-2 + (0.59020366493792212221e-5 + (0.32979263553246520417e-7 + (0.17498524159268458073e-9 + (0.87622459124842525110e-12 + 0.41066206488888888890e-14 * t) * t) * t) * t) * t) * t; + } + case 17: { + T t = 2*y100 - 35; + return 0.29877251304899307550e-1 + (0.10318204245057349310e-2 + (0.61041829697162055093e-5 + (0.34414860359542720579e-7 + (0.18399863072934089607e-9 + (0.92703227366365046533e-12 + 0.43639844053333333334e-14 * t) * t) * t) * t) * t) * t; + } + case 18: { + T t = 2*y100 - 37; + return 0.31965587178596443475e-1 + (0.10566560976716574401e-2 + (0.63151633192414586770e-5 + (0.35924638339521924242e-7 + (0.19353584758781174038e-9 + (0.98102783859889264382e-12 + 0.46381060817777777779e-14 * t) * t) * t) * t) * t) * t; + } + case 19: { + T t = 2*y100 - 39; + return 0.34104450552588334840e-1 + (0.10823541191350532574e-2 + (0.65354356159553934436e-5 + (0.37512918348533521149e-7 + (0.20362979635817883229e-9 + (0.10384187833037282363e-11 + 0.49300625262222222221e-14 * t) * t) * t) * t) * t) * t; + } + case 20: { + T t = 2*y100 - 41; + return 0.36295603928292425716e-1 + (0.11089526167995268200e-2 + (0.67654845095518363577e-5 + (0.39184292949913591646e-7 + (0.21431552202133775150e-9 + (0.10994259106646731797e-11 + 0.52409949102222222221e-14 * t) * t) * t) * t) * t) * t; + } + case 21: { + T t = 2*y100 - 43; + return 0.38540888038840509795e-1 + (0.11364917134175420009e-2 + (0.70058230641246312003e-5 + (0.40943644083718586939e-7 + (0.22563034723692881631e-9 + (0.11642841011361992885e-11 + 0.55721092871111111110e-14 * t) * t) * t) * t) * t) * t; + } + case 22: { + T t = 2*y100 - 45; + return 0.40842225954785960651e-1 + (0.11650136437945673891e-2 + (0.72569945502343006619e-5 + (0.42796161861855042273e-7 + (0.23761401711005024162e-9 + (0.12332431172381557035e-11 + 0.59246802364444444445e-14 * t) * t) * t) * t) * t) * t; + } + case 23: { + T t = 2*y100 - 47; + return 0.43201627431540222422e-1 + (0.11945628793917272199e-2 + (0.75195743532849206263e-5 + (0.44747364553960993492e-7 + (0.25030885216472953674e-9 + (0.13065684400300476484e-11 + 0.63000532853333333334e-14 * t) * t) * t) * t) * t) * t; + } + case 24: { + T t = 2*y100 - 49; + return 0.45621193513810471438e-1 + (0.12251862608067529503e-2 + (0.77941720055551920319e-5 + (0.46803119830954460212e-7 + (0.26375990983978426273e-9 + (0.13845421370977119765e-11 + 0.66996477404444444445e-14 * t) * t) * t) * t) * t) * t; + } + case 25: { + T t = 2*y100 - 51; + return 0.48103121413299865517e-1 + (0.12569331386432195113e-2 + (0.80814333496367673980e-5 + (0.48969667335682018324e-7 + (0.27801515481905748484e-9 + (0.14674637611609884208e-11 + 0.71249589351111111110e-14 * t) * t) * t) * t) * t) * t; + } + case 26: { + T t = 2*y100 - 53; + return 0.50649709676983338501e-1 + (0.12898555233099055810e-2 + (0.83820428414568799654e-5 + (0.51253642652551838659e-7 + (0.29312563849675507232e-9 + (0.15556512782814827846e-11 + 0.75775607822222222221e-14 * t) * t) * t) * t) * t) * t; + } + case 27: { + T t = 2*y100 - 55; + return 0.53263363664388864181e-1 + (0.13240082443256975769e-2 + (0.86967260015007658418e-5 + (0.53662102750396795566e-7 + (0.30914568786634796807e-9 + (0.16494420240828493176e-11 + 0.80591079644444444445e-14 * t) * t) * t) * t) * t) * t; + } + case 28: { + T t = 2*y100 - 57; + return 0.55946601353500013794e-1 + (0.13594491197408190706e-2 + (0.90262520233016380987e-5 + (0.56202552975056695376e-7 + (0.32613310410503135996e-9 + (0.17491936862246367398e-11 + 0.85713381688888888890e-14 * t) * t) * t) * t) * t) * t; + } + case 29: { + T t = 2*y100 - 59; + return 0.58702059496154081813e-1 + (0.13962391363223647892e-2 + (0.93714365487312784270e-5 + (0.58882975670265286526e-7 + (0.34414937110591753387e-9 + (0.18552853109751857859e-11 + 0.91160736711111111110e-14 * t) * t) * t) * t) * t) * t; + } + case 30: { + T t = 2*y100 - 61; + return 0.61532500145144778048e-1 + (0.14344426411912015247e-2 + (0.97331446201016809696e-5 + (0.61711860507347175097e-7 + (0.36325987418295300221e-9 + (0.19681183310134518232e-11 + 0.96952238400000000000e-14 * t) * t) * t) * t) * t) * t; + } + case 31: { + T t = 2*y100 - 63; + return 0.64440817576653297993e-1 + (0.14741275456383131151e-2 + (0.10112293819576437838e-4 + (0.64698236605933246196e-7 + (0.38353412915303665586e-9 + (0.20881176114385120186e-11 + 0.10310784480000000000e-13 * t) * t) * t) * t) * t) * t; + } + case 32: { + T t = 2*y100 - 65; + return 0.67430045633130393282e-1 + (0.15153655418916540370e-2 + (0.10509857606888328667e-4 + (0.67851706529363332855e-7 + (0.40504602194811140006e-9 + (0.22157325110542534469e-11 + 0.10964842115555555556e-13 * t) * t) * t) * t) * t) * t; + } + case 33: { + T t = 2*y100 - 67; + return 0.70503365513338850709e-1 + (0.15582323336495709827e-2 + (0.10926868866865231089e-4 + (0.71182482239613507542e-7 + (0.42787405890153386710e-9 + (0.23514379522274416437e-11 + 0.11659571751111111111e-13 * t) * t) * t) * t) * t) * t; + } + case 34: { + T t = 2*y100 - 69; + return 0.73664114037944596353e-1 + (0.16028078812438820413e-2 + (0.11364423678778207991e-4 + (0.74701423097423182009e-7 + (0.45210162777476488324e-9 + (0.24957355004088569134e-11 + 0.12397238257777777778e-13 * t) * t) * t) * t) * t) * t; + } + case 35: { + T t = 2*y100 - 71; + return 0.76915792420819562379e-1 + (0.16491766623447889354e-2 + (0.11823685320041302169e-4 + (0.78420075993781544386e-7 + (0.47781726956916478925e-9 + (0.26491544403815724749e-11 + 0.13180196462222222222e-13 * t) * t) * t) * t) * t) * t; + } + case 36: { + T t = 2*y100 - 73; + return 0.80262075578094612819e-1 + (0.16974279491709504117e-2 + (0.12305888517309891674e-4 + (0.82350717698979042290e-7 + (0.50511496109857113929e-9 + (0.28122528497626897696e-11 + 0.14010889635555555556e-13 * t) * t) * t) * t) * t) * t; + } + case 37: { + T t = 2*y100 - 75; + return 0.83706822008980357446e-1 + (0.17476561032212656962e-2 + (0.12812343958540763368e-4 + (0.86506399515036435592e-7 + (0.53409440823869467453e-9 + (0.29856186620887555043e-11 + 0.14891851591111111111e-13 * t) * t) * t) * t) * t) * t; + } + case 38: { + T t = 2*y100 - 77; + return 0.87254084284461718231e-1 + (0.17999608886001962327e-2 + (0.13344443080089492218e-4 + (0.90900994316429008631e-7 + (0.56486134972616465316e-9 + (0.31698707080033956934e-11 + 0.15825697795555555556e-13 * t) * t) * t) * t) * t) * t; + } + case 39: { + T t = 2*y100 - 79; + return 0.90908120182172748487e-1 + (0.18544478050657699758e-2 + (0.13903663143426120077e-4 + (0.95549246062549906177e-7 + (0.59752787125242054315e-9 + (0.33656597366099099413e-11 + 0.16815130613333333333e-13 * t) * t) * t) * t) * t) * t; + } + case 40: { + T t = 2*y100 - 81; + return 0.94673404508075481121e-1 + (0.19112284419887303347e-2 + (0.14491572616545004930e-4 + (0.10046682186333613697e-6 + (0.63221272959791000515e-9 + (0.35736693975589130818e-11 + 0.17862931591111111111e-13 * t) * t) * t) * t) * t) * t; + } + case 41: { + T t = 2*y100 - 83; + return 0.98554641648004456555e-1 + (0.19704208544725622126e-2 + (0.15109836875625443935e-4 + (0.10567036667675984067e-6 + (0.66904168640019354565e-9 + (0.37946171850824333014e-11 + 0.18971959040000000000e-13 * t) * t) * t) * t) * t) * t; + } + case 42: { + T t = 2*y100 - 85; + return 0.10255677889470089531e0 + (0.20321499629472857418e-2 + (0.15760224242962179564e-4 + (0.11117756071353507391e-6 + (0.70814785110097658502e-9 + (0.40292553276632563925e-11 + 0.20145143075555555556e-13 * t) * t) * t) * t) * t) * t; + } + case 43: { + T t = 2*y100 - 87; + return 0.10668502059865093318e0 + (0.20965479776148731610e-2 + (0.16444612377624983565e-4 + (0.11700717962026152749e-6 + (0.74967203250938418991e-9 + (0.42783716186085922176e-11 + 0.21385479360000000000e-13 * t) * t) * t) * t) * t) * t; + } + case 44: { + T t = 2*y100 - 89; + return 0.11094484319386444474e0 + (0.21637548491908170841e-2 + (0.17164995035719657111e-4 + (0.12317915750735938089e-6 + (0.79376309831499633734e-9 + (0.45427901763106353914e-11 + 0.22696025653333333333e-13 * t) * t) * t) * t) * t) * t; + } + case 45: { + T t = 2*y100 - 91; + return 0.11534201115268804714e0 + (0.22339187474546420375e-2 + (0.17923489217504226813e-4 + (0.12971465288245997681e-6 + (0.84057834180389073587e-9 + (0.48233721206418027227e-11 + 0.24079890062222222222e-13 * t) * t) * t) * t) * t) * t; + } + case 46: { + T t = 2*y100 - 93; + return 0.11988259392684094740e0 + (0.23071965691918689601e-2 + (0.18722342718958935446e-4 + (0.13663611754337957520e-6 + (0.89028385488493287005e-9 + (0.51210161569225846701e-11 + 0.25540227111111111111e-13 * t) * t) * t) * t) * t) * t; + } + case 47: { + T t = 2*y100 - 95; + return 0.12457298393509812907e0 + (0.23837544771809575380e-2 + (0.19563942105711612475e-4 + (0.14396736847739470782e-6 + (0.94305490646459247016e-9 + (0.54366590583134218096e-11 + 0.27080225920000000000e-13 * t) * t) * t) * t) * t) * t; + } + case 48: { + T t = 2*y100 - 97; + return 0.12941991566142438816e0 + (0.24637684719508859484e-2 + (0.20450821127475879816e-4 + (0.15173366280523906622e-6 + (0.99907632506389027739e-9 + (0.57712760311351625221e-11 + 0.28703099555555555556e-13 * t) * t) * t) * t) * t) * t; + } + case 49: { + T t = 2*y100 - 99; + return 0.13443048593088696613e0 + (0.25474249981080823877e-2 + (0.21385669591362915223e-4 + (0.15996177579900443030e-6 + (0.10585428844575134013e-8 + (0.61258809536787882989e-11 + 0.30412080142222222222e-13 * t) * t) * t) * t) * t) * t; + } + case 50: { + T t = 2*y100 - 101; + return 0.13961217543434561353e0 + (0.26349215871051761416e-2 + (0.22371342712572567744e-4 + (0.16868008199296822247e-6 + (0.11216596910444996246e-8 + (0.65015264753090890662e-11 + 0.32210394506666666666e-13 * t) * t) * t) * t) * t) * t; + } + case 51: { + T t = 2*y100 - 103; + return 0.14497287157673800690e0 + (0.27264675383982439814e-2 + (0.23410870961050950197e-4 + (0.17791863939526376477e-6 + (0.11886425714330958106e-8 + (0.68993039665054288034e-11 + 0.34101266222222222221e-13 * t) * t) * t) * t) * t) * t; + } + case 52: { + T t = 2*y100 - 105; + return 0.15052089272774618151e0 + (0.28222846410136238008e-2 + (0.24507470422713397006e-4 + (0.18770927679626136909e-6 + (0.12597184587583370712e-8 + (0.73203433049229821618e-11 + 0.36087889048888888890e-13 * t) * t) * t) * t) * t) * t; + } + case 53: { + T t = 2*y100 - 107; + return 0.15626501395774612325e0 + (0.29226079376196624949e-2 + (0.25664553693768450545e-4 + (0.19808568415654461964e-6 + (0.13351257759815557897e-8 + (0.77658124891046760667e-11 + 0.38173420035555555555e-13 * t) * t) * t) * t) * t) * t; + } + case 54: { + T t = 2*y100 - 109; + return 0.16221449434620737567e0 + (0.30276865332726475672e-2 + (0.26885741326534564336e-4 + (0.20908350604346384143e-6 + (0.14151148144240728728e-8 + (0.82369170665974313027e-11 + 0.40360957457777777779e-13 * t) * t) * t) * t) * t) * t; + } + case 55: { + T t = 2*y100 - 111; + return 0.16837910595412130659e0 + (0.31377844510793082301e-2 + (0.28174873844911175026e-4 + (0.22074043807045782387e-6 + (0.14999481055996090039e-8 + (0.87348993661930809254e-11 + 0.42653528977777777779e-13 * t) * t) * t) * t) * t) * t; + } + case 56: { + T t = 2*y100 - 113; + return 0.17476916455659369953e0 + (0.32531815370903068316e-2 + (0.29536024347344364074e-4 + (0.23309632627767074202e-6 + (0.15899007843582444846e-8 + (0.92610375235427359475e-11 + 0.45054073102222222221e-13 * t) * t) * t) * t) * t) * t; + } + case 57: { + T t = 2*y100 - 115; + return 0.18139556223643701364e0 + (0.33741744168096996041e-2 + (0.30973511714709500836e-4 + (0.24619326937592290996e-6 + (0.16852609412267750744e-8 + (0.98166442942854895573e-11 + 0.47565418097777777779e-13 * t) * t) * t) * t) * t) * t; + } + case 58: { + T t = 2*y100 - 117; + return 0.18826980194443664549e0 + (0.35010775057740317997e-2 + (0.32491914440014267480e-4 + (0.26007572375886319028e-6 + (0.17863299617388376116e-8 + (0.10403065638343878679e-10 + 0.50190265831111111110e-13 * t) * t) * t) * t) * t) * t; + } + case 59: { + T t = 2*y100 - 119; + return 0.19540403413693967350e0 + (0.36342240767211326315e-2 + (0.34096085096200907289e-4 + (0.27479061117017637474e-6 + (0.18934228504790032826e-8 + (0.11021679075323598664e-10 + 0.52931171733333333334e-13 * t) * t) * t) * t) * t) * t; + } + case 60: { + T t = 2*y100 - 121; + return 0.20281109560651886959e0 + (0.37739673859323597060e-2 + (0.35791165457592409054e-4 + (0.29038742889416172404e-6 + (0.20068685374849001770e-8 + (0.11673891799578381999e-10 + 0.55790523093333333334e-13 * t) * t) * t) * t) * t) * t; + } + case 61: { + T t = 2*y100 - 123; + return 0.21050455062669334978e0 + (0.39206818613925652425e-2 + (0.37582602289680101704e-4 + (0.30691836231886877385e-6 + (0.21270101645763677824e-8 + (0.12361138551062899455e-10 + 0.58770520160000000000e-13 * t) * t) * t) * t) * t) * t; + } + case 62: { + T t = 2*y100 - 125; + return 0.21849873453703332479e0 + (0.40747643554689586041e-2 + (0.39476163820986711501e-4 + (0.32443839970139918836e-6 + (0.22542053491518680200e-8 + (0.13084879235290858490e-10 + 0.61873153262222222221e-13 * t) * t) * t) * t) * t) * t; + } + case 63: { + T t = 2*y100 - 127; + return 0.22680879990043229327e0 + (0.42366354648628516935e-2 + (0.41477956909656896779e-4 + (0.34300544894502810002e-6 + (0.23888264229264067658e-8 + (0.13846596292818514601e-10 + 0.65100183751111111110e-13 * t) * t) * t) * t) * t) * t; + } + case 64: { + T t = 2*y100 - 129; + return 0.23545076536988703937e0 + (0.44067409206365170888e-2 + (0.43594444916224700881e-4 + (0.36268045617760415178e-6 + (0.25312606430853202748e-8 + (0.14647791812837903061e-10 + 0.68453122631111111110e-13 * t) * t) * t) * t) * t) * t; + } + case 65: { + T t = 2*y100 - 131; + return 0.24444156740777432838e0 + (0.45855530511605787178e-2 + (0.45832466292683085475e-4 + (0.38352752590033030472e-6 + (0.26819103733055603460e-8 + (0.15489984390884756993e-10 + 0.71933206364444444445e-13 * t) * t) * t) * t) * t) * t; + } + case 66: { + T t = 2*y100 - 133; + return 0.25379911500634264643e0 + (0.47735723208650032167e-2 + (0.48199253896534185372e-4 + (0.40561404245564732314e-6 + (0.28411932320871165585e-8 + (0.16374705736458320149e-10 + 0.75541379822222222221e-13 * t) * t) * t) * t) * t) * t; + } + case 67: { + T t = 2*y100 - 135; + return 0.26354234756393613032e0 + (0.49713289477083781266e-2 + (0.50702455036930367504e-4 + (0.42901079254268185722e-6 + (0.30095422058900481753e-8 + (0.17303497025347342498e-10 + 0.79278273368888888890e-13 * t) * t) * t) * t) * t) * t; + } + case 68: { + T t = 2*y100 - 137; + return 0.27369129607732343398e0 + (0.51793846023052643767e-2 + (0.53350152258326602629e-4 + (0.45379208848865015485e-6 + (0.31874057245814381257e-8 + (0.18277905010245111046e-10 + 0.83144182364444444445e-13 * t) * t) * t) * t) * t) * t; + } + case 69: { + T t = 2*y100 - 139; + return 0.28426714781640316172e0 + (0.53983341916695141966e-2 + (0.56150884865255810638e-4 + (0.48003589196494734238e-6 + (0.33752476967570796349e-8 + (0.19299477888083469086e-10 + 0.87139049137777777779e-13 * t) * t) * t) * t) * t) * t; + } + case 70: { + T t = 2*y100 - 141; + return 0.29529231465348519920e0 + (0.56288077305420795663e-2 + (0.59113671189913307427e-4 + (0.50782393781744840482e-6 + (0.35735475025851713168e-8 + (0.20369760937017070382e-10 + 0.91262442613333333334e-13 * t) * t) * t) * t) * t) * t; + } + case 71: { + T t = 2*y100 - 143; + return 0.30679050522528838613e0 + (0.58714723032745403331e-2 + (0.62248031602197686791e-4 + (0.53724185766200945789e-6 + (0.37827999418960232678e-8 + (0.21490291930444538307e-10 + 0.95513539182222222221e-13 * t) * t) * t) * t) * t) * t; + } + case 72: { + T t = 2*y100 - 145; + return 0.31878680111173319425e0 + (0.61270341192339103514e-2 + (0.65564012259707640976e-4 + (0.56837930287837738996e-6 + (0.40035151353392378882e-8 + (0.22662596341239294792e-10 + 0.99891109760000000000e-13 * t) * t) * t) * t) * t) * t; + } + case 73: { + T t = 2*y100 - 147; + return 0.33130773722152622027e0 + (0.63962406646798080903e-2 + (0.69072209592942396666e-4 + (0.60133006661885941812e-6 + (0.42362183765883466691e-8 + (0.23888182347073698382e-10 + 0.10439349811555555556e-12 * t) * t) * t) * t) * t) * t; + } + case 74: { + T t = 2*y100 - 149; + return 0.34438138658041336523e0 + (0.66798829540414007258e-2 + (0.72783795518603561144e-4 + (0.63619220443228800680e-6 + (0.44814499336514453364e-8 + (0.25168535651285475274e-10 + 0.10901861383111111111e-12 * t) * t) * t) * t) * t) * t; + } + case 75: { + T t = 2*y100 - 151; + return 0.35803744972380175583e0 + (0.69787978834882685031e-2 + (0.76710543371454822497e-4 + (0.67306815308917386747e-6 + (0.47397647975845228205e-8 + (0.26505114141143050509e-10 + 0.11376390933333333333e-12 * t) * t) * t) * t) * t) * t; + } + case 76: { + T t = 2*y100 - 153; + return 0.37230734890119724188e0 + (0.72938706896461381003e-2 + (0.80864854542670714092e-4 + (0.71206484718062688779e-6 + (0.50117323769745883805e-8 + (0.27899342394100074165e-10 + 0.11862637614222222222e-12 * t) * t) * t) * t) * t) * t; + } + case 77: { + T t = 2*y100 - 155; + return 0.38722432730555448223e0 + (0.76260375162549802745e-2 + (0.85259785810004603848e-4 + (0.75329383305171327677e-6 + (0.52979361368388119355e-8 + (0.29352606054164086709e-10 + 0.12360253370666666667e-12 * t) * t) * t) * t) * t) * t; + } + case 78: { + T t = 2*y100 - 157; + return 0.40282355354616940667e0 + (0.79762880915029728079e-2 + (0.89909077342438246452e-4 + (0.79687137961956194579e-6 + (0.55989731807360403195e-8 + (0.30866246101464869050e-10 + 0.12868841946666666667e-12 * t) * t) * t) * t) * t) * t; + } + case 79: { + T t = 2*y100 - 159; + return 0.41914223158913787649e0 + (0.83456685186950463538e-2 + (0.94827181359250161335e-4 + (0.84291858561783141014e-6 + (0.59154537751083485684e-8 + (0.32441553034347469291e-10 + 0.13387957943111111111e-12 * t) * t) * t) * t) * t) * t; + } + case 80: { + T t = 2*y100 - 161; + return 0.43621971639463786896e0 + (0.87352841828289495773e-2 + (0.10002929142066799966e-3 + (0.89156148280219880024e-6 + (0.62480008150788597147e-8 + (0.34079760983458878910e-10 + 0.13917107176888888889e-12 * t) * t) * t) * t) * t) * t; + } + case 81: { + T t = 2*y100 - 163; + return 0.45409763548534330981e0 + (0.91463027755548240654e-2 + (0.10553137232446167258e-3 + (0.94293113464638623798e-6 + (0.65972492312219959885e-8 + (0.35782041795476563662e-10 + 0.14455745872000000000e-12 * t) * t) * t) * t) * t) * t; + } + case 82: { + T t = 2*y100 - 165; + return 0.47282001668512331468e0 + (0.95799574408860463394e-2 + (0.11135019058000067469e-3 + (0.99716373005509038080e-6 + (0.69638453369956970347e-8 + (0.37549499088161345850e-10 + 0.15003280712888888889e-12 * t) * t) * t) * t) * t) * t; + } + case 83: { + T t = 2*y100 - 167; + return 0.49243342227179841649e0 + (0.10037550043909497071e-1 + (0.11750334542845234952e-3 + (0.10544006716188967172e-5 + (0.73484461168242224872e-8 + (0.39383162326435752965e-10 + 0.15559069118222222222e-12 * t) * t) * t) * t) * t) * t; + } + case 84: { + T t = 2*y100 - 169; + return 0.51298708979209258326e0 + (0.10520454564612427224e-1 + (0.12400930037494996655e-3 + (0.11147886579371265246e-5 + (0.77517184550568711454e-8 + (0.41283980931872622611e-10 + 0.16122419680000000000e-12 * t) * t) * t) * t) * t) * t; + } + case 85: { + T t = 2*y100 - 171; + return 0.53453307979101369843e0 + (0.11030120618800726938e-1 + (0.13088741519572269581e-3 + (0.11784797595374515432e-5 + (0.81743383063044825400e-8 + (0.43252818449517081051e-10 + 0.16692592640000000000e-12 * t) * t) * t) * t) * t) * t; + } + case 86: { + T t = 2*y100 - 173; + return 0.55712643071169299478e0 + (0.11568077107929735233e-1 + (0.13815797838036651289e-3 + (0.12456314879260904558e-5 + (0.86169898078969313597e-8 + (0.45290446811539652525e-10 + 0.17268801084444444444e-12 * t) * t) * t) * t) * t) * t; + } + case 87: { + T t = 2*y100 - 175; + return 0.58082532122519320968e0 + (0.12135935999503877077e-1 + (0.14584223996665838559e-3 + (0.13164068573095710742e-5 + (0.90803643355106020163e-8 + (0.47397540713124619155e-10 + 0.17850211608888888889e-12 * t) * t) * t) * t) * t) * t; + } + case 88: { + T t = 2*y100 - 177; + return 0.60569124025293375554e0 + (0.12735396239525550361e-1 + (0.15396244472258863344e-3 + (0.13909744385382818253e-5 + (0.95651595032306228245e-8 + (0.49574672127669041550e-10 + 0.18435945564444444444e-12 * t) * t) * t) * t) * t) * t; + } + case 89: { + T t = 2*y100 - 179; + return 0.63178916494715716894e0 + (0.13368247798287030927e-1 + (0.16254186562762076141e-3 + (0.14695084048334056083e-5 + (0.10072078109604152350e-7 + (0.51822304995680707483e-10 + 0.19025081422222222222e-12 * t) * t) * t) * t) * t) * t; + } + case 90: { + T t = 2*y100 - 181; + return 0.65918774689725319200e0 + (0.14036375850601992063e-1 + (0.17160483760259706354e-3 + (0.15521885688723188371e-5 + (0.10601827031535280590e-7 + (0.54140790105837520499e-10 + 0.19616655146666666667e-12 * t) * t) * t) * t) * t) * t; + } + case 91: { + T t = 2*y100 - 183; + return 0.68795950683174433822e0 + (0.14741765091365869084e-1 + (0.18117679143520433835e-3 + (0.16392004108230585213e-5 + (0.11155116068018043001e-7 + (0.56530360194925690374e-10 + 0.20209663662222222222e-12 * t) * t) * t) * t) * t) * t; + } + case 92: { + T t = 2*y100 - 185; + return 0.71818103808729967036e0 + (0.15486504187117112279e-1 + (0.19128428784550923217e-3 + (0.17307350969359975848e-5 + (0.11732656736113607751e-7 + (0.58991125287563833603e-10 + 0.20803065333333333333e-12 * t) * t) * t) * t) * t) * t; + } + case 93: { + T t = 2*y100 - 187; + return 0.74993321911726254661e0 + (0.16272790364044783382e-1 + (0.20195505163377912645e-3 + (0.18269894883203346953e-5 + (0.12335161021630225535e-7 + (0.61523068312169087227e-10 + 0.21395783431111111111e-12 * t) * t) * t) * t) * t) * t; + } + case 94: { + T t = 2*y100 - 189; + return 0.78330143531283492729e0 + (0.17102934132652429240e-1 + (0.21321800585063327041e-3 + (0.19281661395543913713e-5 + (0.12963340087354341574e-7 + (0.64126040998066348872e-10 + 0.21986708942222222222e-12 * t) * t) * t) * t) * t) * t; + } + case 95: { + T t = 2*y100 - 191; + return 0.81837581041023811832e0 + (0.17979364149044223802e-1 + (0.22510330592753129006e-3 + (0.20344732868018175389e-5 + (0.13617902941839949718e-7 + (0.66799760083972474642e-10 + 0.22574701262222222222e-12 * t) * t) * t) * t) * t) * t; + } + case 96: { + T t = 2*y100 - 193; + return 0.85525144775685126237e0 + (0.18904632212547561026e-1 + (0.23764237370371255638e-3 + (0.21461248251306387979e-5 + (0.14299555071870523786e-7 + (0.69543803864694171934e-10 + 0.23158593688888888889e-12 * t) * t) * t) * t) * t) * t; + } + case 97: { + T t = 2*y100 - 195; + return 0.89402868170849933734e0 + (0.19881418399127202569e-1 + (0.25086793128395995798e-3 + (0.22633402747585233180e-5 + (0.15008997042116532283e-7 + (0.72357609075043941261e-10 + 0.23737194737777777778e-12 * t) * t) * t) * t) * t) * t; + } + case 98: { + T t = 2*y100 - 197; + return 0.93481333942870796363e0 + (0.20912536329780368893e-1 + (0.26481403465998477969e-3 + (0.23863447359754921676e-5 + (0.15746923065472184451e-7 + (0.75240468141720143653e-10 + 0.24309291271111111111e-12 * t) * t) * t) * t) * t) * t; + } + case 99: { + T t = 2*y100 - 199; + return 0.97771701335885035464e0 + (0.22000938572830479551e-1 + (0.27951610702682383001e-3 + (0.25153688325245314530e-5 + (0.16514019547822821453e-7 + (0.78191526829368231251e-10 + 0.24873652355555555556e-12 * t) * t) * t) * t) * t) * t; + } + } + + // we only get here if y = 1, i.e. |x| < 4*eps, in which case + // erfcx is within 1e-15 of 1.. + return 1.; + } + + template + T erfcx(T x) { + // Short-circuits on NaN (returning NaN) + if (x != x) { + return x; + } + + if (x >= 0) { + if (x > T{50}) { // continued-fraction expansion is faster + const T ispi = 0.56418958354775628694807945156; // 1 / sqrt(pi) + + if (x > T{5e7}) { // 1-term expansion, important to avoid overflow + return ispi / x; + } + + /* 5-term expansion (rely on compiler for CSE), simplified from: + ispi / (x+0.5/(x+1/(x+1.5/(x+2/x)))) */ + return ispi * ((x*x) * (x*x+T{4.5}) + T{2}) / (x * ((x*x) * (x*x+T{5}) + T{3.75})); + } + + // x >= 0 x <= 50 + return erfcx_y100(T{400} / (T{4} + x)); + } + + // x < 0 + if (x < T{-26.7}) { + return POS_INFINITY; + } else if (x < T{-6.1}) { + return T{2} * exp(x * x); + } + + // x < 0 and x >= -6.1 + return T{2} * exp(x * x) - erfcx_y100(T{400} / (T{4} - x)); + } +); // erfcx_string + +const auto airy_ai_string = jiterator_stringify( + template + T airy_ai_forward(T x) { + static const T AN[] = { + +3.46538101525629032477e-01, + +1.20075952739645805542e+01, + +7.62796053615234516538e+01, + +1.68089224934630576269e+02, + +1.59756391350164413639e+02, + +7.05360906840444183113e+01, + +1.40264691163389668864e+01, + +9.99999999999999995305e-01, + }; + + static const T AD[] = { + +5.67594532638770212846e-01, + +1.47562562584847203173e+01, + +8.45138970141474626562e+01, + +1.77318088145400459522e+02, + +1.64234692871529701831e+02, + +7.14778400825575695274e+01, + +1.40959135607834029598e+01, + +1.00000000000000000470e+00, + }; + + static const T AFN[] = { + -1.31696323418331795333e-01, + -6.26456544431912369773e-01, + -6.93158036036933542233e-01, + -2.79779981545119124951e-01, + -4.91900132609500318020e-02, + -4.06265923594885404393e-03, + -1.59276496239262096340e-04, + -2.77649108155232920844e-06, + -1.67787698489114633780e-08, + }; + + static const T AFD[] = { + +1.33560420706553243746e+01, + +3.26825032795224613948e+01, + +2.67367040941499554804e+01, + +9.18707402907259625840e+00, + +1.47529146771666414581e+00, + +1.15687173795188044134e-01, + +4.40291641615211203805e-03, + +7.54720348287414296618e-05, + +4.51850092970580378464e-07, + }; + + static const T AGN[] = { + +1.97339932091685679179e-02, + +3.91103029615688277255e-01, + +1.06579897599595591108e+00, + +9.39169229816650230044e-01, + +3.51465656105547619242e-01, + +6.33888919628925490927e-02, + +5.85804113048388458567e-03, + +2.82851600836737019778e-04, + +6.98793669997260967291e-06, + +8.11789239554389293311e-08, + +3.41551784765923618484e-10, + }; + + static const T AGD[] = { + +9.30892908077441974853e+00, + +1.98352928718312140417e+01, + +1.55646628932864612953e+01, + +5.47686069422975497931e+00, + +9.54293611618961883998e-01, + +8.64580826352392193095e-02, + +4.12656523824222607191e-03, + +1.01259085116509135510e-04, + +1.17166733214413521882e-06, + +4.91834570062930015649e-09, + }; + + int domain_flag = 0; + + T ai; + + if (isinf(x)) { + return NAN; + } + + if (x > T(103.892)) { + return T(0.0); + } + + T f; + T g; + T k; + + if (x < T(-2.09)) { + T z = T(1.0) / (T(-2.0) * x * sqrt(-x) / T(3.0)); + + T afn = 0.0; + + for (uint8_t index = 0; index <= 8; index++) { + afn = afn * (z * z) + AFN[index]; + } + + T afd = 0.0; + + for (uint8_t index = 0; index <= 8; index++) { + afd = afd * (z * z) + AFD[index]; + } + + T agn = 0.0; + + for (uint8_t index = 0; index <= 10 + 0; index++) { + agn = agn * (z * z) + AGN[index]; + } + + T agd = 0.0; + + for (uint8_t index = 0; index <= 10 - 1; index++) { + agd = agd * (z * z) + AGD[index]; + } + + T t = T(-2.0) * x * sqrt(-x) / T(3.0) + T(0.25) * T(3.14159265358979323846); + + return T(5.64189583547756286948e-01) / sqrt(sqrt(-x)) * (sin(t) * (T(1.0) + z * z * afn / afd) - cos(t) * (z * agn / agd)); + } + + if (x >= T(2.09)) { + domain_flag = 5; + + T zeta = T(2.0) * x * sqrt(x) / T(3.0); + + T an = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + an = an * (T(1.0) / zeta) + AN[index]; + } + + T ad = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + ad = ad * (T(1.0) / zeta) + AD[index]; + } + + ai = T(5.64189583547756286948e-01) * (an / ad) / (T(2.0) * sqrt(sqrt(x)) * exp(zeta)); + + if (x > T(8.3203353)) { + return ai; + } + } + + f = 1.0; + g = x; + k = 1.0; + + T m = 1.0; + T n = x; + T t = 1.0; + T z = x * x * x; + + while (t > T(1.11022302462515654042e-16)) { + m *= z; + k += T(1.0); + m /= k; + n *= z; + k += T(1.0); + n /= k; + m /= k; + f += m; + k += T(1.0); + n /= k; + g += n; + + t = abs(m / f); + } + + if ((domain_flag & 1) == 0) { + return T(0.355028053887817239260) * f - T(0.258819403792806798405) * g; + } + + return ai; + } // T airy_ai(T x) +); // airy_ai_string + +const auto bessel_j0_string = jiterator_stringify( + template + T bessel_j0_forward(T x) { + static const T PP[] = { + +7.96936729297347051624e-04, + +8.28352392107440799803e-02, + +1.23953371646414299388e+00, + +5.44725003058768775090e+00, + +8.74716500199817011941e+00, + +5.30324038235394892183e+00, + +9.99999999999999997821e-01, + }; + + static const T PQ[] = { + +9.24408810558863637013e-04, + +8.56288474354474431428e-02, + +1.25352743901058953537e+00, + +5.47097740330417105182e+00, + +8.76190883237069594232e+00, + +5.30605288235394617618e+00, + +1.00000000000000000218e+00, + }; + + static const T QP[] = { + -1.13663838898469149931e-02, + -1.28252718670509318512e+00, + -1.95539544257735972385e+01, + -9.32060152123768231369e+01, + -1.77681167980488050595e+02, + -1.47077505154951170175e+02, + -5.14105326766599330220e+01, + -6.05014350600728481186e+00, + }; + + static const T QQ[] = { + +6.43178256118178023184e+01, + +8.56430025976980587198e+02, + +3.88240183605401609683e+03, + +7.24046774195652478189e+03, + +5.93072701187316984827e+03, + +2.06209331660327847417e+03, + +2.42005740240291393179e+02, + }; + + static const T RP[] = { + -4.79443220978201773821e+09, + +1.95617491946556577543e+12, + -2.49248344360967716204e+14, + +9.70862251047306323952e+15, + }; + + static const T RQ[] = { + +4.99563147152651017219e+02, + +1.73785401676374683123e+05, + +4.84409658339962045305e+07, + +1.11855537045356834862e+10, + +2.11277520115489217587e+12, + +3.10518229857422583814e+14, + +3.18121955943204943306e+16, + +1.71086294081043136091e+18, + }; + + if (x < T(0)) { + x = -x; + } + + if (x <= T(5.0)) { + if (x < T(0.00001)) { + return T(1.0) - x * x / T(4.0); + } + + T rp = 0.0; + + for (uint8_t index = 0; index <= 3; index++) { + rp = rp * (x * x) + RP[index]; + } + + T rq = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + rq = rq * (x * x) + RQ[index]; + } + + return (x * x - T(5.78318596294678452118e+00)) * (x * x - T(3.04712623436620863991e+01)) * rp / rq; + } + + T pp = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pp = pp * (T(25.0) / (x * x)) + PP[index]; + } + + T pq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pq = pq * (T(25.0) / (x * x)) + PQ[index]; + } + + T qp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + qp = qp * (T(25.0) / (x * x)) + QP[index]; + } + + T qq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + qq = qq * (T(25.0) / (x * x)) + QQ[index]; + } + + return (pp / pq * cos(x - T(0.785398163397448309615660845819875721)) - T(5.0) / x * (qp / qq) * sin(x - T(0.785398163397448309615660845819875721))) * T(0.797884560802865355879892119868763737) / sqrt(x); + } // bessel_j0_forward(T x) +); // bessel_j0_string + +const auto bessel_y0_string = bessel_j0_string + jiterator_stringify( + template + T bessel_y0_forward(T x) { + static const T PP[] = { + +7.96936729297347051624e-04, + +8.28352392107440799803e-02, + +1.23953371646414299388e+00, + +5.44725003058768775090e+00, + +8.74716500199817011941e+00, + +5.30324038235394892183e+00, + +9.99999999999999997821e-01, + }; + + static const T PQ[] = { + +9.24408810558863637013e-04, + +8.56288474354474431428e-02, + +1.25352743901058953537e+00, + +5.47097740330417105182e+00, + +8.76190883237069594232e+00, + +5.30605288235394617618e+00, + +1.00000000000000000218e+00, + }; + + static const T QP[] = { + -1.13663838898469149931e-02, + -1.28252718670509318512e+00, + -1.95539544257735972385e+01, + -9.32060152123768231369e+01, + -1.77681167980488050595e+02, + -1.47077505154951170175e+02, + -5.14105326766599330220e+01, + -6.05014350600728481186e+00, + }; + + static const T QQ[] = { + +6.43178256118178023184e+01, + +8.56430025976980587198e+02, + +3.88240183605401609683e+03, + +7.24046774195652478189e+03, + +5.93072701187316984827e+03, + +2.06209331660327847417e+03, + +2.42005740240291393179e+02, + }; + + static const T YP[] = { + +1.55924367855235737965e+04, + -1.46639295903971606143e+07, + +5.43526477051876500413e+09, + -9.82136065717911466409e+11, + +8.75906394395366999549e+13, + -3.46628303384729719441e+15, + +4.42733268572569800351e+16, + -1.84950800436986690637e+16, + }; + + static const T YQ[] = { + +1.04128353664259848412e+03, + +6.26107330137134956842e+05, + +2.68919633393814121987e+08, + +8.64002487103935000337e+10, + +2.02979612750105546709e+13, + +3.17157752842975028269e+15, + +2.50596256172653059228e+17, + }; + + if (x <= T(5.0)) { + if (x == T(0.0)) { + return NEG_INFINITY; + } + + if (x < T(0.0)) { + NAN; + } + + T yp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + yp = yp * (x * x) + YP[index]; + } + + T yq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + yq = yq * (x * x) + YQ[index]; + } + + return yp / yq + (T(0.636619772367581343075535053490057448) * log(x) * bessel_j0_forward(x)); + } + + T pp = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pp = pp * (T(25.0) / (x * x)) + PP[index]; + } + + T pq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pq = pq * (T(25.0) / (x * x)) + PQ[index]; + } + + T qp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + qp = qp * (T(25.0) / (x * x)) + QP[index]; + } + + T qq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + qq = qq * (T(25.0) / (x * x)) + QQ[index]; + } + + return (pp / pq * sin(x - T(0.785398163397448309615660845819875721)) + T(5.0) / x * (qp / qq) * cos(x - T(0.785398163397448309615660845819875721))) * T(0.797884560802865355879892119868763737) / sqrt(x); + } // bessel_y0_forward(T x) +); // bessel_y0_string + +const auto bessel_j1_string = jiterator_stringify( + template + T bessel_j1_forward(T x) { + static const T PP[] = { + +7.62125616208173112003e-04, + +7.31397056940917570436e-02, + +1.12719608129684925192e+00, + +5.11207951146807644818e+00, + +8.42404590141772420927e+00, + +5.21451598682361504063e+00, + +1.00000000000000000254e+00, + }; + + static const T PQ[] = { + +5.71323128072548699714e-04, + +6.88455908754495404082e-02, + +1.10514232634061696926e+00, + +5.07386386128601488557e+00, + +8.39985554327604159757e+00, + +5.20982848682361821619e+00, + +9.99999999999999997461e-01, + }; + + static const T QP[] = { + +5.10862594750176621635e-02, + +4.98213872951233449420e+00, + +7.58238284132545283818e+01, + +3.66779609360150777800e+02, + +7.10856304998926107277e+02, + +5.97489612400613639965e+02, + +2.11688757100572135698e+02, + +2.52070205858023719784e+01, + }; + + static const T QQ[] = { + +7.42373277035675149943e+01, + +1.05644886038262816351e+03, + +4.98641058337653607651e+03, + +9.56231892404756170795e+03, + +7.99704160447350683650e+03, + +2.82619278517639096600e+03, + +3.36093607810698293419e+02, + }; + + static const T RP[] = { + -8.99971225705559398224e+08, + +4.52228297998194034323e+11, + -7.27494245221818276015e+13, + +3.68295732863852883286e+15, + }; + + static const T RQ[] = { + +6.20836478118054335476e+02, + +2.56987256757748830383e+05, + +8.35146791431949253037e+07, + +2.21511595479792499675e+10, + +4.74914122079991414898e+12, + +7.84369607876235854894e+14, + +8.95222336184627338078e+16, + +5.32278620332680085395e+18, + }; + + if (x < T(0.0)) { + return -bessel_j1_forward(-x); + } + + if (x <= T(5.0)) { + T rp = 0.0; + + for (uint8_t index = 0; index <= 3; index++) { + rp = rp * (x * x) + RP[index]; + } + + T rq = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + rq = rq * (x * x) + RQ[index]; + } + + return rp / rq * x * (x * x - T(1.46819706421238932572e+01)) * (x * x - T(4.92184563216946036703e+01)); + } + + T pp = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pp = pp * (T(5.0) / x * (T(5.0) / x)) + PP[index]; + } + + T pq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pq = pq * (T(5.0) / x * (T(5.0) / x)) + PQ[index]; + } + + T qp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + qp = qp * (T(5.0) / x * (T(5.0) / x)) + QP[index]; + } + + T qq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + qq = qq * (T(5.0) / x * (T(5.0) / x)) + QQ[index]; + } + + return (pp / pq * cos(x - T(2.356194490192344928846982537459627163)) - T(5.0) / x * (qp / qq) * sin(x - T(2.356194490192344928846982537459627163))) * T(0.797884560802865355879892119868763737) / sqrt(x); + } // bessel_j1_forward(T x) +); // bessel_j1_string + +const auto bessel_y1_string = bessel_j1_string + jiterator_stringify( + template + T bessel_y1_forward(T x) { + static const T PP[] = { + +7.62125616208173112003e-04, + +7.31397056940917570436e-02, + +1.12719608129684925192e+00, + +5.11207951146807644818e+00, + +8.42404590141772420927e+00, + +5.21451598682361504063e+00, + +1.00000000000000000254e+00, + }; + + static const T PQ[] = { + +5.71323128072548699714e-04, + +6.88455908754495404082e-02, + +1.10514232634061696926e+00, + +5.07386386128601488557e+00, + +8.39985554327604159757e+00, + +5.20982848682361821619e+00, + +9.99999999999999997461e-01, + }; + + static const T QP[] = { + +5.10862594750176621635e-02, + +4.98213872951233449420e+00, + +7.58238284132545283818e+01, + +3.66779609360150777800e+02, + +7.10856304998926107277e+02, + +5.97489612400613639965e+02, + +2.11688757100572135698e+02, + +2.52070205858023719784e+01, + }; + + static const T QQ[] = { + +7.42373277035675149943e+01, + +1.05644886038262816351e+03, + +4.98641058337653607651e+03, + +9.56231892404756170795e+03, + +7.99704160447350683650e+03, + +2.82619278517639096600e+03, + +3.36093607810698293419e+02, + }; + + static const T YP[] = { + +1.26320474790178026440e+09, + -6.47355876379160291031e+11, + +1.14509511541823727583e+14, + -8.12770255501325109621e+15, + +2.02439475713594898196e+17, + -7.78877196265950026825e+17, + }; + + static const T YQ[] = { + +5.94301592346128195359e+02, + +2.35564092943068577943e+05, + +7.34811944459721705660e+07, + +1.87601316108706159478e+10, + +3.88231277496238566008e+12, + +6.20557727146953693363e+14, + +6.87141087355300489866e+16, + +3.97270608116560655612e+18, + }; + + if (x <= T(5.0)) { + if (x == T(0.0)) { + return NEG_INFINITY; + } + + if (x <= T(0.0)) { + return NAN; + } + + T yp = 0.0; + + for (uint8_t index = 0; index <= 5; index++) { + yp = yp * (x * x) + YP[index]; + } + + T yq = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + yq = yq * (x * x) + YQ[index]; + } + + return x * (yp / yq) + (T(0.636619772367581343075535053490057448) * (bessel_j1_forward(x) * log(x) - T(1.0) / x)); + } + + T pp = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pp = pp * (T(5.0) / x * (T(5.0) / x)) + PP[index]; + } + + T pq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + pq = pq * (T(5.0) / x * (T(5.0) / x)) + PQ[index]; + } + + T qp = 0.0; + + for (uint8_t index = 0; index <= 7; index++) { + qp = qp * (T(5.0) / x * (T(5.0) / x)) + QP[index]; + } + + T qq = 0.0; + + for (uint8_t index = 0; index <= 6; index++) { + qq = qq * (T(5.0) / x * (T(5.0) / x)) + QQ[index]; + } + + return (pp / pq * sin(x - T(2.356194490192344928846982537459627163)) + T(5.0) / x * (qp / qq) * cos(x - T(2.356194490192344928846982537459627163))) * T(0.797884560802865355879892119868763737) / sqrt(x); + } // bessel_y1_forward(T x) +); // bessel_y1_string + +const auto chebyshev_polynomial_t_string = jiterator_stringify( + template + T chebyshev_polynomial_t_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (abs(x) == T(1.0)) { + if (x > T(0.0) || n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if ((n > 6) && (abs(x) < T(1.0))) { + return cos(n * acos(x)); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x; + } + + T p = T(1.0); + T q = x; + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x) * q - p; + p = q; + q = r; + } + + return r; + } // chebyshev_polynomial_t_forward(T x, int64_t n) + + template + T chebyshev_polynomial_t_forward(T x, T n) { + return chebyshev_polynomial_t_forward(x, static_cast(n)); + } // chebyshev_polynomial_t_forward(T x, T n) +); // chebyshev_polynomial_t_string + +const auto chebyshev_polynomial_u_string = jiterator_stringify( + template + T chebyshev_polynomial_u_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (abs(x) == T(1.0)) { + if (x > T(0.0) || n % 2 == 0) { + return n + 1; + } + + return -(n + 1); + } + + if ((n > 8) && (abs(x) < T(1.0))) { + if (sin(acos(x)) != T(0.0)) { + return sin((n + 1) * acos(x)) / sin(acos(x)); + } + + return (n + 1) * cos((n + 1) * acos(x)) / x; + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x; + } + + T p = T(1.0); + T q = x + x; + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x) * q - p; + p = q; + q = r; + } + + return r; + } // chebyshev_polynomial_u_forward(T x, int64_t n) + + template + T chebyshev_polynomial_u_forward(T x, T n) { + return chebyshev_polynomial_u_forward(x, static_cast(n)); + } // chebyshev_polynomial_u_forward(T x, T n) +); // chebyshev_polynomial_u_string + +const auto chebyshev_polynomial_v_string = jiterator_stringify( + template + T chebyshev_polynomial_v_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (abs(x) == T(1.0)) { + if (x > T(0.0)) { + return T(1.0); + } + + if (n % 2 == 0) { + return n + n + 1; + } + + return -(n + n + 1); + } + + if ((n > 8) && (abs(x) < T(1.0))) { + if (sin(acos(x) / T(2.0)) != T(1.0)) { + return cos((n + T(0.5)) * acos(x)) / cos(acos(x) / T(2.0)); + } + + if (n % 2 == 0) { + return n + n + 1; + } + + return -(n + n + 1); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0); + } + + T p = T(1.0); + T q = x + x - T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x) * q - p; + p = q; + q = r; + } + + return r; + } // chebyshev_polynomial_v_forward(T x, int64_t n) + + template + T chebyshev_polynomial_v_forward(T x, T n) { + return chebyshev_polynomial_v_forward(x, static_cast(n)); + } // chebyshev_polynomial_v_forward(T x, T n) +); // chebyshev_polynomial_v_string + +const auto chebyshev_polynomial_w_string = jiterator_stringify( + template + T chebyshev_polynomial_w_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (abs(x) == T(1.0)) { + if (x > T(0.0)) { + return n + n + 1; + } + + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if ((n > 8) && (abs(x) < T(1.0))) { + if (cos(acos(x) / T(2.0)) != T(1.0)) { + return sin((n + T(0.5)) * acos(x)) / sin(acos(x) / T(2.0)); + } + + if (x > T(0.0)) { + return n + n + 1; + } + + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x + T(1.0); + } + + T p = T(1.0); + T q = x + x + T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x) * q - p; + p = q; + q = r; + } + + return r; + } // chebyshev_polynomial_w_forward(T x, int64_t n) + + template + T chebyshev_polynomial_w_forward(T x, T n) { + return chebyshev_polynomial_w_forward(x, static_cast(n)); + } // chebyshev_polynomial_w_forward(T x, T n) +); // chebyshev_polynomial_w_string + +const auto hermite_polynomial_h_string = jiterator_stringify( + template + unsigned short getHermitianLimit() { + if (sizeof(T) <= sizeof(float)) { + return 128; + } else if (sizeof(T) <= sizeof(double)) { + return 512; + } else { + return 1024; + } + } + + template + T hermite_polynomial_h_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x; + } + + if (n > getHermitianLimit()) { + return NAN; + } + + T p = T(1.0); + T q = x + x; + T r = T(0.0); + + for (int64_t k = 2; k < n + n; k += 2) { + r = (x + x) * q - k * p; + p = q; + q = r; + } + + return r; + } // hermite_polynomial_h_forward(T x, int64_t n) + + template + T hermite_polynomial_h_forward(T x, T n) { + return hermite_polynomial_h_forward(x, static_cast(n)); + } // hermite_polynomial_h_forward(T x, T n) +); // hermite_polynomial_h_string + +const auto hermite_polynomial_he_string = jiterator_stringify( + template + unsigned short getHermitianLimit() { + if (sizeof(T) <= sizeof(float)) { + return 128; + } else if (sizeof(T) <= sizeof(double)) { + return 512; + } else { + return 1024; + } + } + + template + T hermite_polynomial_he_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x; + } + + if (n > getHermitianLimit()) { + return NAN; + } + + T p = T(1.0); + T q = x; + T r; + + for (int64_t k = 1; k < n; k++) { + r = x * q - k * p; + p = q; + q = r; + } + + return r; + } // hermite_polynomial_he_forward(T x, int64_t n) + + template + T hermite_polynomial_he_forward(T x, T n) { + return hermite_polynomial_he_forward(x, static_cast(n)); + } // hermite_polynomial_he_forward(T x, T n) +); // hermite_polynomial_he_string + +const auto laguerre_polynomial_l_string = jiterator_stringify( + template + T laguerre_polynomial_l_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (abs(x) == T(0.0)) { + return T(1.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return T(1.0) - x; + } + + T p = T(1.0); + T q = T(1.0) - x; + T r; + + for (int64_t k = 1; k < n; k++) { + r = (((k + k) + (T(1.0) - x)) * q - k * p) / (k + 1); + p = q; + q = r; + } + + return r; + } // laguerre_polynomial_l_forward(T x, int64_t n) + + template + T laguerre_polynomial_l_forward(T x, T n) { + return laguerre_polynomial_l_forward(x, static_cast(n)); + } // laguerre_polynomial_l_forward(T x, T n) +); // laguerre_polynomial_l_string + +const auto legendre_polynomial_p_string = jiterator_stringify( + template + T legendre_polynomial_p_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (abs(x) == T(1.0)) { + if (x > T(0.0) || n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x; + } + + T p = T(1.0); + T q = x; + T r; + + for (int64_t k = 1; k < n; k++) { + r = ((k + k + 1) * x * q - k * p) / (k + 1); + p = q; + q = r; + } + + return r; + } // legendre_polynomial_p_forward(T x, int64_t n) + + template + T legendre_polynomial_p_forward(T x, T n) { + return legendre_polynomial_p_forward(x, static_cast(n)); + } // legendre_polynomial_p_forward(T x, T n) +); // legendre_polynomial_p_string + +const auto modified_bessel_i0_string = jiterator_stringify( + template + T modified_bessel_i0_forward(T x) { + static const T A[] = { + -4.41534164647933937950e-18, + +3.33079451882223809783e-17, + -2.43127984654795469359e-16, + +1.71539128555513303061e-15, + -1.16853328779934516808e-14, + +7.67618549860493561688e-14, + -4.85644678311192946090e-13, + +2.95505266312963983461e-12, + -1.72682629144155570723e-11, + +9.67580903537323691224e-11, + -5.18979560163526290666e-10, + +2.65982372468238665035e-09, + -1.30002500998624804212e-08, + +6.04699502254191894932e-08, + -2.67079385394061173391e-07, + +1.11738753912010371815e-06, + -4.41673835845875056359e-06, + +1.64484480707288970893e-05, + -5.75419501008210370398e-05, + +1.88502885095841655729e-04, + -5.76375574538582365885e-04, + +1.63947561694133579842e-03, + -4.32430999505057594430e-03, + +1.05464603945949983183e-02, + -2.37374148058994688156e-02, + +4.93052842396707084878e-02, + -9.49010970480476444210e-02, + +1.71620901522208775349e-01, + -3.04682672343198398683e-01, + +6.76795274409476084995e-01, + }; + + static const T B[] = { + -7.23318048787475395456e-18, + -4.83050448594418207126e-18, + +4.46562142029675999901e-17, + +3.46122286769746109310e-17, + -2.82762398051658348494e-16, + -3.42548561967721913462e-16, + +1.77256013305652638360e-15, + +3.81168066935262242075e-15, + -9.55484669882830764870e-15, + -4.15056934728722208663e-14, + +1.54008621752140982691e-14, + +3.85277838274214270114e-13, + +7.18012445138366623367e-13, + -1.79417853150680611778e-12, + -1.32158118404477131188e-11, + -3.14991652796324136454e-11, + +1.18891471078464383424e-11, + +4.94060238822496958910e-10, + +3.39623202570838634515e-09, + +2.26666899049817806459e-08, + +2.04891858946906374183e-07, + +2.89137052083475648297e-06, + +6.88975834691682398426e-05, + +3.36911647825569408990e-03, + +8.04490411014108831608e-01, + }; + + T p; + T q = 0.0; + + if (abs(x) <= T(8.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 30; index++) { + p = q; + q = a; + a = ((abs(x) / T(2.0)) - T(2.0)) * q - p + A[index]; + } + + return exp(abs(x)) * (T(0.5) * (a - p)); + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(32.0) / abs(x) - T(2.0)) * q - p + B[index]; + } + + return exp(abs(x)) * (T(0.5) * (b - p)) / sqrt(abs(x)); + } // modified_bessel_i0_forward(T x) +); // modified_bessel_i0_string + +const auto modified_bessel_i1_string = jiterator_stringify( + template + T modified_bessel_i1_forward(T x) { + static const T A[] = { + +2.77791411276104639959e-18, + -2.11142121435816608115e-17, + +1.55363195773620046921e-16, + -1.10559694773538630805e-15, + +7.60068429473540693410e-15, + -5.04218550472791168711e-14, + +3.22379336594557470981e-13, + -1.98397439776494371520e-12, + +1.17361862988909016308e-11, + -6.66348972350202774223e-11, + +3.62559028155211703701e-10, + -1.88724975172282928790e-09, + +9.38153738649577178388e-09, + -4.44505912879632808065e-08, + +2.00329475355213526229e-07, + -8.56872026469545474066e-07, + +3.47025130813767847674e-06, + -1.32731636560394358279e-05, + +4.78156510755005422638e-05, + -1.61760815825896745588e-04, + +5.12285956168575772895e-04, + -1.51357245063125314899e-03, + +4.15642294431288815669e-03, + -1.05640848946261981558e-02, + +2.47264490306265168283e-02, + -5.29459812080949914269e-02, + +1.02643658689847095384e-01, + -1.76416518357834055153e-01, + +2.52587186443633654823e-01, + }; + + static const T B[] = { + +7.51729631084210481353e-18, + +4.41434832307170791151e-18, + -4.65030536848935832153e-17, + -3.20952592199342395980e-17, + +2.96262899764595013876e-16, + +3.30820231092092828324e-16, + -1.88035477551078244854e-15, + -3.81440307243700780478e-15, + +1.04202769841288027642e-14, + +4.27244001671195135429e-14, + -2.10154184277266431302e-14, + -4.08355111109219731823e-13, + -7.19855177624590851209e-13, + +2.03562854414708950722e-12, + +1.41258074366137813316e-11, + +3.25260358301548823856e-11, + -1.89749581235054123450e-11, + -5.58974346219658380687e-10, + -3.83538038596423702205e-09, + -2.63146884688951950684e-08, + -2.51223623787020892529e-07, + -3.88256480887769039346e-06, + -1.10588938762623716291e-04, + -9.76109749136146840777e-03, + +7.78576235018280120474e-01, + }; + + T p; + T q = 0.0; + + if (abs(x) <= T(8.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 29; index++) { + p = q; + q = a; + a = ((abs(x) / T(2.0)) - T(2.0)) * q - p + A[index]; + } + + if (x < T(0.0)) { + return -(T(0.5) * (a - p) * abs(x) * exp(abs(x))); + } + + return T(0.5) * (a - p) * abs(x) * exp(abs(x)); + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(32.0) / abs(x) - T(2.0)) * q - p + B[index]; + } + + if (x < T(0.0)) { + return -(exp(abs(x)) * (T(0.5) * (b - p)) / sqrt(abs(x))); + } + + return exp(abs(x)) * (T(0.5) * (b - p)) / sqrt(abs(x)); + } // modified_bessel_i1_forward(T x) +); // modified_bessel_i1_string + +const auto modified_bessel_k0_string = modified_bessel_i0_string + jiterator_stringify( + template + T modified_bessel_k0_forward(T x) { + static const T A[] = { + +1.37446543561352307156e-16, + +4.25981614279661018399e-14, + +1.03496952576338420167e-11, + +1.90451637722020886025e-09, + +2.53479107902614945675e-07, + +2.28621210311945178607e-05, + +1.26461541144692592338e-03, + +3.59799365153615016266e-02, + +3.44289899924628486886e-01, + -5.35327393233902768720e-01, + }; + + static const T B[] = { + +5.30043377268626276149e-18, + -1.64758043015242134646e-17, + +5.21039150503902756861e-17, + -1.67823109680541210385e-16, + +5.51205597852431940784e-16, + -1.84859337734377901440e-15, + +6.34007647740507060557e-15, + -2.22751332699166985548e-14, + +8.03289077536357521100e-14, + -2.98009692317273043925e-13, + +1.14034058820847496303e-12, + -4.51459788337394416547e-12, + +1.85594911495471785253e-11, + -7.95748924447710747776e-11, + +3.57739728140030116597e-10, + -1.69753450938905987466e-09, + +8.57403401741422608519e-09, + -4.66048989768794782956e-08, + +2.76681363944501510342e-07, + -1.83175552271911948767e-06, + +1.39498137188764993662e-05, + -1.28495495816278026384e-04, + +1.56988388573005337491e-03, + -3.14481013119645005427e-02, + +2.44030308206595545468e+00, + }; + + if (x == T(0.0)) { + return INFINITY; + } + + if (x < T(0.0)) { + return NAN; + } + + T p; + T q = 0.0; + + if (x <= T(2.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 10; index++) { + p = q; + q = a; + a = (x * x - T(2.0)) * q - p + A[index]; + } + + return T(0.5) * (a - p) - log(0.5 * x) * modified_bessel_i0_forward(x); + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(8.0) / x - T(2.0)) * q - p + B[index]; + } + + return exp(-x) * (T(0.5) * (b - p)) / sqrt(x); + } // modified_bessel_k0_forward(T x) +); // modified_bessel_k0_string + +const auto scaled_modified_bessel_k0_string = modified_bessel_i0_string + jiterator_stringify( + template + T scaled_modified_bessel_k0_forward(T x) { + static const T A[] = { + +1.37446543561352307156e-16, + +4.25981614279661018399e-14, + +1.03496952576338420167e-11, + +1.90451637722020886025e-09, + +2.53479107902614945675e-07, + +2.28621210311945178607e-05, + +1.26461541144692592338e-03, + +3.59799365153615016266e-02, + +3.44289899924628486886e-01, + -5.35327393233902768720e-01, + }; + + static const T B[] = { + +5.30043377268626276149e-18, + -1.64758043015242134646e-17, + +5.21039150503902756861e-17, + -1.67823109680541210385e-16, + +5.51205597852431940784e-16, + -1.84859337734377901440e-15, + +6.34007647740507060557e-15, + -2.22751332699166985548e-14, + +8.03289077536357521100e-14, + -2.98009692317273043925e-13, + +1.14034058820847496303e-12, + -4.51459788337394416547e-12, + +1.85594911495471785253e-11, + -7.95748924447710747776e-11, + +3.57739728140030116597e-10, + -1.69753450938905987466e-09, + +8.57403401741422608519e-09, + -4.66048989768794782956e-08, + +2.76681363944501510342e-07, + -1.83175552271911948767e-06, + +1.39498137188764993662e-05, + -1.28495495816278026384e-04, + +1.56988388573005337491e-03, + -3.14481013119645005427e-02, + +2.44030308206595545468e+00, + }; + + if (x == T(0.0)) { + return INFINITY; + } + + if (x < T(0.0)) { + return NAN; + } + + T p; + T q = 0.0; + + if (x <= T(2.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 10; index++) { + p = q; + q = a; + a = (x * x - T(2.0)) * q - p + A[index]; + } + + return (T(0.5) * (a - p) - log(T(0.5) * x) * modified_bessel_i0_forward(x)) * exp(x); + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(8.0) / x - T(2.0)) * q - p + B[index]; + } + + return T(0.5) * (b - p) / sqrt(x); + } // T scaled_modified_bessel_k0_forward(T x) +); // scaled_modified_bessel_k0_string + +const auto modified_bessel_k1_string = modified_bessel_i1_string + jiterator_stringify( + template + T modified_bessel_k1_forward(T x) { + static const T A[] = { + -7.02386347938628759343e-18, + -2.42744985051936593393e-15, + -6.66690169419932900609e-13, + -1.41148839263352776110e-10, + -2.21338763073472585583e-08, + -2.43340614156596823496e-06, + -1.73028895751305206302e-04, + -6.97572385963986435018e-03, + -1.22611180822657148235e-01, + -3.53155960776544875667e-01, + +1.52530022733894777053e+00, + }; + + static const T B[] = { + -5.75674448366501715755e-18, + +1.79405087314755922667e-17, + -5.68946255844285935196e-17, + +1.83809354436663880070e-16, + -6.05704724837331885336e-16, + +2.03870316562433424052e-15, + -7.01983709041831346144e-15, + +2.47715442448130437068e-14, + -8.97670518232499435011e-14, + +3.34841966607842919884e-13, + -1.28917396095102890680e-12, + +5.13963967348173025100e-12, + -2.12996783842756842877e-11, + +9.21831518760500529508e-11, + -4.19035475934189648750e-10, + +2.01504975519703286596e-09, + -1.03457624656780970260e-08, + +5.74108412545004946722e-08, + -3.50196060308781257119e-07, + +2.40648494783721712015e-06, + -1.93619797416608296024e-05, + +1.95215518471351631108e-04, + -2.85781685962277938680e-03, + +1.03923736576817238437e-01, + +2.72062619048444266945e+00, + }; + + if (x == T(0.0)) { + return INFINITY; + } + + if (x < T(0.0)) { + return NAN; + } + + T p; + T q = 0.0; + + if (x <= T(2.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 11; index++) { + p = q; + q = a; + a = (x * x - T(2.0)) * q - p + A[index]; + } + + return log(T(0.5) * x) * modified_bessel_i1_forward(x) + T(0.5) * (a - p) / x; + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(8.0) / x - T(2.0)) * q - p + B[index]; + } + + return exp(-x) * (T(0.5) * (b - p)) / sqrt(x); + } // modified_bessel_k1_forward(T x) +); // modified_bessel_k1_string + +const auto scaled_modified_bessel_k1_string = modified_bessel_i1_string + jiterator_stringify( + template + T scaled_modified_bessel_k1_forward(T x) { + static const T A[] = { + -7.02386347938628759343e-18, + -2.42744985051936593393e-15, + -6.66690169419932900609e-13, + -1.41148839263352776110e-10, + -2.21338763073472585583e-08, + -2.43340614156596823496e-06, + -1.73028895751305206302e-04, + -6.97572385963986435018e-03, + -1.22611180822657148235e-01, + -3.53155960776544875667e-01, + +1.52530022733894777053e+00, + }; + + static const T B[] = { + -5.75674448366501715755e-18, + +1.79405087314755922667e-17, + -5.68946255844285935196e-17, + +1.83809354436663880070e-16, + -6.05704724837331885336e-16, + +2.03870316562433424052e-15, + -7.01983709041831346144e-15, + +2.47715442448130437068e-14, + -8.97670518232499435011e-14, + +3.34841966607842919884e-13, + -1.28917396095102890680e-12, + +5.13963967348173025100e-12, + -2.12996783842756842877e-11, + +9.21831518760500529508e-11, + -4.19035475934189648750e-10, + +2.01504975519703286596e-09, + -1.03457624656780970260e-08, + +5.74108412545004946722e-08, + -3.50196060308781257119e-07, + +2.40648494783721712015e-06, + -1.93619797416608296024e-05, + +1.95215518471351631108e-04, + -2.85781685962277938680e-03, + +1.03923736576817238437e-01, + +2.72062619048444266945e+00, + }; + + if (x == T(0.0)) { + return INFINITY; + } + + if (x < T(0.0)) { + return NAN; + } + + T p; + T q = 0.0; + + if (x <= T(2.0)) { + T a = A[0]; + + for (uint8_t index = 1; index < 11; index++) { + p = q; + q = a; + a = (x * x - T(2.0)) * q - p + A[index]; + } + + return (log(T(0.5) * x) * modified_bessel_i1_forward(x) + T(0.5) * (a - p) / x) * exp(x); + } + + T b = B[0]; + + for (uint8_t index = 1; index < 25; index++) { + p = q; + q = b; + b = (T(8.0) / x - T(2.0)) * q - p + B[index]; + } + + return (T(0.5) * (b - p) / sqrt(x)); + } // T scaled_modified_bessel_k1_forward(T x) +); // scaled_modified_bessel_k1_string + +const auto shifted_chebyshev_polynomial_t_string = jiterator_stringify( + template + T shifted_chebyshev_polynomial_t_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (x == T(1.0)) { + return T(1.0); + } + + if (x == T(0.0)) { + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if ((n > 6) && (abs(x + x - T(1.0)) < T(1.0))) { + return cos(n * acos(x + x - T(1.0))); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0); + } + + T p = T(1.0); + T q = x + x - T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x - T(1.0) + (x + x - T(1.0))) * q - p; + p = q; + q = r; + } + + return r; + } // shifted_chebyshev_polynomial_t_forward(T x, int64_t n) + + template + T shifted_chebyshev_polynomial_t_forward(T x, T n) { + return shifted_chebyshev_polynomial_t_forward(x, static_cast(n)); + } // shifted_chebyshev_polynomial_t_forward(T x, T n) +); // shifted_chebyshev_polynomial_t_string + +const auto shifted_chebyshev_polynomial_u_string = jiterator_stringify( + template + T shifted_chebyshev_polynomial_u_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (x == T(1.0)) { + return n + 1; + } + + if (x == T(0.0)) { + if (n % 2 == 0) { + return n + 1; + } + + return -(n + 1); + } + + if ((n > 6) && (abs(x + x - T(1.0)) < T(1.0))) { + if (sin(acos(x + x - T(1.0))) != T(0.0)) { + return sin((n + 1) * acos(x + x - T(1.0))) / sin(acos(x + x - T(1.0))); + } + + return (n + 1) * cos((n + 1) * acos(x + x - T(1.0))) / (x + x - T(1.0)); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0) + (x + x - T(1.0)); + } + + T p = T(1.0); + T q = x + x - T(1.0) + (x + x - T(1.0)); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x - T(1.0) + (x + x - T(1.0))) * q - p; + p = q; + q = r; + } + + return r; + } // shifted_chebyshev_polynomial_u_forward(T x, int64_t n) + + template + T shifted_chebyshev_polynomial_u_forward(T x, T n) { + return shifted_chebyshev_polynomial_u_forward(x, static_cast(n)); + } // shifted_chebyshev_polynomial_u_forward(T x, T n) +); // shifted_chebyshev_polynomial_u_string + +const auto shifted_chebyshev_polynomial_v_string = jiterator_stringify( + template + T shifted_chebyshev_polynomial_v_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (x == T(1.0)) { + return T(1.0); + } + + if (x == T(0.0)) { + if (n % 2 == 0) { + return (n + n + 1); + } + + return -(n + n + 1); + } + + if ((n > 6) && (abs(x + x - T(1.0)) < T(1.0))) { + if (sin(acos(x + x - T(1.0)) / T(2.0)) != T(1.0)) { + return cos(((n) + T(0.5)) * acos(x + x - T(1.0))) / cos(acos(x + x - T(1.0)) / T(2.0)); + } + + if (n % 2 == 0) { + return n + n + 1; + } + + return -(n + n + 1); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0) + (x + x - T(1.0)) - T(1.0); + } + + T p = T(1.0); + T q = x + x - T(1.0) + (x + x - T(1.0)) - T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x - T(1.0) + (x + x - T(1.0))) * q - p; + p = q; + q = r; + } + + return r; + } // shifted_chebyshev_polynomial_v_forward(T x, int64_t n) + + template + T shifted_chebyshev_polynomial_v_forward(T x, T n) { + return shifted_chebyshev_polynomial_v_forward(x, static_cast(n)); + } // shifted_chebyshev_polynomial_v_forward(T x, T n) +); // shifted_chebyshev_polynomial_v_string + +const auto shifted_chebyshev_polynomial_w_string = jiterator_stringify( + template + T shifted_chebyshev_polynomial_w_forward(T x, int64_t n) { + if (n < 0) { + return T(0.0); + } + + if (x == T(1.0)) { + return n + n + 1; + } + + if (x == T(0.0)) { + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if ((n > 4) && (abs(x + x - T(1.0)) < T(1.0))) { + if (cos(acos(x + x - T(1.0)) / T(2.0)) != T(1.0)) { + return sin((n + T(0.5)) * acos(x + x - T(1.0))) / sin(acos(x + x - T(1.0)) / T(2.0)); + } + + if (n % 2 == 0) { + return T(1.0); + } + + return T(-1.0); + } + + if (n == 0) { + return T(1.0); + } + + if (n == 1) { + return x + x - T(1.0) + (x + x - T(1.0)) + T(1.0); + } + + T p = T(1.0); + T q = x + x - T(1.0) + (x + x - T(1.0)) + T(1.0); + T r; + + for (int64_t k = 2; k <= n; k++) { + r = (x + x - T(1.0) + (x + x - T(1.0))) * q - p; + p = q; + q = r; + } + + return r; + } // shifted_chebyshev_polynomial_w_forward(T x, int64_t n) + + template + T shifted_chebyshev_polynomial_w_forward(T x, T n) { + return shifted_chebyshev_polynomial_w_forward(x, static_cast(n)); + } // shifted_chebyshev_polynomial_w_forward(T x, T n) +); // shifted_chebyshev_polynomial_w_string + +const auto spherical_bessel_j0_string = jiterator_stringify( + template + T spherical_bessel_j0_forward(T x) { + if (isinf(x)) { + return T(0.0); + } + + if (abs(x) < T(0.5)) { + return T(1.0) + x * x * (T(-1.0) / T(6.0) + x * x * (T(1.0) / T(120.0) + x * x * (T(-1.0) / T(5040.0) + x * x * (T(1.0) / T(362880.0) + x * x * (T(-1.0) / T(39916800.0) + x * x * (T(1.0) / T(6227020800.0))))))); + } + + return sin(x) / x; + } // T spherical_bessel_j0_forward(T x) +); // spherical_bessel_j0_string + +#else // !AT_USE_JITERATOR() -- kernels must be precompiled + +template +static inline C10_HOST_DEVICE scalar_t calc_gcd(scalar_t a_in, scalar_t b_in) { + scalar_t a = ::abs(a_in); + scalar_t b = ::abs(b_in); + while (a != 0) { + scalar_t c = a; + a = b % a; + b = c; + } + return b; +} + +/* + * For licensing information, please refer to the cpu implementation located in "ATen/native/Math.h". + */ +template +static inline C10_HOST_DEVICE scalar_t calc_digamma(scalar_t in) { + // [C++ Standard Reference: Gamma Function] https://en.cppreference.com/w/cpp/numeric/math/tgamma + using accscalar_t = at::acc_type; + static const double PI_f64 = 3.14159265358979323846; + const accscalar_t PSI_10 = 2.25175258906672110764; + const accscalar_t A[] = { + 8.33333333333333333333E-2, + -2.10927960927960927961E-2, + 7.57575757575757575758E-3, + -4.16666666666666666667E-3, + 3.96825396825396825397E-3, + -8.33333333333333333333E-3, + 8.33333333333333333333E-2, + }; + + accscalar_t x = static_cast(in); + if (x == 0) { + // As per C++ standard for gamma related functions and SciPy, + // If the argument is ±0, ±∞ is returned + return std::copysign(static_cast(INFINITY), -x); + } + + bool x_is_integer = x == ::trunc(x); + accscalar_t result = 0; + if (x < 0) { + if (x_is_integer) { + // As per C++ standard for gamma related functions and SciPy, + // If the argument is a negative integer, NaN is returned + return static_cast(NAN); + } + // Extracts the fractional part of x as r, since tan(pi * r) is more numerically + // accurate than tan(pi * x). While these operations are mathematically equivalent + // since both x and r are in radians and tan() has a periodicity of pi, in practice + // the computation of pi * x is a source of error (when |x| > 1). + double q, r; + r = ::modf(static_cast(x), &q); + result = static_cast(- PI_f64 / ::tan(PI_f64 * r)); + x = 1 - x; + } + + while (x < 10) { + result -= 1 / x; + x += 1; + } + if (x == 10) { + return static_cast(result + PSI_10); + } + + accscalar_t y = 0; + if (x < 1.0e17) { + accscalar_t z = 1 / (x * x); + + accscalar_t polevl_result = 0; + for (int i = 0; i <= 6; i++) { + polevl_result = polevl_result * z + A[i]; + } + y = z * polevl_result; + } + + return static_cast(::log(x) - (static_cast(0.5) / x) - y + result); +} + +template +static inline C10_HOST_DEVICE scalar_t calc_trigamma(scalar_t in) { + using accscalar_t = at::acc_type; + const accscalar_t PI = 3.14159265358979323846; + accscalar_t x = static_cast(in); + accscalar_t sign = +1; + accscalar_t result = 0; + if (x < 0.5f) { + sign = -1; + accscalar_t sin_pi_x = ::sin(PI * x); + result -= (PI * PI) / (sin_pi_x * sin_pi_x); + x = 1 - x; + } + for (int i = 0; i < 6; ++i) { + result += 1 / (x * x); + x += 1; + } + const accscalar_t one = static_cast(1); + const accscalar_t ixx = 1 / (x*x); + result += (1 + 1 / (2*x) + ixx * (one/6 - ixx * (one/30 - ixx * (one/42)))) / x; + return static_cast(sign * result); +} + +/* + * For licensing information and documentation, please refer to the cpu implementation located in "ATen/native/Math.h". + */ +template +static inline C10_HOST_DEVICE scalar_t +chbevl(scalar_t _x, const scalar_t array[], size_t len) { + static_assert(!std::is_same() && !std::is_same(), "don't instantiate with low precision type"); + + scalar_t b0, b1, b2; + + b0 = array[0]; + b1 = 0; + + for (size_t i = 1; i < len; ++i) { + b2 = b1; + b1 = b0; + b0 = _x * b1 - b2 + array[i]; + } + + return (0.5 * (b0 - b2)); +} + +/* + * For licensing information and documentation, please refer to the cpu implementation located in "ATen/native/Math.h". + */ +template +C10_HOST_DEVICE inline std::tuple chebyshev_coefficients_i0e_A() { + /* Chebyshev coefficients for exp(-x) I0(x) + * in the interval [0,8]. + * + * lim(x->0){ exp(-x) I0(x) } = 1. + */ + static const T coefficients[] = { + -4.41534164647933937950E-18, 3.33079451882223809783E-17, + -2.43127984654795469359E-16, 1.71539128555513303061E-15, + -1.16853328779934516808E-14, 7.67618549860493561688E-14, + -4.85644678311192946090E-13, 2.95505266312963983461E-12, + -1.72682629144155570723E-11, 9.67580903537323691224E-11, + -5.18979560163526290666E-10, 2.65982372468238665035E-9, + -1.30002500998624804212E-8, 6.04699502254191894932E-8, + -2.67079385394061173391E-7, 1.11738753912010371815E-6, + -4.41673835845875056359E-6, 1.64484480707288970893E-5, + -5.75419501008210370398E-5, 1.88502885095841655729E-4, + -5.76375574538582365885E-4, 1.63947561694133579842E-3, + -4.32430999505057594430E-3, 1.05464603945949983183E-2, + -2.37374148058994688156E-2, 4.93052842396707084878E-2, + -9.49010970480476444210E-2, 1.71620901522208775349E-1, + -3.04682672343198398683E-1, 6.76795274409476084995E-1}; + + return std::make_tuple(coefficients, 30); +} + +template +C10_HOST_DEVICE inline std::tuple chebyshev_coefficients_i0e_B() { + /* Chebyshev coefficients for exp(-x) sqrt(x) I0(x) + * in the inverted interval [8,infinity]. + * + * lim(x->inf){ exp(-x) sqrt(x) I0(x) } = 1/sqrt(2pi). + */ + static const T coefficients[] = { + -7.23318048787475395456E-18, -4.83050448594418207126E-18, + 4.46562142029675999901E-17, 3.46122286769746109310E-17, + -2.82762398051658348494E-16, -3.42548561967721913462E-16, + 1.77256013305652638360E-15, 3.81168066935262242075E-15, + -9.55484669882830764870E-15, -4.15056934728722208663E-14, + 1.54008621752140982691E-14, 3.85277838274214270114E-13, + 7.18012445138366623367E-13, -1.79417853150680611778E-12, + -1.32158118404477131188E-11, -3.14991652796324136454E-11, + 1.18891471078464383424E-11, 4.94060238822496958910E-10, + 3.39623202570838634515E-9, 2.26666899049817806459E-8, + 2.04891858946906374183E-7, 2.89137052083475648297E-6, + 6.88975834691682398426E-5, 3.36911647825569408990E-3, + 8.04490411014108831608E-1}; + + return std::make_tuple(coefficients, 25); +} + +template +static inline C10_HOST_DEVICE scalar_t calc_i0(scalar_t _x) { + static_assert(!std::is_same() && !std::is_same(), "don't instantiate with low precision type"); + // Upcast input for numerical accuracy purposes + // Needed for accurate results if input is bfloat16 or float16 + scalar_t x = ::abs(_x); + + if (x <= scalar_t{8.0}) { + auto [A, len] = chebyshev_coefficients_i0e_A(); + scalar_t y = (x / scalar_t{2.0}) - scalar_t{2.0}; + return (::exp(x) * chbevl(y, A, len)); + } + + auto [B, len] = chebyshev_coefficients_i0e_B(); + return (::exp(x) * chbevl(scalar_t{32.0} / x - scalar_t{2.0}, B, len) / ::sqrt(x)); +} + +template +C10_HOST_DEVICE inline + typename std::enable_if_t, std::tuple> + chebyshev_coefficients_i1e_A() { + /* Chebyshev coefficients for exp(-x) I1(x) + * in the interval [0,8]. + * + * lim(x->0){ exp(-x) I1(x) / x } = 1/2. + */ + static const T coefficients[] = { + 2.77791411276104639959E-18, -2.11142121435816608115E-17, + 1.55363195773620046921E-16, -1.10559694773538630805E-15, + 7.60068429473540693410E-15, -5.04218550472791168711E-14, + 3.22379336594557470981E-13, -1.98397439776494371520E-12, + 1.17361862988909016308E-11, -6.66348972350202774223E-11, + 3.62559028155211703701E-10, -1.88724975172282928790E-9, + 9.38153738649577178388E-9, -4.44505912879632808065E-8, + 2.00329475355213526229E-7, -8.56872026469545474066E-7, + 3.47025130813767847674E-6, -1.32731636560394358279E-5, + 4.78156510755005422638E-5, -1.61760815825896745588E-4, + 5.12285956168575772895E-4, -1.51357245063125314899E-3, + 4.15642294431288815669E-3, -1.05640848946261981558E-2, + 2.47264490306265168283E-2, -5.29459812080949914269E-2, + 1.02643658689847095384E-1, -1.76416518357834055153E-1, + 2.52587186443633654823E-1}; + + return std::make_tuple(coefficients, 29); +} + +template +C10_HOST_DEVICE inline + typename std::enable_if_t, std::tuple> + chebyshev_coefficients_i1e_A() { + /* Chebyshev coefficients for exp(-x) I1(x) + * in the interval [0,8]. + * + * lim(x->0){ exp(-x) I1(x) / x } = 1/2. + */ + static const T coeff[] = { + 9.38153738649577178388E-9f, + -4.44505912879632808065E-8f, + 2.00329475355213526229E-7f, + -8.56872026469545474066E-7f, + 3.47025130813767847674E-6f, + -1.32731636560394358279E-5f, + 4.78156510755005422638E-5f, + -1.61760815825896745588E-4f, + 5.12285956168575772895E-4f, + -1.51357245063125314899E-3f, + 4.15642294431288815669E-3f, + -1.05640848946261981558E-2f, + 2.47264490306265168283E-2f, + -5.29459812080949914269E-2f, + 1.02643658689847095384E-1f, + -1.76416518357834055153E-1f, + 2.52587186443633654823E-1f}; + return std::make_tuple(coeff, 17); +}; + +template +C10_HOST_DEVICE inline + typename std::enable_if_t, std::tuple> + chebyshev_coefficients_i1e_B() { + /* Chebyshev coefficients for exp(-x) sqrt(x) I1(x) + * in the inverted interval [8,infinity]. + * + * lim(x->inf){ exp(-x) sqrt(x) I1(x) } = 1/sqrt(2pi). + */ + static const T coefficients[] = { + 7.51729631084210481353E-18, 4.41434832307170791151E-18, + -4.65030536848935832153E-17, -3.20952592199342395980E-17, + 2.96262899764595013876E-16, 3.30820231092092828324E-16, + -1.88035477551078244854E-15, -3.81440307243700780478E-15, + 1.04202769841288027642E-14, 4.27244001671195135429E-14, + -2.10154184277266431302E-14, -4.08355111109219731823E-13, + -7.19855177624590851209E-13, 2.03562854414708950722E-12, + 1.41258074366137813316E-11, 3.25260358301548823856E-11, + -1.89749581235054123450E-11, -5.58974346219658380687E-10, + -3.83538038596423702205E-9, -2.63146884688951950684E-8, + -2.51223623787020892529E-7, -3.88256480887769039346E-6, + -1.10588938762623716291E-4, -9.76109749136146840777E-3, + 7.78576235018280120474E-1}; + + return std::make_tuple(coefficients, 25); +} + +template +C10_HOST_DEVICE inline + typename std::enable_if_t, std::tuple> + chebyshev_coefficients_i1e_B() { + /* Chebyshev coefficients for exp(-x) sqrt(x) I1(x) + * in the inverted interval [8,infinity]. + * + * lim(x->inf){ exp(-x) sqrt(x) I1(x) } = 1/sqrt(2pi). + */ + static const T coeff[] = { + -3.83538038596423702205E-9f, + -2.63146884688951950684E-8f, + -2.51223623787020892529E-7f, + -3.88256480887769039346E-6f, + -1.10588938762623716291E-4f, + -9.76109749136146840777E-3f, + 7.78576235018280120474E-1f}; + + return std::make_tuple(coeff, 7); +}; + +template +static inline C10_HOST_DEVICE scalar_t calc_i1(scalar_t _x) { + const auto x = ::abs(_x); + if (x <= scalar_t{8.0}) { + auto [A, len] = chebyshev_coefficients_i1e_A(); + scalar_t y = x / scalar_t{2.0} - scalar_t{2.0}; + const scalar_t out = ::exp(x) * x * chbevl(y, A, len); + return (_x < scalar_t{0.0}) ? -out : out; + } + + auto [B, len] = chebyshev_coefficients_i1e_B(); + const scalar_t out = (::exp(x) * chbevl(scalar_t{32.0} / x - scalar_t{2.0}, B, len)) / ::sqrt(x); + return (_x < scalar_t{0.0}) ? -out : out; +} + +template +static inline C10_HOST_DEVICE scalar_t calc_i1e(scalar_t _x) { + const auto x = ::abs(_x); + if (x <= scalar_t{8.0}) { + auto [A, len] = chebyshev_coefficients_i1e_A(); + const scalar_t y = x / scalar_t{2.0} - scalar_t{2.0}; + const scalar_t out = chbevl(y, A, len) * x; + return (_x < scalar_t{0.0}) ? -out : out; + } + + auto [B, len] = chebyshev_coefficients_i1e_B(); + const scalar_t out = chbevl(scalar_t{32.0} / x - scalar_t{2.0}, B, len) / ::sqrt(x); + return (_x < scalar_t{0.0}) ? -out : out; +} + +#endif // AT_USE_JITERATOR() (this closes the "else" branch of a if/else preprocessor directive) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/MemoryAccess.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/MemoryAccess.cuh new file mode 100644 index 0000000000000000000000000000000000000000..4a00d714a0c7f092c4654515092827062e0b1bb1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/MemoryAccess.cuh @@ -0,0 +1,404 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include + +// References: +// https://devblogs.nvidia.com/cuda-pro-tip-increase-performance-with-vectorized-memory-access/ + +namespace at::native::memory { + +namespace detail { + +// What does the `static_unroll` do? +// +// We want to do something like: +// +// using args_t = typename traits::ArgsTuple; +// args_t args; +// #pragma unroll +// for (int i = 0; i < traits::arity; i++) { +// std::get(args) = .... +// } +// +// but unfortunately the above code does not work because +// the template argument has to be a compile time constant +// so `static_unroll` is created to simulate `#pragma unroll` +// using template metaprogramming. + +template typename func, int end, int current=0> +struct static_unroll { + template + static inline C10_HOST_DEVICE void with_args(Args&&... args) { + func::apply(std::forward(args)...); + static_unroll::with_args(args...); + } +}; + +template typename func, int end> +struct static_unroll { + template + static inline C10_HOST_DEVICE void with_args(Args... args) {} +}; + +// helper structs to be used with static_unroll to load arguments +// one by one + +template +struct vectorized_load_helper { + template + static __device__ void apply(policy_t &self, args_t *args, int idx, int block_work_size) { + using arg_t = std::tuple_element_t; + // `data` hold the data_ptr for tensors [output, input0, input1, ...], so we + // need a +1 offset to get the input + auto ptr = reinterpret_cast(self.data[arg_index + 1]) + block_work_size * idx; + auto args_accessor = [&args] __device__ (int thread_unroll_idx) -> arg_t & { return std::get(args[thread_unroll_idx]); }; + self.load_single_arg(args_accessor, ptr); + } +}; + +template +struct unroll_load_helper { + template + static __device__ void apply(policy_t &self, args_t *args, offset_t offset, loader_t loader, int j, int num_outputs) { + using arg_t = std::tuple_element_t; + // `data` hold the data_ptr for tensors [output, input0, input1, ...], so we + // need a +1 offset to get the input + std::get(args[j]) = loader.template load(self.data[arg_index + num_outputs], offset[arg_index], arg_index); + } +}; + +template +struct multi_outputs_store_helper { + template + C10_HOST_DEVICE static void apply( + const data_t& data, + const offsets_t& offsets, + thrust::tuple ret) { + using T = typename thrust::tuple_element>::type; + T *to = reinterpret_cast(data[current]) + offsets[current]; + *to = thrust::get(ret); + } +}; + +} // namespace detail + +struct LoadWithoutCast { + template + __device__ scalar_t load(char *base_ptr, uint32_t offset, int arg) { + return c10::load(reinterpret_cast(base_ptr) + offset); + } +}; + +template +struct LoadWithCast { + using array_t = std::array(N, 1)>; + using size_array_t = std::array(N, 1)>; + + array_t dtypes; + size_array_t element_sizes; + + LoadWithCast(const TensorIteratorBase& iter) { + CUDA_KERNEL_ASSERT(iter.ninputs() == N); + #pragma unroll + for (auto i = 0; i < N; ++i) { + this->dtypes[i] = iter.dtype(i + iter.noutputs()); + element_sizes[i] = c10::elementSize(iter.dtype(i + iter.noutputs())); + } + } + + template + __device__ scalar_t load(char *base_ptr, uint32_t offset, int arg) { + void *ptr = base_ptr + element_sizes[arg] * offset; + return c10::fetch_and_cast(dtypes[arg], ptr); + } +}; + +struct StoreWithoutCast { + template + __device__ void store(scalar_t value, char *base_ptr, uint32_t offset, int arg = 0) { + *(reinterpret_cast(base_ptr) + offset) = value; + } +}; + +template +struct StoreWithCast { + using array_t = std::array(N, 1)>; + using size_array_t = std::array(N, 1)>; + + array_t dtypes; + size_array_t element_sizes; + + StoreWithCast(const TensorIteratorBase& iter) { + CUDA_KERNEL_ASSERT(iter.noutputs() == N); + #pragma unroll + for (auto i = 0; i < N; ++i) { + this->dtypes[i] = iter.dtype(i); + element_sizes[i] = c10::elementSize(iter.dtype(i)); + } + } + + template + __device__ void store(scalar_t value, char *base_ptr, uint32_t offset, int arg = 0) { + void *ptr = base_ptr + element_sizes[arg] * offset; + c10::cast_and_store(dtypes[arg], ptr, value); + } +}; + +// aligned vector generates vectorized load/store on CUDA +template +struct alignas(sizeof(scalar_t) * vec_size) aligned_vector { + scalar_t val[vec_size]; +}; + +template +__device__ aligned_vector load_vector(const scalar_t *base_ptr, uint32_t offset) { + using vec_t = aligned_vector; + auto *from = reinterpret_cast(base_ptr); + return from[offset]; +} + +template +__device__ aligned_vector load_vector(const bool *base_ptr, uint32_t offset) { + // See NOTE [Loading boolean values] + auto tmp = load_vector(reinterpret_cast(base_ptr), offset); + aligned_vector ret; + for (int i = 0; i < vec_size; ++i) { + ret.val[i] = bool(tmp.val[i]); + } + return ret; +} + +namespace policies { + +template +struct unroll { + + data_t data; + int remaining; + inp_calc_t input_offset_calculator; + out_calc_t output_offset_calculator; + loader_t loader; + storer_t storer; + static constexpr int tws = elems_per_thread; + + __device__ unroll(data_t data, int remaining, inp_calc_t ic, out_calc_t oc, loader_t l, storer_t s): + data(data), remaining(remaining), input_offset_calculator(ic), output_offset_calculator(oc), loader(l), storer(s) {} + + __device__ inline bool check_inbounds(int thread_work_elem) { + return ((int)(threadIdx.x + thread_work_elem*num_threads()) < remaining); + } + + template + __device__ inline void load(args_t *args, int idx) { + constexpr int arity = std::tuple_size_v; + int thread_idx = threadIdx.x; + #pragma unroll + for (int i = 0; i < elems_per_thread; i++) { + if (thread_idx >= remaining) { + return; + } + int linear_idx = thread_idx + elems_per_thread * num_threads() * idx; + auto offset = input_offset_calculator.get(linear_idx); + detail::static_unroll::with_args(*this, args, offset, loader, i, num_outputs); + thread_idx += num_threads(); + } + } + + template + __device__ inline void store(scalar_t *from, int idx) { + int thread_idx = threadIdx.x; + #pragma unroll + for (int i = 0; i < elems_per_thread; i++) { + if (thread_idx >= remaining) { + return; + } + int linear_idx = thread_idx + elems_per_thread * num_threads() * idx; + int offset = output_offset_calculator.get(linear_idx)[0]; + storer.store(from[i], data[0], offset); + thread_idx += num_threads(); + } + } +}; + +// Assumption: +// all tensors are contiguous, that is: stride == sizeof(type) for all tensors +// Note: +// Functions in vectorized policy does not do boundary check. It assumes the whole block +// has its job to do. So the reminders should be handled by the caller manually. +template // vec_size: number of scalars, can be 1, 2, or 4. +struct vectorized { + + static_assert(elems_per_thread % vec_size == 0, "The workload per thread must be a multiple of vec_size"); + static constexpr int loop_size = elems_per_thread / vec_size; + static constexpr int tws = elems_per_thread; + + data_t data; + + __device__ vectorized(data_t data) : data(data) {} + + __device__ inline constexpr bool check_inbounds(int thread_work_elem) { + return true; + } + + template + __device__ inline void load_single_arg(accessor_t to, scalar_t *from) { + int thread_idx = threadIdx.x; + #pragma unroll + for (int i = 0; i < loop_size; i++) { + int index = thread_idx + i * num_threads(); + auto v = load_vector(from, index); + #pragma unroll + for (int j = 0; j < vec_size; j++) { + to(vec_size * i + j) = v.val[j]; + } + } + } + + template + __device__ inline void load(args_t *args, int idx) { + constexpr int arity = std::tuple_size_v; + detail::static_unroll::with_args(*this, args, idx, elems_per_thread * num_threads()); + } + + template + __device__ inline void store(scalar_t *from, int idx) { + using vec_t = aligned_vector; + scalar_t *to = reinterpret_cast(data[0]) + elems_per_thread * num_threads() * idx; + vec_t *to_ = reinterpret_cast(to); + int thread_idx = threadIdx.x; + #pragma unroll + for (int i = 0; i < loop_size; i++) { + int index = thread_idx + i * num_threads(); + vec_t v; + for (int j = 0; j < vec_size; j++) { + v.val[j] = from[vec_size * i + j]; + } + to_[index] = v; + } + } +}; + +template +struct multi_outputs_unroll { + //multi_outputs_unroll struct members and check_inbounds and load methods are copypasted from unroll struct + //we don't use inheritance because of compiler bug in cuda 10.2+ + data_t data; + int remaining; + inp_calc_t input_offset_calculator; + out_calc_t output_offset_calculator; + LoadWithoutCast loader; + StoreWithoutCast storer; + static constexpr int tws = thread_work_size(); + + __device__ multi_outputs_unroll(data_t data, int remaining, inp_calc_t ic, out_calc_t oc): + data(data), remaining(remaining), input_offset_calculator(ic), output_offset_calculator(oc) {} + + __device__ inline bool check_inbounds(int thread_work_elem) { + return ((int)(threadIdx.x + thread_work_elem*num_threads()) < remaining); + } + + template + __device__ inline void load(args_t *args, int idx) { + constexpr int arity = std::tuple_size_v; + int thread_idx = threadIdx.x; + #pragma unroll + for (int i = 0; i < thread_work_size(); i++) { + if (thread_idx >= remaining) { + return; + } + int linear_idx = thread_idx + block_work_size() * idx; + auto offset = input_offset_calculator.get(linear_idx); + detail::static_unroll::with_args(*this, args, offset, loader, i, num_outputs); + thread_idx += num_threads(); + } + } + + + template + __device__ inline void store(return_t *from, int idx) { + int thread_idx = threadIdx.x; + #pragma unroll + for (int i = 0; i < thread_work_size(); i++) { + if (thread_idx >= this->remaining) { + return; + } + int linear_idx = thread_idx + block_work_size() * idx; + auto offsets = this->output_offset_calculator.get(linear_idx); + memory::detail::static_unroll::with_args(this->data, offsets, from[i]); + thread_idx += num_threads(); + } + } +}; + +} // namespace policies + +// This is only used in host, but we will wrap this into some templates +// which is C10_HOST_DEVICE, so we have to make this C10_HOST_DEVICE +// in order to compile +template +inline C10_HOST_DEVICE int can_vectorize_up_to(const char *pointer) { + uint64_t address = reinterpret_cast(pointer); + constexpr int vec2_alignment = std::alignment_of_v>; + constexpr int vec4_alignment = std::alignment_of_v>; + constexpr int vec8_alignment = std::alignment_of_v>; +#ifdef USE_ROCM + constexpr int vec16_alignment = std::alignment_of_v>; + constexpr int type_size = sizeof(scalar_t); + if (type_size == 1 && (address % vec16_alignment == 0)) { + return 16; + } else if (type_size <= 2 && (address % vec8_alignment == 0)) { + return 8; + } else +#else + if (address % vec8_alignment == 0) { + return 8; + } else +#endif + if (address % vec4_alignment == 0) { + return 4; + } else if (address % vec2_alignment == 0) { + return 2; + } + return 1; +} + +template +inline C10_HOST_DEVICE int can_vectorize_up_to(char *pointer) { + return can_vectorize_up_to(static_cast(pointer)); +} + +template +struct can_vectorize_up_to_helper { + template + static C10_HOST_DEVICE void apply(int &result, array_t pointers, traits _) { + using arg_t = typename traits::template arg::type; + // `pointers` hold the data_ptr for tensors [output, input0, input1, ...], so we + // need a +1 offset to get the input + result = std::min(result, can_vectorize_up_to(pointers[i + 1])); + } +}; + +template +inline int can_vectorize_up_to(array_t pointers) { + using traits = function_traits; + using return_t = typename traits::result_type; + constexpr int arity = traits::arity; + int result = can_vectorize_up_to(pointers[0]); + // We need to get the type for each argument of `func_t`, this can only + // be done at compile time. + detail::static_unroll::with_args(result, pointers, traits()); + return result; +} + +} // namespace at::native::memory diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/MiscUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/MiscUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..e616a7d1fcfb8254528dccc4e6b9d0658ffe1a3c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/MiscUtils.h @@ -0,0 +1,32 @@ +#pragma once +#include +#include +#include +#include + +namespace at { +namespace native { + +static inline int cuda_int_cast(int64_t value, const char* varname) { + auto result = static_cast(value); + TORCH_CHECK(static_cast(result) == value, + "cuda_int_cast: The value of ", varname, "(", (long long)value, + ") is too large to fit into a int (", sizeof(int), " bytes)"); + return result; +} + +// Creates an array of size elements of type T, backed by pinned memory +// wrapped in a Storage +template +static inline Storage pin_memory(int64_t size) { + auto* allocator = cuda::getPinnedMemoryAllocator(); + int64_t adjusted_size = size * sizeof(T); + return Storage( + Storage::use_byte_size_t(), + adjusted_size, + allocator, + /*resizable=*/false); +} + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/MultiTensorApply.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/MultiTensorApply.cuh new file mode 100644 index 0000000000000000000000000000000000000000..2fe431f778b1a299e104e0bd79499096fc47a4dc --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/MultiTensorApply.cuh @@ -0,0 +1,382 @@ +#pragma once +#include +#include +#include +#include +#include +#include + +namespace at::native { + +namespace { + +static constexpr int64_t kILP = 4; +static constexpr int64_t kChunkSize = 65536; +static constexpr int64_t kBlockSize = 512; + +// TODO(crcrpar): Add `n>5` for `low prec params & their higher prec copy` +// TensorListMetadata has to be < 4KB - the limit for kernel launch argument +static constexpr int depth_to_max_tensors[5] = {110, 64, 48, 36, 30}; +static constexpr int depth_to_max_blocks[5] = {320, 320, 320, 320, 320}; +static constexpr int depth_to_max_tensors_scalarlist[5] = {96, 64, 48, 36, 30}; +static constexpr int depth_to_max_tensors_scalarlist_of_complex_double[2] = { + 72, + 60}; + +template +__device__ __forceinline__ bool is_aligned(T* p) { + return ((uint64_t)p) % (kILP * sizeof(T)) == 0; +} + +template +__device__ __forceinline__ void load_store( + T* dst, + T* src, + int64_t dst_offset, + int64_t src_offset) { + using LT = at::native::memory::aligned_vector; + ((LT*)dst)[dst_offset] = ((LT*)src)[src_offset]; +} + +template +struct TensorListMetadata { + const void* addresses[n][depth_to_max_tensors[n - 1]]; + int64_t numel_for_tensor[depth_to_max_tensors[n - 1]]; + unsigned char block_to_tensor[depth_to_max_blocks[n - 1]]; + int block_to_chunk[depth_to_max_blocks[n - 1]]; + int start_tensor_this_launch; +}; + +template +struct TensorListScalarListMetadata { + const void* addresses[n][depth_to_max_tensors_scalarlist[n - 1]]; + int64_t numel_for_tensor[depth_to_max_tensors_scalarlist[n - 1]]; + scalar_vals_t scalar_vals[depth_to_max_tensors_scalarlist[n - 1]]; + unsigned char block_to_tensor[depth_to_max_blocks[n - 1]]; + int block_to_chunk[depth_to_max_blocks[n - 1]]; +}; + +// note(mkozuki): `n` of 1&2 violate the limit of cuda kernel argument size of +// 4kb with `c10::complex` +template <> +struct TensorListScalarListMetadata, 1> { + const void* addresses[1] + [depth_to_max_tensors_scalarlist_of_complex_double[0]]; + int64_t + numel_for_tensor[depth_to_max_tensors_scalarlist_of_complex_double[0]]; + c10::complex + scalar_vals[depth_to_max_tensors_scalarlist_of_complex_double[0]]; + unsigned char block_to_tensor[depth_to_max_blocks[1 - 1]]; + int block_to_chunk[depth_to_max_blocks[1 - 1]]; +}; + +template <> +struct TensorListScalarListMetadata, 2> { + const void* addresses[2] + [depth_to_max_tensors_scalarlist_of_complex_double[1]]; + int64_t + numel_for_tensor[depth_to_max_tensors_scalarlist_of_complex_double[1]]; + c10::complex + scalar_vals[depth_to_max_tensors_scalarlist_of_complex_double[1]]; + unsigned char block_to_tensor[depth_to_max_blocks[2 - 1]]; + int block_to_chunk[depth_to_max_blocks[2 - 1]]; +}; + +// NOTE(crcrpar): This is a conservative resolution to handle `state_steps` +// whose each element is `at::Tensor` of 1 element representing the number of +// `step`s called so far. +template +struct FusedOptimizerTensorListMetadata { + const void* addresses[n][depth_to_max_tensors[n - 1]]; + int64_t numel_for_tensor[depth_to_max_tensors[n - 1]]; + const void* state_steps_addresses[depth_to_max_tensors_scalarlist[n - 1]]; + unsigned char block_to_tensor[depth_to_max_blocks[n - 1]]; + int block_to_chunk[depth_to_max_blocks[n - 1]]; + int start_tensor_this_launch; +}; + +template +C10_LAUNCH_BOUNDS_1(kBlockSize) +__global__ void multi_tensor_apply_kernel( + T tensorListMeta, + U callable, + ArgTypes... args) { + // Hand the chunk information to the user-supplied functor to process however + // it likes. + callable(kChunkSize, tensorListMeta, args...); +} + +} // namespace + +// multi_tensor_apply enables horizontal fusion across lists of tensors. +// For example, whereas you once had a for-loop of a + b = c, where a, b, +// and c are individual tensors in lists as, bs, and cs, you can now with +// fewer kernel launches compute as + bs = cs. +// +// You can also imagine bs to be a scalar list vs a tensor list. +// +// The function below takes in tensor lists, scalars, and a callable and +// chunks up the computation to launch as few kernels as possible by iterating +// through every "chunk" in every tensor (thus the nested for loops). In the +// simplest case, everything gets bundled into just one kernel launch, but +// due to blocksize constraints, we may need to launch multiple kernels. +// Each kernel launch is defined by one tensorListMeta construct, which we +// use to track and reset the necessary metadata for each launch. +template +void multi_tensor_apply( + std::vector>& tensor_lists, + at::ArrayRef scalars, + T callable, + ArgTypes... args) { + TORCH_CHECK( + tensor_lists.size() == depth, + "Number of tensor lists has to match the depth."); + const size_t n_tensors = tensor_lists[0].size(); + using scalar_vals_t = typename T::opmath_t; + TensorListScalarListMetadata tensorListMeta; + + int loc_block_info = 0; + int loc_tensor_info = 0; + for (size_t t = 0; t < n_tensors; t++) { + // short-circuit to avoid adding empty tensors to tensorListMeta + if (tensor_lists[0][t].numel() == 0) { + continue; + } + tensorListMeta.scalar_vals[loc_tensor_info] = scalars[t].to(); + tensorListMeta.numel_for_tensor[loc_tensor_info] = + tensor_lists[0][t].numel(); + for (int d = 0; d < depth; d++) { + tensorListMeta.addresses[d][loc_tensor_info] = + tensor_lists[d][t].const_data_ptr(); + } + loc_tensor_info++; + + // now we enter [chunking territory]. + // we will launch a kernel when EITHER the blocks get filled up OR + // the tensors get filled up. There will always be at least one block + // per tensor since the zero-sized ones will not enter the loop, so + // the nested forloop within represents iterating through the chunks + // of a single tensor. + const auto numel = tensor_lists[0][t].numel(); + const auto chunks = numel / kChunkSize + (numel % kChunkSize != 0); + for (auto chunk = 0; chunk < chunks; chunk++) { + tensorListMeta.block_to_tensor[loc_block_info] = loc_tensor_info - 1; + tensorListMeta.block_to_chunk[loc_block_info] = chunk; + loc_block_info++; + + // a tensor is not considered full unless all its chunks have been + // processed + const bool tensors_full = + (loc_tensor_info == depth_to_max_tensors_scalarlist[depth - 1] && + chunk == chunks - 1); + const bool blocks_full = + (loc_block_info == depth_to_max_blocks[depth - 1]); + + if (tensors_full || blocks_full) { + multi_tensor_apply_kernel<<< + loc_block_info, + kBlockSize, + 0, + at::cuda::getCurrentCUDAStream()>>>( + tensorListMeta, callable, args...); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + + // Reset. + loc_block_info = 0; + // all chunks have already been handled in the kernel + if (chunk == chunks - 1) { + loc_tensor_info = 0; + } else { // blocks were full and tensor chunks remain + tensorListMeta.numel_for_tensor[0] = + tensorListMeta.numel_for_tensor[loc_tensor_info - 1]; + tensorListMeta.scalar_vals[0] = + tensorListMeta.scalar_vals[loc_tensor_info - 1]; + for (int d = 0; d < depth; d++) { + tensorListMeta.addresses[d][0] = + tensorListMeta.addresses[d][loc_tensor_info - 1]; + } + loc_tensor_info = 1; + } + } + } + } + + // note: [finishing what we started] + // if there's remaining work to be done but the tensors/blocks aren't full + // yet we are at the end, submit the kernel to do the work! + if (loc_block_info != 0) { + multi_tensor_apply_kernel<<< + loc_block_info, + kBlockSize, + 0, + at::cuda::getCurrentCUDAStream()>>>(tensorListMeta, callable, args...); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } +} + +template +void multi_tensor_apply( + std::vector>& tensor_lists, + T callable, + ArgTypes... args) { + TORCH_CHECK( + tensor_lists.size() == depth, + "Number of tensor lists has to match the depth."); + const size_t n_tensors = tensor_lists[0].size(); + TensorListMetadata tensorListMeta; + tensorListMeta.start_tensor_this_launch = 0; + + int loc_block_info = 0; + int loc_tensor_info = 0; + int processed = 0; + + for (size_t t = 0; t < n_tensors; t++) { + // short-circuit to avoid adding empty tensors to tensorListMeta + if (tensor_lists[0][t].numel() == 0) { + continue; + } + processed++; + tensorListMeta.numel_for_tensor[loc_tensor_info] = + tensor_lists[0][t].numel(); + for (int d = 0; d < depth; d++) { + tensorListMeta.addresses[d][loc_tensor_info] = + tensor_lists[d][t].const_data_ptr(); + } + loc_tensor_info++; + + // see note: [chunking territory]. + const auto numel = tensor_lists[0][t].numel(); + const auto chunks = numel / kChunkSize + (numel % kChunkSize != 0); + for (auto chunk = 0; chunk < chunks; chunk++) { + tensorListMeta.block_to_tensor[loc_block_info] = loc_tensor_info - 1; + tensorListMeta.block_to_chunk[loc_block_info] = chunk; + loc_block_info++; + + const bool tensors_full = + (loc_tensor_info == depth_to_max_tensors[depth - 1] && + chunk == chunks - 1); + const bool blocks_full = + (loc_block_info == depth_to_max_blocks[depth - 1]); + + if (tensors_full || blocks_full) { + multi_tensor_apply_kernel<<< + loc_block_info, + kBlockSize, + 0, + at::cuda::getCurrentCUDAStream()>>>( + tensorListMeta, callable, args...); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + + // Reset. + loc_block_info = 0; + if (chunk == chunks - 1) { + loc_tensor_info = 0; + tensorListMeta.start_tensor_this_launch = processed; + } else { + tensorListMeta.numel_for_tensor[0] = + tensorListMeta.numel_for_tensor[loc_tensor_info - 1]; + for (int d = 0; d < depth; d++) { + tensorListMeta.addresses[d][0] = + tensorListMeta.addresses[d][loc_tensor_info - 1]; + } + loc_tensor_info = 1; + tensorListMeta.start_tensor_this_launch = processed - 1; + } + } + } + } + + // see note: [finishing what we started] + if (loc_block_info != 0) { + multi_tensor_apply_kernel<<< + loc_block_info, + kBlockSize, + 0, + at::cuda::getCurrentCUDAStream()>>>(tensorListMeta, callable, args...); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } +} + +template +void multi_tensor_apply_for_fused_optimizer( + std::vector>& tensor_lists, + at::TensorList state_steps, + T callable, + ArgTypes... args) { + TORCH_CHECK( + tensor_lists.size() == depth, + "Number of tensor lists has to match the depth"); + const auto num_tensors = tensor_lists[0].size(); + FusedOptimizerTensorListMetadata tensorListMeta; + + int loc_block_info = 0; + int loc_tensor_info = 0; + for (const auto& tensor_index : c10::irange(num_tensors)) { + // short-circuit to avoid adding empty tensors to tensorListMeta + if (tensor_lists[0][tensor_index].numel() == 0) { + continue; + } + tensorListMeta.state_steps_addresses[loc_tensor_info] = + state_steps[tensor_index].const_data_ptr(); + tensorListMeta.numel_for_tensor[loc_tensor_info] = + tensor_lists[0][tensor_index].numel(); + for (const auto& d : c10::irange(depth)) { + tensorListMeta.addresses[d][loc_tensor_info] = + tensor_lists[d][tensor_index].const_data_ptr(); + } + loc_tensor_info++; + + // see above note: [chunking territory] + const auto numel = tensor_lists[0][tensor_index].numel(); + const auto chunks = numel / kChunkSize + (numel % kChunkSize != 0); + TORCH_CHECK(chunks > -1); + for (const auto& chunk : c10::irange(chunks)) { + tensorListMeta.block_to_tensor[loc_block_info] = loc_tensor_info - 1; + tensorListMeta.block_to_chunk[loc_block_info] = chunk; + loc_block_info++; + + const auto tensor_full = + (loc_tensor_info == depth_to_max_tensors[depth - 1] && + chunk == chunks - 1); + const auto blocks_full = loc_block_info == depth_to_max_blocks[depth - 1]; + + if (tensor_full || blocks_full) { + multi_tensor_apply_kernel<<< + loc_block_info, + kBlockSize, + 0, + at::cuda::getCurrentCUDAStream()>>>( + tensorListMeta, callable, args...); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + + // Reset. + loc_block_info = 0; + if (chunk == chunks - 1) { + loc_tensor_info = 0; + } else { + tensorListMeta.numel_for_tensor[0] = + tensorListMeta.numel_for_tensor[loc_tensor_info - 1]; + tensorListMeta.state_steps_addresses[0] = + tensorListMeta.state_steps_addresses[loc_tensor_info - 1]; + for (const auto& d : c10::irange(depth)) { + tensorListMeta.addresses[d][0] = + tensorListMeta.addresses[d][loc_tensor_info - 1]; + } + loc_tensor_info = 1; + } + } + } + } + + // see above note: [finishing what we've started] + if (loc_block_info != 0) { + multi_tensor_apply_kernel<<< + loc_block_info, + kBlockSize, + 0, + at::cuda::getCurrentCUDAStream()>>>(tensorListMeta, callable, args...); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Normalization.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Normalization.cuh new file mode 100644 index 0000000000000000000000000000000000000000..088aa517aa23a27739faaf65c8c0ad5904c66e65 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Normalization.cuh @@ -0,0 +1,1742 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#include +#include +#endif + +namespace at::native { + +// The maximum number of threads in a block +#if defined(USE_ROCM) +constexpr int MAX_BLOCK_SIZE = 256; +#else +constexpr int MAX_BLOCK_SIZE = 512; +#endif + +constexpr unsigned MAX_GRID_SIZE = 65535u; + +// Number of threads in a block given an input size up to MAX_BLOCK_SIZE +static int getNumThreads(int nElem) { +#if defined(USE_ROCM) + int threadSizes[5] = { 16, 32, 64, 128, MAX_BLOCK_SIZE }; +#else + int threadSizes[5] = { 32, 64, 128, 256, MAX_BLOCK_SIZE }; +#endif + for (int i = 0; i != 5; ++i) { + if (nElem <= threadSizes[i]) { + return threadSizes[i]; + } + } + return MAX_BLOCK_SIZE; +} + +// Returns the index of the most significant 1 bit in `val`. +__device__ __forceinline__ int getMSB(int val) { + return 31 - __clz(val); +} + +template +struct Float2 { + accscalar_t v1, v2; + __device__ Float2() {} + __device__ Float2(scalar_t v1, scalar_t v2) : v1(static_cast(v1)), v2(static_cast(v2)) {} + __device__ Float2(int v) : v1(static_cast(v)), v2(static_cast(v)) {} + __device__ Float2& operator+=(const Float2& a) { + v1 += a.v1; + v2 += a.v2; + return *this; + } + __device__ friend Float2 operator+(Float2 a, const Float2& b) { + a += b; + return a; + } +}; + +template +struct GradOp { + __device__ GradOp(accscalar_t m, const PTA& i, const PTA& g) + : mean(m), input(i), grad_output(g) {} + __device__ __forceinline__ Float2 operator()(int batch, int plane, int n) { + accscalar_t g = grad_output[batch][plane][n]; + accscalar_t c = static_cast(input[batch][plane][n]) - mean; + return Float2(g, g * c); + } + const accscalar_t mean; + const PTA& input; + const PTA& grad_output; +}; + +template +struct SumReduceOp { + __device__ __forceinline__ acc_t combine(acc_t a, acc_t b) const { return a + b; } + + __device__ __forceinline__ acc_t warp_shfl_down(acc_t data, int offset) const { + return WARP_SHFL_DOWN(data, offset); + } +}; + +template +struct SumReduceOp> { + using acc_t = Float2; + + __device__ __forceinline__ acc_t combine(acc_t a, acc_t b) const { return a + b; } + + __device__ __forceinline__ acc_t warp_shfl_down(acc_t data, int offset) const { + return {WARP_SHFL_DOWN(data.v1, offset), WARP_SHFL_DOWN(data.v2, offset)}; + } +}; + +// Sum across (batch, x/y/z) applying Op() pointwise +// this works by first having each thread sum it's part +// of the data. Then there is a double-shuffling reduction. +// First each warp (of C10_WARP_SIZE threads) uses warpSum to reduce its +// data to the "warp leader", who writes its value into shared memory. +// Then a single warp reads the remaining (at most C10_WARP_SIZE) items +// and reduces them using another warpSum. +// The implicit assumption is that there are no more +// than C10_WARP_SIZE**2 threads. +template +__device__ scalar_t reduce(Op op, PTA tensor, int plane) { + // first the reductions each thread does separately + scalar_t sum = static_cast(0); + for (int batch = threadIdx.y; batch < tensor.size(0); batch += blockDim.y) { + for (int x = threadIdx.x; x < tensor.size(2); x += blockDim.x) { + sum += op(batch, plane, x); + } + } + __shared__ scalar_t shared[C10_WARP_SIZE]; + SumReduceOp reduce_op; + sum = cuda_utils::BlockReduce, cuda_utils::Block2D>(sum, reduce_op, 0, shared); + if (threadIdx.x == 0 && threadIdx.y == 0) { + shared[0] = sum; + } + __syncthreads(); + // Everyone picks it up, should be broadcast into the whole grad_input + return shared[0]; +} + +constexpr int ELEMENTS_PER_ITER = 4; // enables concurrency within each thread to hide latency +constexpr int ELEMENTS_PER_THREAD = 16; +constexpr int OPTIMAL_TILE_W = 32; +constexpr int MAX_H_BLOCK = 128; + +__host__ void flexible_launch_configs( + const int reduction, + const int stride, + dim3 &block, + dim3 &grid, + const bool coop_flag = false) { + int block_x = std::min(lastPow2(stride), OPTIMAL_TILE_W); + int block_y = std::min(lastPow2(at::ceil_div(reduction , ELEMENTS_PER_THREAD)), + MAX_BLOCK_SIZE / block_x); + if (block_x * block_y != MAX_BLOCK_SIZE) { + block_x = std::min(lastPow2(stride), MAX_BLOCK_SIZE / block_y); + } + + int grid_x = at::ceil_div(stride, block_x); + int grid_y = std::min(at::ceil_div(reduction, block_y * ELEMENTS_PER_THREAD), MAX_H_BLOCK); + if (coop_flag) { + // it's not worth having a grid reduction if the reduction dimension is not big enough + grid_y = grid_y < 8 ? 1 : grid_y; + } + + block.x = block_x; + block.y = block_y; + block.z = 1; + grid.x = grid_x; + grid.y = grid_y; + grid.z = 1; +} + +template +__device__ __forceinline__ void welford_merge_element(C& count, + T& mean, + T& m2n, + const C& count_new, + const T& mean_new, + const T& m2n_new) { + T factor = T(1.0) / ::max(1, (count + count_new)); + T delta0 = mean - mean_new; + mean = (mean_new * count_new + mean * count) * factor; + m2n += m2n_new + delta0 * delta0 * count_new * count * factor; + count += count_new; +} + +// merge mean/m2n among threadIdx.y within block +template +__device__ __forceinline__ void welford_merge_block_vertical(C& count, + T& mean, + T& m2n, + C* shmem_count, + T* shmem_mean, + T* shmem_m2n) { + // write to shared memory + auto address_base = threadIdx.x + threadIdx.y * blockDim.x; + +#pragma unroll + for (int offset = blockDim.y/2; offset > 0; offset >>= 1) { + if (threadIdx.y < offset*2) { + shmem_mean[address_base] = mean; + shmem_m2n[address_base] = m2n; + shmem_count[address_base] = count; + } + __syncthreads(); + if (threadIdx.y < offset && threadIdx.y + offset < blockDim.y) { + auto address = address_base + offset * blockDim.x; + // read shared memory back to register for reduction + auto count_new = shmem_count[address]; + auto mean_new = shmem_mean[address]; + auto m2n_new = shmem_m2n[address]; + + welford_merge_element(count, mean, m2n, count_new, mean_new, m2n_new); + } + } +} + +template +__global__ void batch_norm_transform_input_kernel( + const GenericPackedTensorAccessor input, + GenericPackedTensorAccessor output, + const GenericPackedTensorAccessor, 1, RestrictPtrTraits, index_t> mean_, + const GenericPackedTensorAccessor, 1, RestrictPtrTraits, index_t> var_or_invstd, + const GenericPackedTensorAccessor weight, + const GenericPackedTensorAccessor bias, + stat_accscalar_t epsilon) { + + index_t plane = blockIdx.x; + + if (plane >= input.size(1)) { + return; + } + + stat_accscalar_t gamma = weight.size(0) > 0 ? static_cast(weight[plane]) : static_cast(1); + stat_accscalar_t beta = bias.size(0) > 0 ? static_cast(bias[plane]) : static_cast(0); + stat_accscalar_t mean = static_cast(mean_[plane]); + stat_accscalar_t invstd; + if (train) { + invstd = var_or_invstd[plane]; + } else { + invstd = static_cast(1) / device_sqrt(static_cast(var_or_invstd[plane]) + epsilon); + } + + index_t bs = input.size(0); + index_t fs = input.size(2); + + index_t bstep = blockDim.y * gridDim.y; + for (index_t batch = threadIdx.y + blockIdx.y * blockDim.y; batch < bs; batch += bstep) { + auto o = output[batch][plane]; + auto i = input[batch][plane]; + for (index_t feature = threadIdx.x; feature < fs; feature += blockDim.x) { + o[feature] = static_cast(gamma * (i[feature] - mean) * invstd + beta); + } + } +} + +struct InvStd { + template + __device__ __forceinline__ T operator()(T var, double epsilon) const { + T invstd = 0; + if (var != static_cast(0) || epsilon != static_cast(0)) { + invstd = static_cast(1) / device_sqrt(var + epsilon); + } + return invstd; + } +}; + +struct Var { + template + __device__ __forceinline__ T operator()(T var, double epsilon) const { + return var; + } +}; + +template +__global__ void batch_norm_collect_statistics_kernel( + const GenericPackedTensorAccessor input, + const stat_accscalar_t epsilon, + const stat_accscalar_t momentum, + GenericPackedTensorAccessor save_mean, + GenericPackedTensorAccessor save_transformed_var) { + + __shared__ int shared_n[2 * 2 * C10_WARP_SIZE + C10_WARP_SIZE]; + + int plane = blockIdx.x; + int N = input.size(0) * input.size(2); + int tid = threadIdx.x + threadIdx.y * blockDim.x; + + // Compute the mean and variance across (batch, x/y/z) + // this uses the Welford (in the for loop)/parallel algorithm (to sum across the block) + // https://en.wikipedia.org/wiki/Algorithms_for_calculating_variance#Welford's_Online_algorithm + // and the parallel algorithm on the same page. + // We use two shuffles to reduce across the entire block. + // https://devblogs.nvidia.com/faster-parallel-reductions-kepler/ has a description. + stat_accscalar_t* shared_avg_var = (stat_accscalar_t*) &shared_n[C10_WARP_SIZE]; + + // first the reductions each thread does separately + stat_accscalar_t avg = 0; + stat_accscalar_t var_n = 0; + int n = 0; + for (int batch = threadIdx.y; batch < input.size(0); batch += blockDim.y) { + for (int x = threadIdx.x; x < input.size(2); x += blockDim.x) { + stat_accscalar_t v = input[batch][plane][x]; + stat_accscalar_t d1 = v - avg; + n++; + avg += d1 / n; + var_n += d1 * (v - avg); + } + } + + // first warpSum to get one value per thread to + // one value per warp + for (int i = 0; i < getMSB(C10_WARP_SIZE); ++i) { + stat_accscalar_t o_avg = WARP_SHFL_XOR(avg, 1 << i, C10_WARP_SIZE); + int o_n = WARP_SHFL_XOR(n, 1 << i, C10_WARP_SIZE); + stat_accscalar_t factor = 1.0 / fmaxf(1.0, n+o_n); + var_n += WARP_SHFL_XOR(var_n, 1 << i, C10_WARP_SIZE) + (avg - o_avg) * (avg - o_avg) * n * o_n * factor; + avg = (n * avg + o_n * o_avg) * factor; + n += o_n; + } + + // this writes each warps item into shared memory + // there are at most C10_WARP_SIZE items left because + // there are at most C10_WARP_SIZE**2 threads at the beginning + __syncthreads(); + if (tid % C10_WARP_SIZE == 0) { + shared_n[tid / C10_WARP_SIZE] = n; + shared_avg_var[tid / C10_WARP_SIZE * 2] = avg; + shared_avg_var[tid / C10_WARP_SIZE * 2 + 1] = var_n; + } + __syncthreads(); + // now have a second warpSum to reduce the intermediate values + // from shared memory to a single number. The very first + // thread writes it to shared memory. + + if (tid < C10_WARP_SIZE) { + n = (tid < blockDim.x * blockDim.y / C10_WARP_SIZE ? shared_n[tid] : 0); + avg = (tid < blockDim.x * blockDim.y / C10_WARP_SIZE ? shared_avg_var[2 * tid] : stat_accscalar_t(0)); + var_n = (tid < blockDim.x * blockDim.y / C10_WARP_SIZE ? shared_avg_var[2 * tid + 1] : stat_accscalar_t(0)); + } + for (int i = 0; i < getMSB(C10_WARP_SIZE); ++i) { + stat_accscalar_t o_avg = WARP_SHFL_XOR(avg, 1 << i, C10_WARP_SIZE); + int o_n = WARP_SHFL_XOR(n, 1 << i, C10_WARP_SIZE); + stat_accscalar_t factor = 1.0 / fmaxf(1.0, n+o_n); + var_n += WARP_SHFL_XOR(var_n, 1 << i, C10_WARP_SIZE) + (avg - o_avg) * (avg - o_avg) * n * o_n * factor; + avg = (n * avg + o_n * o_avg) * factor; + n += o_n; + } + + // Save the mean, variance, and moving averages + if (tid == 0) { + if (save_mean.data() != NULL) { + save_mean[plane] = avg; + } + if (save_transformed_var.data() != NULL) { + save_transformed_var[plane] = VarTransform{}(var_n / N, epsilon); + } + } + +} + +template +__global__ void batch_norm_backward_kernel( + const GenericPackedTensorAccessor input, + const GenericPackedTensorAccessor grad_output, + GenericPackedTensorAccessor grad_input, + GenericPackedTensorAccessor grad_weight, + GenericPackedTensorAccessor grad_bias, + const GenericPackedTensorAccessor weight, + const GenericPackedTensorAccessor running_mean, + const GenericPackedTensorAccessor running_var, + const GenericPackedTensorAccessor save_mean, + const GenericPackedTensorAccessor save_invstd, + bool train, + stat_accscalar_t epsilon) { + + index_t plane = blockIdx.x; + index_t N = grad_output.size(0) * grad_output.size(2); + + stat_accscalar_t mean, invstd; + if (train) { + mean = save_mean[plane]; + invstd = save_invstd[plane]; + } else { + mean = static_cast(running_mean[plane]); + invstd = static_cast(1) / device_sqrt(static_cast(running_var[plane]) + epsilon); + } + + stat_accscalar_t weight_val = weight.size(0) > 0 ? static_cast(weight[plane]) : stat_accscalar_t(1); + stat_accscalar_t norm = stat_accscalar_t(1) / N; + + // Compute two values across (batch, x/y/z) in one pass: + // 1. Sum(grad_output) + // 2. DotProduct(input - mean, grad_output) + GradOp> g(mean, input, grad_output); + auto res = reduce>(g, grad_output, plane); + + stat_accscalar_t grad_output_sum = res.v1; + stat_accscalar_t dot_p = res.v2; + + stat_accscalar_t grad_mean = grad_output_sum * norm; + stat_accscalar_t proj_scale = dot_p * norm * invstd * invstd; + stat_accscalar_t grad_scale = invstd * weight_val; + + if (grad_input.data() != NULL) { + for (int batch = threadIdx.y; batch < grad_output.size(0); batch += blockDim.y) { + for (int x = threadIdx.x; x < grad_output.size(2); x += blockDim.x) { + input_scalar_t go = grad_output[batch][plane][x]; + if (train) { + stat_accscalar_t inp = input[batch][plane][x]; + stat_accscalar_t proj = (inp - mean) * proj_scale; + grad_input[batch][plane][x] = static_cast((go - proj - grad_mean) * grad_scale); + } else { + grad_input[batch][plane][x] = static_cast(go * grad_scale); + } + } + } + } + + if (grad_weight.size(0) > 0) { + if (threadIdx.x == 0) { + grad_weight[plane] = static_cast(dot_p * invstd); + } + } + + if (grad_bias.size(0) > 0) { + if (threadIdx.x == 0) { + grad_bias[plane] = static_cast(grad_output_sum); + } + } +} + +template +__global__ void batch_norm_reduce_statistics_kernel( + const GenericPackedTensorAccessor vec_mean, + const GenericPackedTensorAccessor vec_invstd, + GenericPackedTensorAccessor mean, + GenericPackedTensorAccessor invstd, + GenericPackedTensorAccessor running_mean, + GenericPackedTensorAccessor running_var, + const accscalar_t epsilon, + const accscalar_t momentum, + const GenericPackedTensorAccessor counts) { + + int feature_size = vec_mean.size(1); + int world_size = vec_mean.size(0); + + int bid = blockIdx.x; + int tid = threadIdx.x; + + // first the reductions each thread does separately + for (int i = bid*blockDim.x+tid; i < feature_size; i += gridDim.x*blockDim.x) { + accscalar_t avg = 0; + accscalar_t var_n = 0; + index_t n = 0; + for (int j = 0; j < world_size; j++) { + scalar_t count = counts[j]; + accscalar_t m = vec_mean[j][i]; + accscalar_t v = accscalar_t(1.0) / (vec_invstd[j][i]); + v = (v * v - epsilon) * count; + accscalar_t factor = 1.0 / (n + count); + var_n += v + (avg - m) * (avg - m) * n * count * factor; + avg = n * factor * avg + count * factor * m; + n += count; + } + mean[i] = avg; + invstd[i] = static_cast(1) / device_sqrt(var_n / n + epsilon); + if (running_mean.data() != NULL) { + running_mean[i] = static_cast((1 - momentum) * running_mean[i] + momentum * avg); + } + accscalar_t unbiasedVar = var_n / (n - 1); + if (running_var.data() != NULL) { + running_var[i] = static_cast((1 - momentum) * running_var[i] + momentum * unbiasedVar); + } + } + +} + +template +__global__ void batch_norm_backward_reduce_kernel( + const GenericPackedTensorAccessor input, + const GenericPackedTensorAccessor grad_output, + GenericPackedTensorAccessor mean, + GenericPackedTensorAccessor invstd, + GenericPackedTensorAccessor sum_dy, + GenericPackedTensorAccessor sum_dy_xmu, + GenericPackedTensorAccessor grad_weight, + GenericPackedTensorAccessor grad_bias) { + + index_t plane = blockIdx.x; + + stat_accscalar_t r_mean = mean[plane]; + stat_accscalar_t factor = invstd[plane]; + + GradOp> g(r_mean, input, grad_output); + auto res = reduce>(g, grad_output, plane); + + if (threadIdx.x == 0) { + if (grad_weight.size(0) > 0) { + grad_weight[plane] = static_cast(res.v2 * factor); + } + if (grad_bias.size(0) > 0) { + grad_bias[plane] = static_cast(res.v1); + } + if (sum_dy.size(0) > 0) { + sum_dy[plane] = static_cast(res.v1); + } + if (sum_dy_xmu.size(0) > 0) { + sum_dy_xmu[plane] = static_cast(res.v2); + } + } +} + +template +__device__ __forceinline__ void batch_norm_backward_elemt_kernel_impl( + const GenericPackedTensorAccessor input, + const GenericPackedTensorAccessor grad_output, + const GenericPackedTensorAccessor mean, + const GenericPackedTensorAccessor invstd, + const GenericPackedTensorAccessor weight, + const GenericPackedTensorAccessor sum_dy, + const GenericPackedTensorAccessor sum_dy_xmu, + GenericPackedTensorAccessor grad_input, + const stat_accscalar_t norm_fct) { + index_t plane = blockIdx.x; + + if (plane >= input.size(1)) { + return; + } + + stat_accscalar_t m_c = mean[plane]; + stat_accscalar_t m_dy_c = sum_dy[plane] * norm_fct; + stat_accscalar_t factor_1_c = invstd[plane]; + stat_accscalar_t factor_2_c = weight.size(0) > 0 ? static_cast(weight[plane]) : stat_accscalar_t(1); + factor_2_c *= factor_1_c; + factor_1_c = factor_1_c * factor_1_c * sum_dy_xmu[plane] * norm_fct; + + index_t bs = input.size(0); + index_t fs = input.size(2); + + index_t bstep = blockDim.y * gridDim.y; + for (index_t batch = threadIdx.y + blockIdx.y * blockDim.y; batch < bs; batch += bstep) { + auto g_i = grad_input[batch][plane]; + auto g_o = grad_output[batch][plane]; + auto i = input[batch][plane]; + for (index_t feature = threadIdx.x; feature < fs; feature += blockDim.x) { + g_i[feature] = static_cast((g_o[feature] - m_dy_c - (i[feature] - m_c) * factor_1_c) * factor_2_c); + } + } +} + +template +__global__ void batch_norm_backward_elemt_kernel( + const GenericPackedTensorAccessor input, + const GenericPackedTensorAccessor grad_output, + const GenericPackedTensorAccessor mean, + const GenericPackedTensorAccessor invstd, + const GenericPackedTensorAccessor weight, + const GenericPackedTensorAccessor sum_dy, + const GenericPackedTensorAccessor sum_dy_xmu, + GenericPackedTensorAccessor grad_input, + const int* __restrict__ numel, const int world_size) { + int64_t total_numel = 0; + for (int i = 0; i < world_size; i ++) { + total_numel += numel[i]; + } + + const stat_accscalar_t norm_fct = + static_cast(1) / static_cast(total_numel); + batch_norm_backward_elemt_kernel_impl( + input, grad_output, mean, invstd, weight, sum_dy, sum_dy_xmu, grad_input, norm_fct); +} + +template +__global__ void batch_norm_backward_elemt_kernel( + const GenericPackedTensorAccessor input, + const GenericPackedTensorAccessor grad_output, + const GenericPackedTensorAccessor mean, + const GenericPackedTensorAccessor invstd, + const GenericPackedTensorAccessor weight, + const GenericPackedTensorAccessor sum_dy, + const GenericPackedTensorAccessor sum_dy_xmu, + GenericPackedTensorAccessor grad_input, + const stat_accscalar_t norm_fct) { + batch_norm_backward_elemt_kernel_impl( + input, grad_output, mean, invstd, weight, sum_dy, sum_dy_xmu, grad_input, norm_fct); +} + +template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> +static GenericPackedTensorAccessor get_packed_accessor( + const Tensor& t, std::string_view var_name) { + constexpr auto expect_type = c10::CppTypeToScalarType>::value; + const auto actual_type = t.scalar_type(); + TORCH_CHECK(actual_type == expect_type, "Expected ", var_name, + " to have type ", expect_type, " but got ", actual_type); + return t.generic_packed_accessor(); +} + +template class PtrTraits = DefaultPtrTraits, typename index_t = int64_t> +static GenericPackedTensorAccessor packed_accessor_or_dummy( + const Tensor& t, std::string_view var_name) { + if (!t.defined()) { + const std::array zeros{{0}}; + return GenericPackedTensorAccessor(nullptr, zeros.data(), zeros.data()); + } + return get_packed_accessor(t, var_name); +} + +template +std::tuple batch_norm_backward_cuda_template(const Tensor& grad_out_, const Tensor& input_, const Tensor& weight_, + const Tensor& running_mean_, const Tensor& running_var_, const Tensor& save_mean_, const Tensor& save_invstd_, + bool train, double epsilon, std::array grad_input_mask) { + + using accscalar_t = at::acc_type; + Tensor grad_input_; + Tensor grad_input_reshaped; + Tensor grad_weight_; + Tensor grad_bias_; + auto input_reshaped = input_.reshape({input_.size(0), input_.size(1), -1}); + auto grad_output_reshaped = grad_out_.reshape(input_reshaped.sizes()); + + if (grad_input_mask[0]) { + grad_input_ = at::empty_like(input_, LEGACY_CONTIGUOUS_MEMORY_FORMAT); + grad_input_reshaped = grad_input_.view(input_reshaped.sizes()); + } + if (grad_input_mask[1]) { + grad_weight_ = at::empty_like(weight_, LEGACY_CONTIGUOUS_MEMORY_FORMAT); + } + if (grad_input_mask[2]) { + grad_bias_ = at::empty_like(weight_, LEGACY_CONTIGUOUS_MEMORY_FORMAT); + } + + auto input = get_packed_accessor< + const input_scalar_t, 3, DefaultPtrTraits, index_t>(input_reshaped, "input"); + auto grad_output = get_packed_accessor< + const input_scalar_t, 3, DefaultPtrTraits, index_t>(grad_output_reshaped, "grad_output"); + auto grad_input = packed_accessor_or_dummy< + input_scalar_t, 3, DefaultPtrTraits, index_t>(grad_input_reshaped, "grad_input"); + auto weight = packed_accessor_or_dummy< + const stat_scalar_t, 1, DefaultPtrTraits, index_t>(weight_, "weight"); + auto grad_weight = packed_accessor_or_dummy< + stat_scalar_t, 1, DefaultPtrTraits, index_t>(grad_weight_, "grad_weight"); + auto grad_bias = packed_accessor_or_dummy< + stat_scalar_t, 1, DefaultPtrTraits, index_t>(grad_bias_, "grad_bias"); + auto running_mean = packed_accessor_or_dummy< + const stat_scalar_t, 1, DefaultPtrTraits, index_t>(running_mean_, "running_mean"); + auto running_var = packed_accessor_or_dummy< + const stat_scalar_t, 1, DefaultPtrTraits, index_t>(running_var_, "running_var"); + auto save_mean = packed_accessor_or_dummy< + const accscalar_t, 1, DefaultPtrTraits, index_t>(save_mean_, "save_mean"); + auto save_invstd = packed_accessor_or_dummy< + const accscalar_t, 1, DefaultPtrTraits, index_t>(save_invstd_, "save_invstd"); + + auto stream = at::cuda::getCurrentCUDAStream(); + dim3 blocks(input.size(1)); + int tf = getNumThreads(input.size(2)); + dim3 threads(tf, std::max(1, MAX_BLOCK_SIZE/tf)); + + batch_norm_backward_kernel <<>> + (input, grad_output, grad_input, grad_weight, grad_bias, weight, running_mean, running_var, + save_mean, save_invstd, train, epsilon); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + + return std::make_tuple(grad_input_, grad_weight_, grad_bias_); +} + +template +void batch_norm_stats_cuda_template( + const Tensor& out_mean, const Tensor& out_invstd, const Tensor& input_, double epsilon) { + + using accscalar_t = at::acc_type; + int64_t n_input = input_.size(1); + Tensor dummy_mean_; + Tensor dummy_var_; + auto input_reshaped = input_.reshape({input_.size(0), input_.size(1), -1}); // internally we merge the feature dimensions + + resize_output(out_mean, {n_input}); + resize_output(out_invstd, {n_input}); + auto input = get_packed_accessor< + const scalar_t, 3, RestrictPtrTraits, index_t>(input_reshaped, "input"); + TORCH_INTERNAL_ASSERT(out_invstd.dim() == 1 && out_invstd.is_contiguous() && + out_invstd.sizes()[0]); + TORCH_INTERNAL_ASSERT(out_mean.dim() == 1 && out_mean.is_contiguous() && + out_mean.sizes()[0]); + + auto mean = packed_accessor_or_dummy< + accscalar_t, 1, RestrictPtrTraits, index_t>(out_mean, "out_mean"); + auto invstd = packed_accessor_or_dummy< + accscalar_t, 1, RestrictPtrTraits, index_t>(out_invstd, "out_invstd"); + auto stream = at::cuda::getCurrentCUDAStream(); + + dim3 blocks(input.size(1)); + int tf = getNumThreads(input.size(2)); + dim3 threads(tf, std::max(1, MAX_BLOCK_SIZE/tf)); + batch_norm_collect_statistics_kernel <<>> + (input, epsilon, 0.0, mean, invstd); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +void batch_norm_elemt_cuda_template(const Tensor& output_, const Tensor& input_, const Tensor& weight_, + const Tensor& bias_, const Tensor& mean_, const Tensor& invstd_) { + + using stat_accscalar_t = at::acc_type; + int64_t n_input = input_.size(1); + auto input_reshaped = input_.reshape({input_.size(0), input_.size(1), -1}); // internally we merge the feature dimensions + auto output_reshaped = output_.view({input_.size(0), input_.size(1), -1}); + + auto input = get_packed_accessor< + const input_scalar_t, 3, RestrictPtrTraits, index_t>(input_reshaped, "input"); + auto output = get_packed_accessor< + input_scalar_t, 3, RestrictPtrTraits, index_t>(output_reshaped, "output"); + auto weight = packed_accessor_or_dummy< + const stat_scalar_t, 1, RestrictPtrTraits, index_t>(weight_, "weight"); + auto bias = packed_accessor_or_dummy< + const stat_scalar_t, 1, RestrictPtrTraits, index_t>(bias_, "bias"); + auto mean = packed_accessor_or_dummy< + stat_accscalar_t, 1, RestrictPtrTraits, index_t>(mean_, "mean"); + auto invstd = packed_accessor_or_dummy< + stat_accscalar_t, 1, RestrictPtrTraits, index_t>(invstd_, "invstd"); + auto stream = at::cuda::getCurrentCUDAStream(); + + // NOTE: We use transform_input_kernel in training mode, which ignores epsilon + const double dummy_epsilon = 1e-5; + + // The input_transform kernel is pointwise, but we need to balance reading parameters (save_var/mean, + // weight/bias) - which we only do once and have a for loop afterwards - with having many threads and blocks + // and good occupancy. Quiet likely, we could go with even more blocks than 1024. + // The various planes are independent, so we use blocks for them. + int tf = std::max(getNumThreads(input.size(2)/4), + std::min(getNumThreads(input.size(2)), 64)); + int tb = std::max(64/tf, 1); + dim3 blocks_trans(input.size(1), std::max(1, std::min((256*1024)/input.size(1), + (input.size(0)+tb-1)/tb))); + blocks_trans.y = std::min(blocks_trans.y, MAX_GRID_SIZE); + dim3 threads_trans(tf, tb); + batch_norm_transform_input_kernel <<>> + (input, output, mean, invstd, weight, bias, dummy_epsilon); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +std::tuple batch_norm_gather_stats_cuda_template(const Tensor& mean_, const Tensor& invstd_, + const Tensor& running_mean_, const Tensor& running_var_, + double momentum, double epsilon, const Tensor& counts_) { + + Tensor save_mean_; + Tensor save_invstd_; + + auto features = mean_.size(1); + auto input_options = mean_.options(); + if (mean_.scalar_type() == at::ScalarType::Half || mean_.scalar_type() == at::ScalarType::BFloat16) { + input_options = input_options.dtype(ScalarType::Float); + } + save_mean_ = at::empty({features}, input_options); + save_invstd_ = at::empty({features}, input_options); + + auto mean = packed_accessor_or_dummy< + accscalar_t, 2, RestrictPtrTraits, index_t>(mean_, "mean"); + auto invstd = packed_accessor_or_dummy< + accscalar_t, 2, RestrictPtrTraits, index_t>(invstd_, "invstd"); + auto running_mean = packed_accessor_or_dummy< + scalar_t, 1, RestrictPtrTraits, index_t>(running_mean_, "running_mean"); + auto running_var = packed_accessor_or_dummy< + scalar_t, 1, RestrictPtrTraits, index_t>(running_var_, "running_mean"); + auto counts = packed_accessor_or_dummy< + scalar_t, 1, RestrictPtrTraits, index_t>(counts_, "counts"); + + auto save_mean = get_packed_accessor< + accscalar_t, 1, RestrictPtrTraits, index_t>(save_mean_, "save_mean"); + auto save_invstd = get_packed_accessor< + accscalar_t, 1, RestrictPtrTraits, index_t>(save_invstd_, "save_invstd"); + auto stream = at::cuda::getCurrentCUDAStream(); + + int block = getNumThreads(features); + int grid = std::max(1, features/block); + batch_norm_reduce_statistics_kernel <<>> + (mean, invstd, save_mean, save_invstd, running_mean, running_var, epsilon, momentum, counts); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + + return std::make_tuple(save_mean_, save_invstd_); +} + +template +std::tuple batch_norm_backward_reduce_cuda_template(const Tensor& grad_out_, const Tensor& input_, + const Tensor& mean_, const Tensor& invstd_, const Tensor& weight_, + const bool input_g, const bool weight_g, const bool bias_g) { + + using stat_accscalar_t = at::acc_type; + int64_t n_input = input_.size(1); + Tensor sum_dy_; + Tensor sum_dy_xmu_; + Tensor grad_weight_; + Tensor grad_bias_; + auto input_reshaped = input_.reshape({input_.size(0), input_.size(1), -1}); // internally we merge the feature dimensions + auto grad_output_reshaped = grad_out_.reshape(input_reshaped.sizes()); + + if (input_g) { + sum_dy_ = at::empty_like(mean_, LEGACY_CONTIGUOUS_MEMORY_FORMAT); + sum_dy_xmu_ = at::empty_like(mean_, LEGACY_CONTIGUOUS_MEMORY_FORMAT); + } + if (weight_g) { + grad_weight_ = at::empty({n_input}, weight_.options()); + } + if (bias_g) { + grad_bias_ = at::empty({n_input}, weight_.options()); + } + + auto input = get_packed_accessor< + input_scalar_t, 3, DefaultPtrTraits, index_t>(input_reshaped, "input"); + auto grad_output = get_packed_accessor< + input_scalar_t, 3, DefaultPtrTraits, index_t>(grad_output_reshaped, "grad_output"); + auto grad_weight = packed_accessor_or_dummy< + stat_scalar_t, 1, DefaultPtrTraits, index_t>(grad_weight_, "grad_weight"); + auto grad_bias = packed_accessor_or_dummy< + stat_scalar_t, 1, DefaultPtrTraits, index_t>(grad_bias_, "grad_bias"); + auto mean = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(mean_, "mean"); + auto invstd = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(invstd_, "invstd"); + auto sum_dy = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(sum_dy_, "sum_dy"); + auto sum_dy_xmu = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(sum_dy_xmu_, "sum_dy_xmu"); + + auto batch_size = input_reshaped.size(0); + auto feature_size = input_reshaped.size(2); + auto stream = at::cuda::getCurrentCUDAStream(); + + int warp_size = at::cuda::warp_size(); + int block_y = std::min(lastPow2(batch_size), MAX_BLOCK_SIZE/warp_size); + // We want block_x to be at least a warp width + int block_x = std::min(std::max(getNumThreads(feature_size), warp_size), MAX_BLOCK_SIZE/block_y); + const dim3 block(block_x, block_y); + const dim3 grid(n_input); + + batch_norm_backward_reduce_kernel <<>> + (input, grad_output, mean, invstd, sum_dy, sum_dy_xmu, grad_weight, grad_bias); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + + return std::make_tuple(sum_dy_, sum_dy_xmu_, grad_weight_, grad_bias_); +} + +template +Tensor batch_norm_backward_elemt_cuda_template(const Tensor& grad_out_, const Tensor& input_, + const Tensor& mean_, const Tensor& invstd_, + const Tensor& weight_, const Tensor& sum_dy_, const Tensor& sum_dy_xmu_) { + + using stat_accscalar_t = at::acc_type; + int64_t n_input = input_.size(1); + auto input_reshaped = input_.reshape({input_.size(0), input_.size(1), -1}); // internally we merge the feature dimensions + auto grad_output_reshaped = grad_out_.reshape(input_reshaped.sizes()); + auto grad_input_reshaped = at::empty_like(input_reshaped, LEGACY_CONTIGUOUS_MEMORY_FORMAT); + + auto input = get_packed_accessor< + input_scalar_t, 3, DefaultPtrTraits, index_t>(input_reshaped, "input"); + auto grad_input = get_packed_accessor< + input_scalar_t, 3, DefaultPtrTraits, index_t>(grad_input_reshaped, "grad_input"); + auto grad_output = get_packed_accessor< + input_scalar_t, 3, DefaultPtrTraits, index_t>(grad_output_reshaped, "grad_output"); + auto mean = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(mean_, "mean"); + auto invstd = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(invstd_, "invstd"); + auto weight = packed_accessor_or_dummy< + stat_scalar_t, 1, DefaultPtrTraits, index_t>(weight_, "weight"); + auto sum_dy = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(sum_dy_, "sum_dy"); + auto sum_dy_xmu = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(sum_dy_xmu_, "sum_dy_xmu"); + + auto stream = at::cuda::getCurrentCUDAStream(); + + // The kernel is pointwise, but we need to balance reading parameters (save_var/mean, + // weight/bias) - which we only do once and have a for loop afterwards - with having many threads and blocks + // and good occupancy. Quiet likely, we could go with even more blocks than 1024. + // The various planes are independent, so we use blocks for them. + int tf = std::max(getNumThreads(input.size(2)/4), + std::min(getNumThreads(input.size(2)), 64)); + int tb = std::max(64/tf, 1); + dim3 blocks_trans(input.size(1), std::max(1, std::min((256*1024)/input.size(1), + (input.size(0)+tb-1)/tb))); + blocks_trans.y = std::min(blocks_trans.y, MAX_GRID_SIZE); + dim3 threads_trans(tf, tb); + auto reduction_size = input_.numel() / n_input; + auto norm_fct = static_cast(1.0 / reduction_size); + batch_norm_backward_elemt_kernel + <<>> + (input, grad_output, mean, invstd, weight, sum_dy, sum_dy_xmu, grad_input, norm_fct); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + + return grad_input_reshaped.view(input_.sizes()); +} + +template +Tensor batch_norm_backward_elemt_cuda_template(const Tensor& grad_out_, const Tensor& input_, + const Tensor& mean_, const Tensor& invstd_, + const Tensor& weight_, const Tensor& sum_dy_, const Tensor& sum_dy_xmu_, const Tensor& count) { + + using stat_accscalar_t = at::acc_type; + int64_t n_input = input_.size(1); + auto input_reshaped = input_.reshape({input_.size(0), input_.size(1), -1}); // internally we merge the feature dimensions + auto grad_output_reshaped = grad_out_.reshape(input_reshaped.sizes()); + auto grad_input_reshaped = at::empty_like(input_reshaped, LEGACY_CONTIGUOUS_MEMORY_FORMAT); + + auto input = get_packed_accessor< + input_scalar_t, 3, DefaultPtrTraits, index_t>(input_reshaped, "input"); + auto grad_input = get_packed_accessor< + input_scalar_t, 3, DefaultPtrTraits, index_t>(grad_input_reshaped, "grad_input"); + auto grad_output = get_packed_accessor< + input_scalar_t, 3, DefaultPtrTraits, index_t>(grad_output_reshaped, "grad_output"); + auto mean = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(mean_, "mean"); + auto invstd = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(invstd_, "invstd"); + auto weight = packed_accessor_or_dummy< + stat_scalar_t, 1, DefaultPtrTraits, index_t>(weight_, "weight"); + auto sum_dy = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(sum_dy_, "sum_dy"); + auto sum_dy_xmu = packed_accessor_or_dummy< + stat_accscalar_t, 1, DefaultPtrTraits, index_t>(sum_dy_xmu_, "sum_dy_xmu"); + + auto stream = at::cuda::getCurrentCUDAStream(); + + // The kernel is pointwise, but we need to balance reading parameters (save_var/mean, + // weight/bias) - which we only do once and have a for loop afterwards - with having many threads and blocks + // and good occupancy. Quiet likely, we could go with even more blocks than 1024. + // The various planes are independent, so we use blocks for them. + int tf = std::max(getNumThreads(input.size(2)/4), + std::min(getNumThreads(input.size(2)), 64)); + int tb = std::max(64/tf, 1); + dim3 blocks_trans(input.size(1), std::max(1, std::min((256*1024)/input.size(1), + (input.size(0)+tb-1)/tb))); + blocks_trans.y = std::min(blocks_trans.y, MAX_GRID_SIZE); + dim3 threads_trans(tf, tb); + batch_norm_backward_elemt_kernel <<>> + (input, grad_output, mean, invstd, weight, sum_dy, sum_dy_xmu, grad_input, count.const_data_ptr(), count.numel()); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + + return grad_input_reshaped.view(input_.sizes()); +} + +// welford kernel for c last tensor calculating mean/biased_variance/unbiased_variance +// original apex name: welford_kernel_c_last +template + +__global__ void +batch_norm_collect_statistics_channels_last_kernel( + const scalar_t* __restrict__ input, + accscalar_t* __restrict__ out_mean, + accscalar_t* __restrict__ out_invstd, + volatile accscalar_t* staging_data, + int* semaphores, + const int reduction_size, + const int stride, + accscalar_t epsilon) { + // hide latency with concurrency + accscalar_t x_mean[PARALLEL_LOADS]; + accscalar_t m_2_n[PARALLEL_LOADS]; + int count[PARALLEL_LOADS]; + +#pragma unroll + for (int i = 0; i < PARALLEL_LOADS; i++) { + x_mean[i] = accscalar_t(0); + m_2_n[i] = accscalar_t(0); + count[i] = accscalar_t(0); + } + // tensor dimension (m,c) + + // loop along m dimension + int inner_loop_stride = blockDim.y * gridDim.y; + + // offset along m dimension + int m_offset = blockIdx.y * blockDim.y + threadIdx.y; + int c_offset = blockIdx.x * blockDim.x + threadIdx.x; + + int loop_count = 1 + (reduction_size - 1) / (inner_loop_stride * PARALLEL_LOADS); + int address_base = m_offset * stride + c_offset; + int address_increment = inner_loop_stride * stride; + + for (int i = 0; i < loop_count; i++) { + accscalar_t x_math[PARALLEL_LOADS]; + accscalar_t x_count_inv[PARALLEL_LOADS]; + accscalar_t is_valid[PARALLEL_LOADS]; + + // load multiple data in +#pragma unroll + for (int j = 0; j < PARALLEL_LOADS; j++) { + if (c_offset < stride && m_offset < reduction_size) { + x_math[j] = input[address_base]; + count[j]++; + x_count_inv[j] = accscalar_t(1) / count[j]; + is_valid[j] = accscalar_t(1); + } else { + x_math[j] = accscalar_t(0); + x_count_inv[j] = accscalar_t(0); + is_valid[j] = accscalar_t(0); + } + m_offset += inner_loop_stride; + address_base += address_increment; + } + + // calculate mean/m2n with welford +#pragma unroll + for (int j = 0; j < PARALLEL_LOADS; j++) { + accscalar_t delta0 = x_math[j] - x_mean[j]; + x_mean[j] += delta0 * x_count_inv[j]; + accscalar_t delta1 = x_math[j] - x_mean[j]; + m_2_n[j] += delta0 * delta1 * is_valid[j]; + } + } + + // thread reduction to accumulate mean/m_2_n/count between PARALLEL_LOADS +#pragma unroll + for (int j = 1; j < PARALLEL_LOADS; j++) { + welford_merge_element(count[0], x_mean[0], m_2_n[0], count[j], x_mean[j], m_2_n[j]); + } + + // release x_mean / m_2_n + auto mean_th = x_mean[0]; + auto m2_th = m_2_n[0]; + auto count_th = count[0]; + + // block-wise reduction with shared memory (since reduction cannot be done within a warp) + static __shared__ accscalar_t shmem_mean[MAX_BLOCK_SIZE]; + static __shared__ accscalar_t shmem_m2n[MAX_BLOCK_SIZE]; + static __shared__ int shmem_count[MAX_BLOCK_SIZE]; + + welford_merge_block_vertical(count_th, mean_th, m2_th, shmem_count, shmem_mean, shmem_m2n); + + if (gridDim.y > 1) { + volatile accscalar_t* staging_mean = staging_data; + volatile accscalar_t* staging_m2n = &staging_data[stride*gridDim.y]; + volatile int* staging_count = reinterpret_cast(&staging_m2n[stride*gridDim.y]); + + address_base = c_offset + blockIdx.y * stride; + // write data to staging_data; + if (threadIdx.y == 0 && c_offset < stride) { + staging_mean[address_base] = mean_th; + staging_m2n[address_base] = m2_th; + staging_count[address_base] = count_th; + } + + __threadfence(); + __syncthreads(); // ensuring writes to staging_ is visible to all blocks + + __shared__ bool is_last_block_done; + // mark block done + if (threadIdx.x == 0 && threadIdx.y == 0) { + int old = atomicAdd(&semaphores[blockIdx.x], 1); + is_last_block_done = (old == (gridDim.y-1)); + } + + __syncthreads(); + + // check that all data is now available in global memory + if (is_last_block_done) { + count_th = 0; + mean_th = accscalar_t(0.0); + m2_th = accscalar_t(0.0); + + for (int y = threadIdx.y; y < gridDim.y; y += blockDim.y) { + address_base = c_offset + y * stride; + int count_new = c_offset < stride ? staging_count[address_base] : 0; + accscalar_t mean_new = c_offset < stride ? staging_mean[address_base] : accscalar_t(0.0); + accscalar_t m2n_new = c_offset < stride ? staging_m2n[address_base] : accscalar_t(0.0); + + welford_merge_element(count_th, mean_th, m2_th, count_new, mean_new, m2n_new); + } + + welford_merge_block_vertical(count_th, mean_th, m2_th, shmem_count, shmem_mean, shmem_m2n); + if (threadIdx.y == 0 && c_offset < stride) { + out_mean[c_offset] = static_cast(mean_th); + out_invstd[c_offset] = VarTransform{}(m2_th/count_th, epsilon); + } + } + } else { + if (blockIdx.y == 0 && threadIdx.y == 0 && c_offset < stride) { + out_mean[c_offset] = static_cast(mean_th); + out_invstd[c_offset] = VarTransform{}(m2_th/count_th, epsilon); + } + } +} + +// elementwise BN kernel +// original apex name: batchnorm_forward_c_last_kernel +template < + typename scalar_t, + typename accscalar_t, + typename layerscalar_t, + int PARALLEL_LOADS> +__global__ void batch_norm_transform_input_channels_last_kernel( + const scalar_t* __restrict__ input, + const scalar_t* __restrict__ z, + const accscalar_t* __restrict__ mean, + const accscalar_t* __restrict__ inv_std, + const layerscalar_t* __restrict__ weight, + const layerscalar_t* __restrict__ shift, + scalar_t* __restrict__ out, + const int reduction_size, + const int stride, + const bool fuse_relu) { + // tensor dimension (m,c) + // loop along m dimension + int inner_loop_stride = blockDim.y * gridDim.y; + + // offset along m dimension + int m_offset = blockIdx.y * blockDim.y + threadIdx.y; + int c_offset = blockIdx.x * blockDim.x + threadIdx.x; + + if (c_offset >= stride || m_offset >= reduction_size) { + return; + } + + auto m_c = mean[c_offset]; + auto inv_std_c = static_cast(inv_std[c_offset]); + auto w_c = weight == nullptr ? accscalar_t(1.0) : static_cast(weight[c_offset]); + auto s_c = shift == nullptr ? accscalar_t(0.0) : static_cast(shift[c_offset]); + + int loop_count = 1 + (reduction_size - 1) / (inner_loop_stride * PARALLEL_LOADS); + int address_base = m_offset * stride + c_offset; + int address_increment = inner_loop_stride * stride; + + for (int i = 0; i < loop_count; i++) { +#pragma unroll + for (int j = 0; j < PARALLEL_LOADS; j++) { + if (c_offset < stride && m_offset < reduction_size) { + auto tmp = w_c * (static_cast(input[address_base]) - m_c ) * inv_std_c + s_c; + if (z != nullptr) { + tmp += z[address_base]; + } + out[address_base] = (fuse_relu && tmp <= accscalar_t(0.0) ? scalar_t(0.0) : static_cast(tmp)); + } + m_offset += inner_loop_stride; + address_base += address_increment; + } + } +} + +template +__device__ __forceinline__ void merge_block_vertical_backward(T& sum_dy, + T& sum_dy_xmu, + T* shmem_sum_dy, + T* shmem_sum_dy_xmu) { + // write to shared memory + auto address_base = threadIdx.x + threadIdx.y * blockDim.x; + +#pragma unroll + for (int offset = blockDim.y/2; offset > 0; offset >>= 1) { + if (threadIdx.y < offset*2) { + shmem_sum_dy[address_base] = sum_dy; + shmem_sum_dy_xmu[address_base] = sum_dy_xmu; + } + __syncthreads(); + if (threadIdx.y < offset && threadIdx.y + offset < blockDim.y) { + auto address = address_base + offset * blockDim.x; + + sum_dy += shmem_sum_dy[address]; + sum_dy_xmu += shmem_sum_dy_xmu[address]; + } + } +} + +// batchnorm backward kernel for c last tensor +// original apex name: reduce_bn_c_last_kernel +template < + int PARALLEL_LOADS, + typename scalar_t, + typename accscalar_t, + typename layerscalar_t> +__global__ void batch_norm_backward_reduce_channels_last_kernel( + const scalar_t* __restrict__ input, + const scalar_t* __restrict__ grad_output, + const accscalar_t* __restrict__ mean, + const accscalar_t* __restrict__ inv_std, + accscalar_t* __restrict__ sum_dy_o, + accscalar_t* __restrict__ sum_dy_xmu_o, + layerscalar_t* __restrict__ grad_weight, + layerscalar_t* __restrict__ grad_bias, + volatile accscalar_t* staging_data, + int* semaphores, + const int reduction_size, + const int stride) { + + // hide latency with concurrency + accscalar_t sum_dy[PARALLEL_LOADS]; + accscalar_t sum_dy_xmu[PARALLEL_LOADS]; + +#pragma unroll + for (int i = 0; i < PARALLEL_LOADS; i++) { + sum_dy[i] = accscalar_t(0); + sum_dy_xmu[i] = accscalar_t(0); + } + // tensor dimension (m,c) + + // loop along m dimension + int inner_loop_stride = blockDim.y * gridDim.y; + + // offset along m dimension + int m_offset = blockIdx.y * blockDim.y + threadIdx.y; + int c_offset = blockIdx.x * blockDim.x + threadIdx.x; + + if (c_offset >= stride || m_offset >= reduction_size) { + return; + } + + int loop_count = 1 + (reduction_size - 1) / (inner_loop_stride * PARALLEL_LOADS); + int address_base = m_offset * stride + c_offset; + int address_increment = inner_loop_stride * stride; + + auto r_mean = mean[c_offset]; + auto factor = inv_std[c_offset]; + + for (int i = 0; i < loop_count; i++) { + accscalar_t x_input[PARALLEL_LOADS]; + accscalar_t x_grad_output[PARALLEL_LOADS]; + + // load multiple data in +#pragma unroll + for (int j = 0; j < PARALLEL_LOADS; j++) { + if (c_offset < stride && m_offset < reduction_size) { + x_input[j] = input[address_base]; + x_grad_output[j] = grad_output[address_base]; + } else { + x_input[j] = accscalar_t(0); + x_grad_output[j] = accscalar_t(0); + } + m_offset += inner_loop_stride; + address_base += address_increment; + } + + // calculate sum_dy / sum_dy_xmu +#pragma unroll + for (int j = 0; j < PARALLEL_LOADS; j++) { + sum_dy[j] += x_grad_output[j]; + sum_dy_xmu[j] += x_grad_output[j] * (x_input[j] - r_mean); + } + } + + // thread reduction to accumulate sum_dy / sum_dy_xmu between PARALLEL_LOADS +#pragma unroll + for (int j = 1; j < PARALLEL_LOADS; j++) { + sum_dy[0] += sum_dy[j]; + sum_dy_xmu[0] += sum_dy_xmu[j]; + } + + // release array of registers + auto sum_dy_th = sum_dy[0]; + auto sum_dy_xmu_th = sum_dy_xmu[0]; + + // block-wise reduction with shared memory (since reduction cannot be done within a warp) + static __shared__ accscalar_t shmem_sum_dy[MAX_BLOCK_SIZE]; + static __shared__ accscalar_t shmem_sum_dy_xmu[MAX_BLOCK_SIZE]; + + merge_block_vertical_backward(sum_dy_th, sum_dy_xmu_th, shmem_sum_dy, shmem_sum_dy_xmu); + + if (gridDim.y > 1) { + volatile accscalar_t* staging_sum_dy = staging_data; + volatile accscalar_t* staging_sum_dy_xmu = &staging_data[stride*gridDim.y]; + + address_base = c_offset + blockIdx.y * stride; + // write data to staging_data; + if (threadIdx.y == 0 && c_offset < stride) { + staging_sum_dy[address_base] = sum_dy_th; + staging_sum_dy_xmu[address_base] = sum_dy_xmu_th; + } + + __threadfence(); + __syncthreads(); // ensuring writes to staging_ is visible to all blocks + + __shared__ bool is_last_block_done; + // mark block done + if (threadIdx.x == 0 && threadIdx.y == 0) { + int old = atomicAdd(&semaphores[blockIdx.x], 1); + is_last_block_done = (old == (gridDim.y-1)); + } + + __syncthreads(); + + // check that all data is now available in global memory + if (is_last_block_done) { + sum_dy_th = accscalar_t(0.0); + sum_dy_xmu_th = accscalar_t(0.0); + + for (int y = threadIdx.y; y < gridDim.y; y += blockDim.y) { + address_base = c_offset + y * stride; + sum_dy_th += (c_offset < stride ? staging_sum_dy[address_base] : accscalar_t(0.0)); + sum_dy_xmu_th += (c_offset < stride ? staging_sum_dy_xmu[address_base] : accscalar_t(0.0)); + } + + merge_block_vertical_backward(sum_dy_th, sum_dy_xmu_th, shmem_sum_dy, shmem_sum_dy_xmu); + if (threadIdx.y == 0 && c_offset < stride) { + if (grad_bias != nullptr) { + grad_bias[c_offset] = static_cast(sum_dy_th); + } + if (grad_weight != nullptr) { + grad_weight[c_offset] = static_cast(sum_dy_xmu_th * factor); + } + //mean_dy[c_offset] = sum_dy_th / reduction_size; + //mean_dy_xmu[c_offset] = sum_dy_xmu_th / reduction_size; + sum_dy_o[c_offset] = sum_dy_th; + sum_dy_xmu_o[c_offset] = sum_dy_xmu_th; + } + } + } else { + if (blockIdx.y == 0 && threadIdx.y == 0 && c_offset < stride) { + if (grad_bias != nullptr) { + grad_bias[c_offset] = static_cast(sum_dy_th); + } + if (grad_weight != nullptr) { + grad_weight[c_offset] = static_cast(sum_dy_xmu_th * factor); + } + //mean_dy[c_offset] = sum_dy_th / reduction_size; + //mean_dy_xmu[c_offset] = sum_dy_xmu_th / reduction_size; + sum_dy_o[c_offset] = sum_dy_th; + sum_dy_xmu_o[c_offset] = sum_dy_xmu_th; + } + } +} + +// elementwise BN kernel +// original apex name: batchnorm_backward_c_last_kernel +template < + int PARALLEL_LOADS, + typename scalar_t, + typename accscalar_t, + typename layerscalar_t> +__device__ __forceinline__ void batch_norm_backward_elemt_channels_last_kernel_impl( + const scalar_t* __restrict__ grad_output, + const scalar_t* __restrict__ input, + const accscalar_t* __restrict__ mean, + const accscalar_t* __restrict__ inv_std, + const layerscalar_t* __restrict__ weight, + const accscalar_t* __restrict__ sum_dy, + const accscalar_t* __restrict__ sum_dy_xmu, + scalar_t* __restrict__ grad_input, + const accscalar_t norm_fct, + const int reduction_size, + const int stride) { + // tensor dimension (m,c) + // loop along m dimension + int inner_loop_stride = blockDim.y * gridDim.y; + + // offset along m dimension + int m_offset = blockIdx.y * blockDim.y + threadIdx.y; + int c_offset = blockIdx.x * blockDim.x + threadIdx.x; + + if (c_offset >= stride || m_offset >= reduction_size) { + return; + } + + auto m_c = mean[c_offset]; + auto m_dy_c = sum_dy[c_offset] * norm_fct; + auto factor_1_c = inv_std[c_offset]; + auto factor_2_c = (weight == nullptr? accscalar_t(1.0) : static_cast(weight[c_offset])) * factor_1_c; + factor_1_c = factor_1_c * factor_1_c * sum_dy_xmu[c_offset] * norm_fct; + + int loop_count = 1 + (reduction_size - 1) / (inner_loop_stride * PARALLEL_LOADS); + int address_base = m_offset * stride + c_offset; + int address_increment = inner_loop_stride * stride; + + for (int i = 0; i < loop_count; i++) { +#pragma unroll + for (int j = 0; j < PARALLEL_LOADS; j++) { + if (c_offset < stride && m_offset < reduction_size) { + grad_input[address_base] = static_cast( + (static_cast(grad_output[address_base]) - m_dy_c - + (static_cast(input[address_base]) - m_c) * factor_1_c) + * factor_2_c); + } + m_offset += inner_loop_stride; + address_base += address_increment; + } + } +} + +template < + int PARALLEL_LOADS, + typename scalar_t, + typename accscalar_t, + typename layerscalar_t> +__global__ void batch_norm_backward_elemt_channels_last_kernel( + const scalar_t* __restrict__ grad_output, + const scalar_t* __restrict__ input, + const accscalar_t* __restrict__ mean, + const accscalar_t* __restrict__ inv_std, + const layerscalar_t* __restrict__ weight, + const accscalar_t* __restrict__ sum_dy, + const accscalar_t* __restrict__ sum_dy_xmu, + const int* __restrict__ numel, + scalar_t* __restrict__ grad_input, + const int64_t world_size, + const int reduction_size, + const int stride) { + + int64_t total_numel = 0; + for (int i = 0; i < world_size; i++) { + total_numel += numel[i]; + } + + auto norm_fct = static_cast(1) / static_cast(total_numel); + batch_norm_backward_elemt_channels_last_kernel_impl( + grad_output, input, mean, inv_std, weight, sum_dy, sum_dy_xmu, + grad_input, norm_fct, reduction_size, stride); +} + +template < + int PARALLEL_LOADS, + typename scalar_t, + typename accscalar_t, + typename layerscalar_t> +__global__ void batch_norm_backward_elemt_channels_last_kernel( + const scalar_t* __restrict__ grad_output, + const scalar_t* __restrict__ input, + const accscalar_t* __restrict__ mean, + const accscalar_t* __restrict__ inv_std, + const layerscalar_t* __restrict__ weight, + const accscalar_t* __restrict__ sum_dy, + const accscalar_t* __restrict__ sum_dy_xmu, + scalar_t* __restrict__ grad_input, + const accscalar_t norm_fct, + const int reduction_size, + const int stride) { + batch_norm_backward_elemt_channels_last_kernel_impl( + grad_output, input, mean, inv_std, weight, sum_dy, sum_dy_xmu, + grad_input, norm_fct, reduction_size, stride); +} + +template +void batch_norm_stats_channels_last_cuda_template( + const Tensor& out_mean, const Tensor& out_invstd, const Tensor& input, double epsilon) { + using accscalar_t = at::acc_type; + + const auto stride = input.sizes()[1]; + const auto reduction_size = input.numel() / stride; + + resize_output(out_mean, {stride}); + resize_output(out_invstd, {stride}); + TORCH_INTERNAL_ASSERT(out_invstd.dim() == 1 && out_invstd.is_contiguous() && + out_invstd.sizes()[0]); + TORCH_INTERNAL_ASSERT(out_mean.dim() == 1 && out_mean.is_contiguous() && + out_mean.sizes()[0]); + + dim3 block; + dim3 grid; + flexible_launch_configs(reduction_size, stride, block, grid, true); + + at::Tensor staging_data; + at::Tensor semaphores; + if (grid.y > 1) { + staging_data = at::empty({4*stride*grid.y}, out_mean.options()); + semaphores = at::zeros({grid.x}, input.options().dtype(at::kInt)); + } + + accscalar_t* staging_data_ptr = grid.y > 1 ? staging_data.mutable_data_ptr() : nullptr; + int* semaphores_ptr = grid.y > 1 ? semaphores.mutable_data_ptr() : nullptr; + batch_norm_collect_statistics_channels_last_kernel + <<>>( + input.const_data_ptr(), + out_mean.mutable_data_ptr(), + out_invstd.mutable_data_ptr(), + staging_data_ptr, + semaphores_ptr, + reduction_size, + stride, + epsilon); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +void batch_norm_elemt_channels_last_cuda_template( + const at::Tensor& output, + const at::Tensor& input, + const at::Tensor& weight, + const at::Tensor& shift, // bias of BN + const at::Tensor& mean, + const at::Tensor& inv_std, + const std::optional& z = std::nullopt, // bias after BN + const bool fuse_relu = false) { + const auto stride = input.sizes()[1]; + const auto reduction_size = input.numel() / stride; + + dim3 block; + dim3 grid; + flexible_launch_configs(reduction_size, stride, block, grid); + + auto stream = at::cuda::getCurrentCUDAStream(); + const auto second_dtype = weight.defined() ? weight.scalar_type() : + (shift.defined() ? shift.scalar_type() : input.scalar_type()); + + if (input.scalar_type() != second_dtype) { + AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, input.scalar_type(), "batchnorm_forward", [&] { + using accscalar_t = at::acc_type; + batch_norm_transform_input_channels_last_kernel + <<>>( + input.const_data_ptr(), + z.has_value() ? z.value().const_data_ptr() : nullptr, + mean.const_data_ptr(), + inv_std.const_data_ptr(), + weight.defined() ? weight.const_data_ptr() : nullptr, + shift.defined() ? shift.const_data_ptr() : nullptr, + output.mutable_data_ptr(), + reduction_size, + stride, + fuse_relu); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + }); + } else { + if (weight.defined()){ + TORCH_CHECK(input.scalar_type() == weight.scalar_type(), "batchnorm_forward: input.scalar_type() ", input.scalar_type(), + " is not supported with weight.scalar_type() ", weight.scalar_type()); + } + AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, input.scalar_type(), "batchnorm_forward", [&] { + using accscalar_t = at::acc_type; + batch_norm_transform_input_channels_last_kernel + <<>>( + input.const_data_ptr(), + z.has_value() ? z.value().const_data_ptr() : nullptr, + mean.const_data_ptr(), + inv_std.const_data_ptr(), + weight.defined() ? weight.const_data_ptr() : nullptr, + shift.defined() ? shift.const_data_ptr(): nullptr, + output.mutable_data_ptr(), + reduction_size, + stride, + fuse_relu); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + }); + } +} + +std::tuple +batch_norm_backward_reduce_cuda_channels_last_template(const at::Tensor& grad_output, + const at::Tensor& input, + const at::Tensor& mean, + const at::Tensor& inv_std, + const at::Tensor& weight, + const bool input_g, const bool weight_g, const bool bias_g) { + const auto stride = input.sizes()[1]; + const auto reduction_size = input.numel() / stride; + + at::Tensor sumn_dy = at::empty({stride}, mean.options()); + at::Tensor sum_dy_xmu = at::empty({stride}, mean.options()); + + at::Tensor grad_weight; + at::Tensor grad_bias; + if (weight.defined()) { + grad_weight = at::empty({stride}, weight.options()); + grad_bias = at::empty({stride}, weight.options()); + } else { + // because I cannot return an uninitialized at::Tensor + grad_weight = at::empty({0}, mean.options()); + grad_bias = at::empty({0}, mean.options()); + } + + dim3 block; + dim3 grid; + flexible_launch_configs(reduction_size, stride, block, grid, true); + + at::Tensor staging_data; + at::Tensor semaphores; + if (grid.y > 1) { + staging_data = at::empty({2*stride*grid.y}, mean.options()); + semaphores = at::zeros({grid.x}, input.options().dtype(at::kInt)); + } + auto stream = at::cuda::getCurrentCUDAStream(); + + if (weight.defined() && input.scalar_type() != weight.scalar_type()) { + AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, input.scalar_type(), "batchnorm_backward_reduce", [&] { + using accscalar_t = at::acc_type; + accscalar_t* staging_data_ptr = grid.y > 1 ? staging_data.mutable_data_ptr() : nullptr; + int* semaphores_ptr = grid.y > 1 ? semaphores.mutable_data_ptr() : nullptr; + batch_norm_backward_reduce_channels_last_kernel + <<>>( + input.const_data_ptr(), + grad_output.const_data_ptr(), + mean.const_data_ptr(), + inv_std.const_data_ptr(), + sumn_dy.mutable_data_ptr(), + sum_dy_xmu.mutable_data_ptr(), + grad_weight.mutable_data_ptr(), + grad_bias.mutable_data_ptr(), + staging_data_ptr, + semaphores_ptr, + reduction_size, + stride); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + }); + } else { + if (weight.defined()) { + TORCH_CHECK(input.scalar_type() == weight.scalar_type(), "batchnorm_backward_reduce: input.scalar_type() ", input.scalar_type(), + " is not supported with weight.scalar_type() ", weight.scalar_type()); + } + AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, input.scalar_type(), "batchnorm_backward_reduce", [&] { + using accscalar_t = at::acc_type; + accscalar_t* staging_data_ptr = grid.y > 1 ? staging_data.mutable_data_ptr() : nullptr; + int* semaphores_ptr = grid.y > 1 ? semaphores.mutable_data_ptr() : nullptr; + batch_norm_backward_reduce_channels_last_kernel + <<>>( + input.const_data_ptr(), + grad_output.const_data_ptr(), + mean.const_data_ptr(), + inv_std.const_data_ptr(), + sumn_dy.mutable_data_ptr(), + sum_dy_xmu.mutable_data_ptr(), + weight.defined() ? grad_weight.mutable_data_ptr() : nullptr, + weight.defined() ? grad_bias.mutable_data_ptr() : nullptr, + staging_data_ptr, + semaphores_ptr, + reduction_size, + stride); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + }); + } + + return std::make_tuple(sumn_dy, sum_dy_xmu, grad_weight, grad_bias); +} + +at::Tensor batch_norm_backward_elemt_channels_last_cuda_template( + const at::Tensor& grad_output, + const at::Tensor& input, + const at::Tensor& mean, + const at::Tensor& inv_std, + const at::Tensor& weight, + const at::Tensor& sum_dy, + const at::Tensor& sum_dy_xmu, + const at::Tensor& count) { + const auto stride = input.sizes()[1]; + const auto reduction_size = input.numel() / stride; + + // Input is guarunteed to be channels-last compatible + at::Tensor grad_input = at::empty_like(input); + + dim3 block; + dim3 grid; + flexible_launch_configs(reduction_size, stride, block, grid); + + auto stream = at::cuda::getCurrentCUDAStream(); + + if (weight.defined() && weight.scalar_type() != input.scalar_type()) { + AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, input.scalar_type(), "batchnorm_backward_element", [&] { + using accscalar_t = at::acc_type; + batch_norm_backward_elemt_channels_last_kernel + <<>>( + grad_output.const_data_ptr(), + input.const_data_ptr(), + mean.const_data_ptr(), + inv_std.const_data_ptr(), + weight.const_data_ptr(), + sum_dy.const_data_ptr(), + sum_dy_xmu.const_data_ptr(), + count.const_data_ptr(), + grad_input.mutable_data_ptr(), + count.numel(), + reduction_size, + stride); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + }); + } else { + if (weight.defined()) { + TORCH_CHECK(input.scalar_type() == weight.scalar_type(), "batchnorm_backward_element: input.scalar_type() ", input.scalar_type(), + " is not supported with weight.scalar_type() ", weight.scalar_type()); + } + AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, input.scalar_type(), "batchnorm_backward_element", [&] { + using accscalar_t = at::acc_type; + batch_norm_backward_elemt_channels_last_kernel + <<>>( + grad_output.const_data_ptr(), + input.const_data_ptr(), + mean.const_data_ptr(), + inv_std.const_data_ptr(), + weight.defined() ? weight.const_data_ptr() : nullptr, + sum_dy.const_data_ptr(), + sum_dy_xmu.const_data_ptr(), + count.const_data_ptr(), + grad_input.mutable_data_ptr(), + count.numel(), + reduction_size, + stride); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + }); + } + + return grad_input; +} + +at::Tensor batch_norm_backward_elemt_channels_last_cuda_template( + const at::Tensor& grad_output, + const at::Tensor& input, + const at::Tensor& mean, + const at::Tensor& inv_std, + const at::Tensor& weight, + const at::Tensor& sum_dy, + const at::Tensor& sum_dy_xmu) { + const auto stride = input.sizes()[1]; + const auto reduction_size = input.numel() / stride; + auto norm_fct = 1.0 / reduction_size; + + // Input is guarunteed to be channels-last compatible + at::Tensor grad_input = at::empty_like(input); + + dim3 block; + dim3 grid; + flexible_launch_configs(reduction_size, stride, block, grid); + + auto stream = at::cuda::getCurrentCUDAStream(); + + AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, input.scalar_type(), "batchnorm_backward_element", [&] { + using accscalar_t = at::acc_type; + + if (weight.defined() && weight.scalar_type() != input.scalar_type()) { + batch_norm_backward_elemt_channels_last_kernel + <<>>( + grad_output.const_data_ptr(), + input.const_data_ptr(), + mean.const_data_ptr(), + inv_std.const_data_ptr(), + weight.const_data_ptr(), + sum_dy.const_data_ptr(), + sum_dy_xmu.const_data_ptr(), + grad_input.mutable_data_ptr(), + static_cast(norm_fct), + reduction_size, + stride); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } else { + batch_norm_backward_elemt_channels_last_kernel + <<>>( + grad_output.const_data_ptr(), + input.const_data_ptr(), + mean.const_data_ptr(), + inv_std.const_data_ptr(), + weight.defined() ? weight.const_data_ptr() : nullptr, + sum_dy.const_data_ptr(), + sum_dy_xmu.const_data_ptr(), + grad_input.mutable_data_ptr(), + static_cast(norm_fct), + reduction_size, + stride); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } + }); + + return grad_input; +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/PersistentSoftmax.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/PersistentSoftmax.cuh new file mode 100644 index 0000000000000000000000000000000000000000..f0871fa0ead6fd19f31b45623864393741080b3e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/PersistentSoftmax.cuh @@ -0,0 +1,402 @@ +#pragma once + +#include +#include +#include +#include +#include + +#include + +namespace { + +int log2_ceil(int value) { + int log2_value = 0; + while ((1 << log2_value) < value) ++log2_value; + return log2_value; +} + +template +struct Add { + __device__ __forceinline__ T operator()(T a, T b) const { + return a + b; + } +}; + +template +struct Max { + __device__ __forceinline__ T operator()(T a, T b) const { + return a < b ? b : a; + } +}; + +template class ReduceOp> +__device__ __forceinline__ void warp_reduce(acc_t* sum) { + ReduceOp r; + #pragma unroll + for (int offset = WARP_SIZE / 2; offset > 0; offset /= 2) { + #pragma unroll + for (int i = 0; i < WARP_BATCH; ++i) { + acc_t b = WARP_SHFL_XOR(sum[i], offset, WARP_SIZE); + sum[i] = r(sum[i], b); + } + } +} + +// The softmax_warp_* methods perform softmax forward and backward propagation on samples spanning the fast dimension. +// Each sample contains element_count scalar elements. element_count can be any integer value <= 1024. +// The template arguments have the following meaning: +// One "WARP" works on one "BATCH". One "BATCH" contains "WARP_BATCH" samples. +// WARP_BATCH is equal to 1 when element_count is large, and > 1 when element_count is small. +// A "WARP" contains "C10_WARPS_SIZE" threads, these treads are guaranteed to belong to the same warp. +// This is important because it means only __shfl_ instructions are required for reductions. +// Note that this means WARP_SIZE must be a power of two and <= architecture warp size. +// CUDA warp size is 32 for all existing GPU architectures, but there is no guarantee this will not change for future arch. +// ROCm warp size is 64 for all currently ROCm-supported GPU architectures, but this may change for future archs. +// is_log_softmax is a flag indicating whether SoftMax or LogSoftMax should be computed. +// is_masked is a flag indicating whether SoftMax or MaskedSoftMax should be computed. +// The template can be instantiated with any floating point type for the type arguments input_t, output_t and acc_t. +// This allows SoftMax to be fused with a cast immediately following the SoftMax. +// The mask should have the same shape as input, with a boolean indicate if the value is masked. +// The head_chunk_size is only used for transformer mask softmax, equals to H * D * D. +// For instance: +// input_t=half, acc_t=float, output_t=half => read half tensor, float accumulators, write half tensor. +// input_t=half, acc_t=float, output_t=float => read half tensor, float accumulators, write float tensor. +// input_t_float, acc_t=float, output_t=half => read float tensor, float accumulators, write half tensor. + +template +__global__ void softmax_warp_forward(output_t *dst, const input_t *src, int batch_size, int stride, int element_count, const bool *mask = nullptr, const int head_chunk_size = -1, bool is_transformer_mask = false) +{ + // WARP_SIZE and WARP_BATCH must match the return values batches_per_warp and warp_size of method warp_softmax_forward_kernel. + constexpr int next_power_of_two = 1 << log2_elements; + constexpr int WARP_SIZE = (next_power_of_two < C10_WARP_SIZE) ? next_power_of_two : C10_WARP_SIZE; + constexpr int WARP_ITERATIONS = next_power_of_two / WARP_SIZE; + constexpr int WARP_BATCH = (next_power_of_two <= 128) ? 2 : 1; + + int first_batch = (blockDim.y * blockIdx.x + threadIdx.y) * WARP_BATCH; + + // batch_size might not be a multiple of WARP_BATCH. Check how + // many batches have to computed within this WARP. + int local_batches = batch_size - first_batch; + if (local_batches > WARP_BATCH) + local_batches = WARP_BATCH; + + // there might be multiple batches per warp. compute the index within the batch + int local_idx = threadIdx.x; + int idx_offset = first_batch * stride + local_idx; + + src += idx_offset; + dst += idx_offset; + + if (is_transformer_mask) { + mask += ((first_batch * stride) / head_chunk_size) * stride + local_idx; + } else { + mask += idx_offset; + } + // The nested loops over WARP_BATCH and then WARP_ITERATIONS can be simplified to one loop, + // but I think doing so would obfuscate the logic of the algorithm, thus I chose to keep + // the nested loops. + // This should have no impact on performance because the loops are unrolled anyway. + + // load data from global memory + acc_t elements[WARP_BATCH][WARP_ITERATIONS]; + for (int i = 0; i < WARP_BATCH; ++i) { + int batch_element_count = (i >= local_batches) ? 0 : element_count; + for (int it = 0; it < WARP_ITERATIONS; ++it) { + int element_index = local_idx + it * WARP_SIZE; + if (element_index < batch_element_count) { + elements[i][it] = src[i*element_count+it*WARP_SIZE]; + } else { + elements[i][it] = -std::numeric_limits::infinity(); + } + } + } + + // compute max_value + acc_t max_value[WARP_BATCH]; + #pragma unroll + for (int i = 0; i < WARP_BATCH; ++i) { + int batch_element_count = (i >= local_batches) ? 0 : element_count; + bool is_meaningful_max = false; + max_value[i] = elements[i][0]; + #pragma unroll + for (int it = 0; it < WARP_ITERATIONS; ++it) { + if (is_masked) { + int idx = it*WARP_SIZE; + if ((idx + local_idx) < batch_element_count) { + if (!is_transformer_mask) { + idx += i*element_count; + } + if (!mask[idx]) { + max_value[i] = (is_meaningful_max && max_value[i] > elements[i][it]) ? max_value[i] : elements[i][it]; + is_meaningful_max = true; + } + } + } else { + max_value[i] = max_value[i] > elements[i][it] ? max_value[i] : elements[i][it]; + } + } + if (is_masked) { + if (!is_meaningful_max) { + max_value[i] = -std::numeric_limits::infinity(); + } + } + } + warp_reduce(max_value); + + acc_t sum[WARP_BATCH] { 0.0f }; + #pragma unroll + for (int i = 0; i < WARP_BATCH; ++i) { + int batch_element_count = (i >= local_batches) ? 0 : element_count; + #pragma unroll + for (int it = 0; it < WARP_ITERATIONS; ++it) { + if (!is_masked) { + if (is_log_softmax) { + sum[i] += std::exp(elements[i][it] - max_value[i]); + } else { + elements[i][it] = std::exp(elements[i][it] - max_value[i]); + sum[i] += elements[i][it]; + } + } else { + int idx = it*WARP_SIZE; + bool valid = (idx + local_idx) < batch_element_count; + if (!is_transformer_mask) { + idx += i*element_count; + } + if (valid) { + if (!mask[idx]) { + if (is_log_softmax) { + sum[i] += std::exp(elements[i][it] - max_value[i]); + } else { + elements[i][it] = std::exp(elements[i][it] - max_value[i]); + sum[i] += elements[i][it]; + } + } else { + if (!is_log_softmax) { + // Masked values are treated as -infinity, and std::exp(-infinity) is 0. + elements[i][it] = 0; + } + } + } else { + if (!is_log_softmax) { + elements[i][it] = 0.; + } + } + } + } + } + warp_reduce(sum); + + // store result + #pragma unroll + for (int i = 0; i < WARP_BATCH; ++i) { + if (i >= local_batches) + break; + if (is_log_softmax) sum[i] = std::log(sum[i]); + #pragma unroll + for (int it = 0; it < WARP_ITERATIONS; ++it) { + int element_index = local_idx + it * WARP_SIZE; + if (element_index < element_count) { + if (is_log_softmax) { + dst[i*element_count+it*WARP_SIZE] = elements[i][it] - max_value[i] - sum[i]; + } else if (sum[i] == 0) { + dst[i*element_count+it*WARP_SIZE] = std::numeric_limits::quiet_NaN(); + } else { + dst[i*element_count+it*WARP_SIZE] = elements[i][it] / sum[i]; + } + } else { + break; + } + } + } +} + +template +__global__ void softmax_warp_backward(output_t *gradInput, const input_t *grad, const input_t *output, int batch_size, int stride, int element_count, const bool *mask = nullptr) +{ + // WARP_SIZE and WARP_BATCH must match the return values batches_per_warp and warp_size of method warp_softmax_backward_kernel. + constexpr int next_power_of_two = 1 << log2_elements; + constexpr int WARP_SIZE = (next_power_of_two < C10_WARP_SIZE) ? next_power_of_two : C10_WARP_SIZE; + constexpr int WARP_ITERATIONS = next_power_of_two / WARP_SIZE; + constexpr int WARP_BATCH = (next_power_of_two <= 128) ? 2 : 1; + + int first_batch = (blockDim.y * blockIdx.x + threadIdx.y) * WARP_BATCH; + + // batch_size might not be a multiple of WARP_BATCH. Check how + // many batches have to computed within this WARP. + int local_batches = batch_size - first_batch; + if (local_batches > WARP_BATCH) + local_batches = WARP_BATCH; + + // there might be multiple batches per warp. compute the index within the batch + int local_idx = threadIdx.x % WARP_SIZE; + + // the first element to process by the current thread + int thread_offset = first_batch * stride + local_idx; + grad += thread_offset; + output += thread_offset; + gradInput += thread_offset; + if (is_masked) { + mask += thread_offset; + } + + // The nested loops over WARP_BATCH and then WARP_ITERATIONS can be simplified to one loop, + // but I think doing so would obfuscate the logic of the algorithm, thus I chose to keep + // the nested loops. + // This should have no impact on performance because the loops are unrolled anyway. + + // load data from global memory + acc_t grad_reg[WARP_BATCH][WARP_ITERATIONS]; + acc_t output_reg[WARP_BATCH][WARP_ITERATIONS]; + for (int i = 0; i < WARP_BATCH; ++i) { + int batch_element_count = (i >= local_batches) ? 0 : element_count; + for (int it = 0; it < WARP_ITERATIONS; ++it) { + int element_index = local_idx + it * WARP_SIZE; + if (element_index < batch_element_count) { + grad_reg[i][it] = grad[i*element_count+it*WARP_SIZE]; + output_reg[i][it] = output[i*element_count+it*WARP_SIZE]; + } else { + grad_reg[i][it] = acc_t(0); + output_reg[i][it] = acc_t(0); + } + } + } + + acc_t sum[WARP_BATCH] { 0.0f }; + #pragma unroll + for (int i = 0; i < WARP_BATCH; ++i) { + #pragma unroll + for (int it = 0; it < WARP_ITERATIONS; ++it) { + if (!is_masked || !mask[i*element_count+it*WARP_SIZE]) { + sum[i] += grad_reg[i][it]; + } + } + } + warp_reduce(sum); + + // store result + #pragma unroll + for (int i = 0; i < WARP_BATCH; ++i) { + if (i >= local_batches) + break; + #pragma unroll + for (int it = 0; it < WARP_ITERATIONS; ++it) { + int element_index = local_idx + it * WARP_SIZE; + if (element_index < element_count) { + if (is_masked && mask[i*element_count+it*WARP_SIZE]) { + gradInput[i*element_count+it*WARP_SIZE] = 0; + } + // compute gradients + else if (is_log_softmax) { + gradInput[i*element_count+it*WARP_SIZE] = (grad_reg[i][it] - std::exp(output_reg[i][it]) * sum[i]); + } else { + gradInput[i*element_count+it*WARP_SIZE] = (grad_reg[i][it] - output_reg[i][it] * sum[i]); + } + } + } + } +} + +} // end of anonymous namespace + +template +void dispatch_softmax_forward(output_t *dst, const input_t *src, int softmax_elements, int softmax_elements_stride, int batch_count, const bool *mask = nullptr, int chunk_size = -1, bool is_transformer_mask = false) +{ + TORCH_INTERNAL_ASSERT( softmax_elements >= 0 && softmax_elements <= 2048 ); + if (softmax_elements == 0) { + return; + } else { + int log2_elements = log2_ceil(softmax_elements); + const int next_power_of_two = 1 << log2_elements; + + // This value must match the WARP_SIZE constexpr value computed inside softmax_warp_forward. + int warp_size = at::cuda::warp_size(); + warp_size = (next_power_of_two < warp_size) ? next_power_of_two : warp_size; + + // This value must match the WARP_BATCH constexpr value computed inside softmax_warp_forward. + int batches_per_warp = (next_power_of_two <= 128) ? 2 : 1; + + // use 128 threads per block to maximize gpu utilization + constexpr int threads_per_block = 128; + + int warps_per_block = (threads_per_block / warp_size); + int batches_per_block = warps_per_block * batches_per_warp; + int blocks = (batch_count + batches_per_block - 1) / batches_per_block; + dim3 threads(warp_size, warps_per_block, 1); + // Launch code would be more elegant if C++ supported FOR CONSTEXPR + switch (log2_elements) { + #define LAUNCH_SOFTMAX_WARP_FORWARD(L2E) case L2E: \ + softmax_warp_forward \ + <<>>(dst, \ + src, batch_count, softmax_elements_stride, softmax_elements, mask, chunk_size, is_transformer_mask); \ + C10_CUDA_KERNEL_LAUNCH_CHECK(); \ + break; + + LAUNCH_SOFTMAX_WARP_FORWARD(0); // 1 + LAUNCH_SOFTMAX_WARP_FORWARD(1); // 2 + LAUNCH_SOFTMAX_WARP_FORWARD(2); // 4 + LAUNCH_SOFTMAX_WARP_FORWARD(3); // 8 + LAUNCH_SOFTMAX_WARP_FORWARD(4); // 16 + LAUNCH_SOFTMAX_WARP_FORWARD(5); // 32 + LAUNCH_SOFTMAX_WARP_FORWARD(6); // 64 + LAUNCH_SOFTMAX_WARP_FORWARD(7); // 128 + LAUNCH_SOFTMAX_WARP_FORWARD(8); // 256 + LAUNCH_SOFTMAX_WARP_FORWARD(9); // 512 + LAUNCH_SOFTMAX_WARP_FORWARD(10); // 1024 + LAUNCH_SOFTMAX_WARP_FORWARD(11); // 2048 + default: + break; + } + } +} + +template +void dispatch_softmax_backward(output_t *grad_input, const input_t *grad, const input_t *output, int softmax_elements, int softmax_elements_stride, int batch_count, const bool *mask = nullptr) +{ + TORCH_INTERNAL_ASSERT( softmax_elements >= 0 && softmax_elements <= 1024 ); + if (softmax_elements == 0) { + return; + } else { + int log2_elements = log2_ceil(softmax_elements); + const int next_power_of_two = 1 << log2_elements; + + // This value must match the WARP_SIZE constexpr value computed inside softmax_warp_backward. + int warp_size = at::cuda::warp_size(); + warp_size = (next_power_of_two < warp_size) ? next_power_of_two : warp_size; + + // This value must match the WARP_BATCH constexpr value computed inside softmax_warp_backward. + int batches_per_warp = (next_power_of_two <= 128) ? 2 : 1; + + // use 128 threads per block to maximize gpu utilization + constexpr int threads_per_block = 128; + + int warps_per_block = (threads_per_block / warp_size); + int batches_per_block = warps_per_block * batches_per_warp; + int blocks = (batch_count + batches_per_block - 1) / batches_per_block; + dim3 threads(warp_size, warps_per_block, 1); + // Launch code would be more elegant if C++ supported FOR CONSTEXPR + switch (log2_elements) { + #define LAUNCH_SOFTMAX_WARP_BACKWARD(L2E) case L2E: \ + softmax_warp_backward \ + <<>> \ + (grad_input, grad, output, batch_count, softmax_elements_stride, \ + softmax_elements, mask); \ + C10_CUDA_KERNEL_LAUNCH_CHECK(); \ + break; + + LAUNCH_SOFTMAX_WARP_BACKWARD(0); // 1 + LAUNCH_SOFTMAX_WARP_BACKWARD(1); // 2 + LAUNCH_SOFTMAX_WARP_BACKWARD(2); // 4 + LAUNCH_SOFTMAX_WARP_BACKWARD(3); // 8 + LAUNCH_SOFTMAX_WARP_BACKWARD(4); // 16 + LAUNCH_SOFTMAX_WARP_BACKWARD(5); // 32 + LAUNCH_SOFTMAX_WARP_BACKWARD(6); // 64 + LAUNCH_SOFTMAX_WARP_BACKWARD(7); // 128 + LAUNCH_SOFTMAX_WARP_BACKWARD(8); // 256 + LAUNCH_SOFTMAX_WARP_BACKWARD(9); // 512 + LAUNCH_SOFTMAX_WARP_BACKWARD(10); // 1024 + default: + break; + } + } +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Pow.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Pow.cuh new file mode 100644 index 0000000000000000000000000000000000000000..dc9faf77f22a35960eb3ddd9f3c903af239206ed --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Pow.cuh @@ -0,0 +1,58 @@ +#pragma once +#include +#include + +namespace at::native { + +namespace { + + +// SFINAE doesn't work well with NVCC under Windows for math functions like pow and sqrt. +// So we need to define the functions with the explicit function signatures. +// As for pow, the following signatures are defined as the device function: +// pow(float, int) +// pow(double, int) +// pow(float, float) +// pow(double, double) +#ifdef _MSC_VER +// Functions for pow +// pow for at::Half +static inline __host__ __device__ at::Half pow_(at::Half base, at::Half exp) { + return static_cast(std::pow(static_cast(base), static_cast(exp))); +} +// pow for at::BFloat16 +static inline __host__ __device__ at::BFloat16 pow_(at::BFloat16 base, at::BFloat16 exp) { + return static_cast(std::pow(static_cast(base), static_cast(exp))); +} +// pow (floating, floating/int) +template +static inline __host__ __device__ typename std::enable_if_t && (std::is_same_v || std::is_same_v), Base_type> + pow_(Base_type base, Exp_type exp) { + return std::pow(base, exp); +} +// pow (Otherwise) +template +static inline __host__ __device__ typename std::enable_if_t && !std::is_same_v, Base_type> + pow_(Base_type base, Exp_type exp) { + return static_cast(std::pow(static_cast(base), static_cast(exp))); +} +#else +template +static inline __host__ __device__ Base_type pow_(Base_type base, Exp_type exp) { + return ::pow(base, exp); +} +#endif + +template +static inline __host__ __device__ std::enable_if_t, T> pow_( + T base, T exp) { + return at::native::powi(base, exp); +} + +template +static inline __host__ __device__ c10::complex pow_(c10::complex base, c10::complex exp) { + return c10_complex_math::pow(base, exp); +} + +} // namespace +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Randperm.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Randperm.cuh new file mode 100644 index 0000000000000000000000000000000000000000..bdcc5a576be593f9defebd95c0675a23ffc7e10f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Randperm.cuh @@ -0,0 +1,58 @@ +#include +#include +#include + +#include +#include +#include + +namespace { + +// See note [Algorithm of randperm] +template +__global__ void randperm_handle_duplicate_keys_kernel(T *keys, scalar_t *data, T mask, int n, at::PhiloxCudaState philox_args) { + int tid = threadIdx.x + blockDim.x * blockIdx.x; + + // find the beginning of islands + if (tid >= n - 1) return; // out of range + if ((keys[tid] & mask) != (keys[tid + 1] & mask)) return; // not in an island + if (tid != 0 && (keys[tid] & mask) == (keys[tid - 1] & mask)) return; // not the beginning of an island + + // find the size of islands + int island_size = 0; + do { island_size++; } + while ((tid + island_size < n) && (keys[tid + island_size] & mask) == (keys[tid] & mask)); + + // do random permutation inside each island. + data += tid; + const auto [seed, offset] = at::cuda::philox::unpack(philox_args); + curandStatePhilox4_32_10_t state; + curand_init(seed, tid, offset, &state); + for (int i = island_size - 1; i > 0; i--) { + unsigned int r = curand(&state) % (i + 1); + if (i != r) { + scalar_t tmp = data[i]; + data[i] = data[r]; + data[r] = tmp; + } + } +} + +// See note [Algorithm of randperm] +template +void randperm_handle_duplicate_keys(T *keys, scalar_t *data, int bits, int64_t n, std::optional &gen_) { + auto gen = at::get_generator_or_default(gen_, at::cuda::detail::getDefaultCUDAGenerator()); + int64_t counter_offset = n; + at::PhiloxCudaState rng_engine_inputs; + { + // See Note [Acquire lock when using random generators] + std::lock_guard lock(gen->mutex_); + rng_engine_inputs = gen->philox_cuda_state(counter_offset); + } + T mask = static_cast((1UL << bits) - 1); + randperm_handle_duplicate_keys_kernel<<<(n + 511) / 512, 512, 0, at::cuda::getCurrentCUDAStream()>>>( + keys, data, mask, n, rng_engine_inputs); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Reduce.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Reduce.cuh new file mode 100644 index 0000000000000000000000000000000000000000..2c25c413ead2fb2b5f5f0c8c9f878ba08250654d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Reduce.cuh @@ -0,0 +1,1395 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include + +namespace at::native { + +static inline int64_t div_up(int64_t a, int64_t b) { + return (a + b - 1) / b; +} + +// returns floor(log2(n)) +static inline int last_pow2(int n) { + n |= (n >> 1); + n |= (n >> 2); + n |= (n >> 4); + n |= (n >> 8); + n |= (n >> 16); + return std::max(1, n - (n >> 1)); +} + +// returns reduced fraction numerator & denominator +C10_HOST_DEVICE static void reduce_fraction(size_t &numerator, size_t &denominator) { + // get GCD of num and denom using Euclid's algorithm. + // Can replace this with std::gcd if we ever support c++17. + size_t a = denominator; + size_t b = numerator; + while (b != 0) { + a %= b; + // swap(a,b) + size_t tmp = a; + a = b; + b = tmp; + } + + // a is now the GCD + numerator /= a; + denominator /= a; +} + +//template for changing MAX_NUM_THREADS based on op dtype +template +struct mnt_wrapper { + static constexpr int MAX_NUM_THREADS = 512; +}; + +template <> +struct mnt_wrapper >{ + static constexpr int MAX_NUM_THREADS = 256; +}; + +constexpr int max_reduce_threads(c10::ScalarType type) { + return type == kComplexDouble ? 256 : 512; +} + +struct ReduceConfig { + static constexpr int BLOCK_X = 0; + static constexpr int BLOCK_Y = 1; + static constexpr int CTA = 2; + + ReduceConfig(int element_size_bytes, int num_outputs, int num_inputs) + : element_size_bytes(element_size_bytes) + , num_inputs(num_inputs) + , num_outputs(num_outputs) {} + int element_size_bytes; + int num_inputs; + int num_outputs; + int step_input = 1; + int step_output = 1; + int ctas_per_output = 1; + int input_mult[3] = {0, 0, 0}; + int output_mult[2] = {0, 0}; + + int block_width; + int block_height; + int num_threads; + + bool vectorize_input = false; + int output_vec_size = 1; + + template + void set_block_dimension(int64_t dim0, int64_t dim1) { + const int max_num_threads = mnt_wrapper::MAX_NUM_THREADS / output_vec_size; + int dim0_pow2 = dim0 < max_num_threads ? static_cast(last_pow2(dim0)) : max_num_threads; + int dim1_pow2 = dim1 < max_num_threads ? static_cast(last_pow2(dim1)) : max_num_threads; + block_width = std::min(dim0_pow2, int(at::cuda::warp_size())); + block_height = std::min(dim1_pow2, int(max_num_threads / block_width)); + block_width = std::min(dim0_pow2, int(max_num_threads / block_height)); + num_threads = block_width * block_height; + } + + int split_input(int parallelism) { + int step = step_input; + step_input *= parallelism; + return step; + } + + int split_output(int parallelism) { + int step = step_output; + step_output *= parallelism; + return step; + } + + dim3 block() const { + return dim3(block_width, block_height); + } + + dim3 grid() const { + return dim3(div_up(num_outputs / output_vec_size, step_output), ctas_per_output); + } + + C10_HOST_DEVICE bool should_block_x_reduce() const { + return input_mult[BLOCK_X] != 0; + } + + C10_HOST_DEVICE bool should_block_y_reduce() const { + return input_mult[BLOCK_Y] != 0; + } + + C10_HOST_DEVICE bool should_global_reduce() const { + return input_mult[CTA] != 0; + } + + C10_DEVICE bool should_store(int output_idx) const { + return output_idx < num_outputs && + (!should_block_x_reduce() || threadIdx.x == 0) && + (!should_block_y_reduce() || threadIdx.y == 0); + } + + C10_DEVICE bool should_reduce_tail() const { + return (!should_block_y_reduce() || threadIdx.y == 0) && + (!should_global_reduce() || blockIdx.y == 0); + } + + C10_HOST_DEVICE int input_idx() const { + int lane = threadIdx.x; + int warp = threadIdx.y; + int cta2 = blockIdx.y; + return (lane * input_mult[BLOCK_X] + + warp * input_mult[BLOCK_Y] + + cta2 * input_mult[CTA]); + } + + template + C10_HOST_DEVICE int output_idx() const { + int lane = threadIdx.x; + int warp = threadIdx.y; + int cta1 = blockIdx.x; + return (lane * output_mult[BLOCK_X] + + warp * output_mult[BLOCK_Y] + + cta1 * step_output) * output_vec_size; + } + + C10_DEVICE int shared_memory_offset(int offset) const { + return threadIdx.x + (threadIdx.y + offset) * blockDim.x; + } + + C10_DEVICE int staging_memory_offset(int cta2) const { + int offset = cta2 + blockIdx.x * gridDim.y; + if (!should_block_x_reduce()) { + offset = threadIdx.x + offset * blockDim.x; + } + return offset; + } + + int shared_memory_size() const { + if (!should_block_y_reduce() && + (!should_block_x_reduce() || + block_width <= at::cuda::warp_size())) { + return 0; + } + return element_size_bytes * num_threads * output_vec_size; + } + + int64_t global_memory_size() const { + if (!should_global_reduce()) { + return 0; + } + auto size = (int64_t)element_size_bytes * num_outputs * ctas_per_output; + if (!should_block_x_reduce()) { + size *= block().x * output_vec_size; + } + return size; + } + + int semaphore_size() const { + if (!should_global_reduce()) { + return 0; + } + return sizeof(int) * grid().x; + } + + int values_per_thread() const { + return div_up(num_inputs, step_input); + } +}; + +std::ostream& operator<<(std::ostream& out, const ReduceConfig& config); + +template +C10_LAUNCH_BOUNDS_2(nt, 4) +__global__ void reduce_kernel(R reduction) { + reduction.template run(); +} + +template +static OffsetCalculator<2, index_t> make_output_calculator(const TensorIterator& iter) { + int num_reduce_dims = iter.num_reduce_dims(); + int num_output_dims = iter.ndim() - num_reduce_dims; + int input_index = iter.ntensors() - 1; + int output_index = 0; + std::array strides = { + iter.strides(output_index).data() + num_reduce_dims, + iter.strides(input_index).data() + num_reduce_dims, + }; + auto shape = iter.shape().data() + num_reduce_dims; + return OffsetCalculator<2, index_t>(num_output_dims, shape, strides.data()); +} + +template +static OffsetCalculator<1, index_t> make_input_calculator(const TensorIterator& iter) { + int num_reduce_dims = iter.num_reduce_dims(); + int input_index = iter.ntensors() - 1; + std::array strides = { + iter.strides(input_index).data(), + }; + return OffsetCalculator<1, index_t>(num_reduce_dims, iter.shape().data(), strides.data()); +} + +template +struct func_wrapper_t { + using arg_t = typename binary_function_traits::arg1_t; + using scalar_t = typename binary_function_traits::arg2_t; + + func_t combine; + static inline __device__ out_scalar_t project(arg_t arg) { + return (out_scalar_t) arg; + } + static inline __device__ arg_t warp_shfl_down(arg_t arg, int offset) { + return WARP_SHFL_DOWN(arg, offset); + } + + static __device__ arg_t translate_idx(arg_t acc, int64_t /*idx*/) { + return acc; + } + + func_wrapper_t(const func_t& op) : combine(op) { + } + + // wrap a normal reduction that ignores the index + __device__ arg_t reduce(arg_t acc, scalar_t val, int64_t idx) const { + return combine(acc, val); + } +}; + +template +func_wrapper_t func_wrapper(const func_t& op) { + return func_wrapper_t { op }; +} + +template +struct ReduceJitOp { +//ReduceJitOp is almost like ReduceOp, but it doesn't have ops functor that specifies reduction operations +//Maybe we can find a way to unify ReduceOp and ReduceJitOp + using InputCalculator = OffsetCalculator<1, uint32_t>; + using OutputCalculator = OffsetCalculator<2, uint32_t>; + //TODO for now arg_t is always opmath_t of the input, later we'll need to change it + using arg_t = at::opmath_type; + + //TODO - ReduceJitOp will probably need to be changed for reductions that need full functor, + //not just wrapper + arg_t ident; + ReduceConfig config; + InputCalculator input_calc; + OutputCalculator output_calc; + const void* src; + const char* dst[2]; //it accepts at most two destinations + // acc_buf used for accumulation among sub Tensor Iterator when accumulation on + // output is not permissible + void* acc_buf; + // cta_buf used for accumulation between blocks during global reduction + void* cta_buf; + int* semaphores; + int64_t base_idx; + bool accumulate; + bool final_output; + int noutputs; + + ReduceJitOp( + ReduceConfig config, + InputCalculator input_calc, + OutputCalculator output_calc, + const void* src, + char* dst0, + std::optional dst1, + void* acc_buf, + void* cta_buf, + int* semaphores, + arg_t ident, + int noutputs, + int64_t base_idx) + : ident(ident), + config(config), + input_calc(input_calc), + output_calc(output_calc), + src(src), + acc_buf(acc_buf), + cta_buf(cta_buf), + semaphores(semaphores), + base_idx(base_idx), + noutputs(noutputs) { + dst[0] = dst0; + if (dst1.has_value()) { + dst[1] = dst1.value(); + } + } +}; + +template +struct ReduceOp { + using traits = function_traits; + using arg_t = typename std::decay::type>::type; + + using InputCalculator = OffsetCalculator<1, index_t>; + using OutputCalculator = OffsetCalculator<2, index_t>; + + static constexpr bool can_accumulate_in_output = + std::is_convertible_v + && std::is_convertible_v; + + ops_t ops; + arg_t ident; + ReduceConfig config; + InputCalculator input_calc; + OutputCalculator output_calc; + const void* src; + const char* dst[2]; //it accepts at most two destinations + // acc_buf used for accumulation among sub Tensor Iterator when accumulation on + // output is not permissible + void* acc_buf; + // cta_buf used for accumulation between blocks during global reduction + void* cta_buf; + int* semaphores; + int64_t base_idx; + bool accumulate; + bool final_output; + int noutputs; + + ReduceOp( + ops_t ops, + ReduceConfig config, + InputCalculator input_calc, + OutputCalculator output_calc, + const void* src, + char* dst0, + std::optional dst1, + void* acc_buf, + void* cta_buf, + int* semaphores, + arg_t ident, + int noutputs, + int64_t base_idx) + : ops(ops), + ident(ident), + config(config), + input_calc(input_calc), + output_calc(output_calc), + src(src), + acc_buf(acc_buf), + cta_buf(cta_buf), + semaphores(semaphores), + base_idx(base_idx), + noutputs(noutputs) { + dst[0] = dst0; + if (dst1.has_value()) { + dst[1] = dst1.value(); + } + } + + template + C10_DEVICE void run() const { + extern __shared__ char shared_memory[]; + index_t output_idx = config.output_idx(); + index_t input_idx = config.input_idx(); + auto base_offsets1 = output_calc.get(output_idx)[1]; + + using arg_vec_t = std::array; + arg_vec_t value; + + if (output_idx < config.num_outputs && input_idx < config.num_inputs) { + const scalar_t* input_slice = (const scalar_t*)((const char*)src + base_offsets1); + value = thread_reduce(input_slice); + } + + if (config.should_block_y_reduce()) { + value = block_y_reduce(value, shared_memory); + } + if (config.should_block_x_reduce()) { + value = block_x_reduce(value, shared_memory); + } + + using out_ptr_vec_t = std::array; + using offset_vec_t = std::array; + offset_vec_t base_offsets; + out_ptr_vec_t out; + + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + base_offsets[i] = output_calc.get(output_idx + i)[0]; + out[i] = (out_scalar_t*)((char*)dst[0] + base_offsets[i]); + } + + arg_vec_t* acc = nullptr; + if (acc_buf != nullptr) { + size_t numerator = sizeof(arg_t); + size_t denominator = sizeof(out_scalar_t); + reduce_fraction(numerator, denominator); + acc = (arg_vec_t*)((char*)acc_buf + (base_offsets[0] * numerator / denominator)); + } + + if (config.should_global_reduce()) { + value = global_reduce(value, acc, shared_memory); + } else if (config.should_store(output_idx)) { + if (accumulate) { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = ops.translate_idx(value[i], base_idx); + } + } + + if (acc == nullptr) { + if (accumulate) { + value = accumulate_in_output(out, value); + } + if (final_output) { + set_results_to_output(value, base_offsets); + } else { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + *(out[i]) = get_accumulated_output(out[i], value[i]); + } + } + } else { + if (accumulate) { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = ops.combine((*acc)[i], value[i]); + } + } + if (final_output) { + set_results_to_output(value, base_offsets); + } else { + *acc = value; + } + } + } + } + + template + C10_DEVICE std::array thread_reduce(const scalar_t* data) const { + if (config.vectorize_input) { + CUDA_KERNEL_ASSERT(output_vec_size == 1); + // reduce at the header of input_slice where memory is not aligned, + // so that thread_reduce will have an aligned memory to work on. + return {input_vectorized_thread_reduce_impl(data)}; + } else { + index_t element_stride = input_calc.strides_[0][0] / sizeof(scalar_t); + bool is_contiguous = (input_calc.dims == 1 && element_stride == 1); + if (is_contiguous) { + return thread_reduce_impl(data, [](index_t idx) { return idx; }); + } else if (input_calc.dims == 1) { + return thread_reduce_impl(data, [&](index_t idx) { return idx * element_stride; }); + } else { + return thread_reduce_impl(data, [&](index_t idx) { return input_calc.get(idx)[0] / sizeof(scalar_t); }); + } + } + } + + C10_DEVICE arg_t input_vectorized_thread_reduce_impl(const scalar_t* data) const { + index_t end = config.num_inputs; + + // Handle the head of input slice where data is not aligned + arg_t value = ident; + constexpr int align_bytes = alignof(at::native::memory::aligned_vector); + constexpr int align_elements = align_bytes / sizeof(scalar_t); + int shift = ((uint64_t)data) % align_bytes / sizeof(scalar_t); + if (shift > 0) { + data -= shift; + end += shift; + if(threadIdx.x >= shift && threadIdx.x < align_elements && config.should_reduce_tail()){ + value = ops.reduce(value, c10::load(data + threadIdx.x), threadIdx.x - shift); + } + end -= align_elements; + data += align_elements; + shift = align_elements - shift; + } + + // Do the vectorized reduction + using load_t = at::native::memory::aligned_vector; + + index_t idx = config.input_idx(); + const index_t stride = config.step_input; + + // Multiple accumulators to remove dependency between unrolled loops. + arg_t value_list[input_vec_size]; + value_list[0] = value; + + #pragma unroll + for (int i = 1; i < input_vec_size; i++) { + value_list[i] = ident; + } + + while (idx * input_vec_size + input_vec_size - 1 < end) { + const auto values_vec = memory::load_vector(data, idx); + #pragma unroll + for (index_t i = 0; i < input_vec_size; i++) { + value_list[i] = ops.reduce(value_list[i], values_vec.val[i], shift + idx * input_vec_size + i); + } + idx += stride; + } + + // tail + index_t tail_start = end - end % input_vec_size; + if (config.should_reduce_tail()) { + int idx = tail_start + threadIdx.x; + if (idx < end) { + const auto value = c10::load(data + idx); + value_list[0] = ops.reduce(value_list[0], value, idx + shift); + } + } + + // combine accumulators + #pragma unroll + for (int i = 1; i < input_vec_size; i++) { + value_list[0] = ops.combine(value_list[0], value_list[i]); + } + return value_list[0]; + } + + template + C10_DEVICE std::array thread_reduce_impl(const scalar_t* data_, offset_calc_t calc) const { + index_t idx = config.input_idx(); + const index_t end = config.num_inputs; + const index_t stride = config.step_input; + + using arg_vec_t = std::array; + using load_t = at::native::memory::aligned_vector; + + // Multiple accumulators to remove dependency between unrolled loops. + arg_vec_t value_list[vt0]; + + #pragma unroll + for (int i = 0; i < vt0; i++) { + #pragma unroll + for (int j = 0; j < output_vec_size; j++) { + value_list[i][j] = ident; + } + } + + load_t values[vt0]; + + while (idx + (vt0 - 1) * stride < end) { + #pragma unroll + for (index_t i = 0; i < vt0; i++) { + const auto offset = calc(idx + i * stride) / output_vec_size; + values[i] = memory::load_vector(data_, offset); + } + #pragma unroll + for (index_t i = 0; i < vt0; i++) { + #pragma unroll + for (index_t j = 0; j < output_vec_size; j++) { + value_list[i][j] = ops.reduce(value_list[i][j], values[i].val[j], idx + i * stride); + } + } + idx += stride * vt0; + } + + // tail + int idx_ = idx; + #pragma unroll + for (index_t i = 0; i < vt0; i++) { + if (idx >= end) { + break; + } + const auto offset = calc(idx) / output_vec_size; + values[i] = memory::load_vector(data_, offset); + idx += stride; + } + idx = idx_; + #pragma unroll + for (index_t i = 0; i < vt0; i++) { + if (idx >= end) { + break; + } + #pragma unroll + for (index_t j = 0; j < output_vec_size; j++) { + value_list[i][j] = ops.reduce(value_list[i][j], values[i].val[j], idx); + } + idx += stride; + } + + // combine accumulators + #pragma unroll + for (int i = 1; i < vt0; i++) { + #pragma unroll + for (index_t j = 0; j < output_vec_size; j++) { + value_list[0][j] = ops.combine(value_list[0][j], value_list[i][j]); + } + } + return value_list[0]; + } + + template + C10_DEVICE std::array block_x_reduce(std::array value, char* shared_memory) const { + using args_vec_t = std::array; + int dim_x = blockDim.x; + args_vec_t* shared = (args_vec_t*)shared_memory; + if (dim_x > warpSize) { + int address_base = threadIdx.x + threadIdx.y*blockDim.x; + shared[address_base] = value; + for (int offset = dim_x/2; offset >= warpSize; offset >>= 1) { + __syncthreads(); + if (threadIdx.x < offset && threadIdx.x + offset < blockDim.x) { + args_vec_t other = shared[address_base + offset]; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = ops.combine(value[i], other[i]); + } + shared[address_base] = value; + } + } + dim_x = warpSize; + } + + __syncthreads(); + + for (int offset = 1; offset < dim_x; offset <<= 1) { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + arg_t other = ops.warp_shfl_down(value[i], offset); + value[i] = ops.combine(value[i], other); + } + } + return value; + } + + template + C10_DEVICE std::array block_y_reduce(std::array value, char* shared_memory) const { + using args_vec_t = std::array; + args_vec_t* shared = (args_vec_t*)shared_memory; + shared[config.shared_memory_offset(0)] = value; + for (int offset = blockDim.y / 2; offset > 0; offset >>= 1) { + __syncthreads(); + if (threadIdx.y < offset && threadIdx.y + offset < blockDim.y) { + args_vec_t other = shared[config.shared_memory_offset(offset)]; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = ops.combine(value[i], other[i]); + } + shared[config.shared_memory_offset(0)] = value; + } + } + return value; + } + + C10_DEVICE bool mark_block_finished() const { + __shared__ bool is_last_block_done_shared; + + __syncthreads(); + if (threadIdx.x == 0 && threadIdx.y == 0) { + int prev_blocks_finished = atomicAdd(&semaphores[blockIdx.x], 1); + is_last_block_done_shared = (prev_blocks_finished == gridDim.y - 1); + } + + __syncthreads(); + + return is_last_block_done_shared; + } + + template + C10_DEVICE std::array accumulate_in_output( + std::array out, + std::array value, + typename std::enable_if_t* = nullptr + ) const { + std::array ret; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + ret[i] = ops.combine(*(out[i]), value[i]); + } + return ret; + } + + template + C10_DEVICE out_scalar_t get_accumulated_output( + out_scalar_t* out, arg_t value, + typename std::enable_if_t* = nullptr + ) const { + CUDA_KERNEL_ASSERT(!final_output); + return (out_scalar_t)value; + } + + // This function should never be called -- + // it's the version of `accumulate_in_output` + // when accumulation in the output is not possible. + template + C10_DEVICE std::array accumulate_in_output( + std::array, + std::array, + typename std::enable_if_t* = nullptr + ) const { + CUDA_KERNEL_ASSERT(false); + return {arg_t{}}; + } + + // This function should never be called -- + // it's the version of `get_accumulated_output` + // when accumulation in the output is not possible. + template + C10_DEVICE out_scalar_t get_accumulated_output( + out_scalar_t* out, arg_t value, + typename std::enable_if_t* = nullptr + ) const { + CUDA_KERNEL_ASSERT(false); + return *out; + } + + template + C10_DEVICE void set_results(const T x, const index_t base_offset) const { + CUDA_KERNEL_ASSERT(noutputs == 1); + auto res = (out_scalar_t*)((char*)dst[0] + base_offset); + *res = x; + } + + //Currently implemented for max of two outputs + template + C10_DEVICE void set_results(const thrust::pair x, const index_t base_offset) const { + if (noutputs >= 1) { + auto res0 = (T1*)((char*)dst[0] + base_offset); + *res0 = x.first; + } + if (noutputs >= 2) { + // base offset is computed assuming element size being sizeof(T1), so we need to make a + // correction to obtain the correct base offset + auto res1 = (T2*) ((char *) dst[1] + base_offset / sizeof(T1) * sizeof(T2)); + *res1 = x.second; + } + } + + template + C10_DEVICE void set_results_to_output(std::array value, std::array base_offset) const { + CUDA_KERNEL_ASSERT(final_output); + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + set_results(ops.project(value[i]), base_offset[i]); + } + } + + template + C10_DEVICE std::array global_reduce(std::array value, std::array *acc, char* shared_memory) const { + using arg_vec_t = std::array; + using out_ptr_vec_t = std::array; + using offset_vec_t = std::array; + + arg_vec_t* reduce_buffer = (arg_vec_t*)cta_buf; + index_t output_idx = config.output_idx(); + offset_vec_t base_offsets; + out_ptr_vec_t out; + + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + base_offsets[i] = output_calc.get(output_idx + i)[0]; + out[i] = (out_scalar_t*)((char*)dst[0] + base_offsets[i]); + } + + bool should_store = config.should_store(output_idx); + if (should_store) { + index_t offset = config.staging_memory_offset(blockIdx.y); + reduce_buffer[offset] = value; + } + + __threadfence(); // make sure writes are globally visible + __syncthreads(); // if multiple warps in this block wrote to staging, make sure they're all done + bool is_last_block_done = mark_block_finished(); + + if (is_last_block_done) { + __threadfence(); // complete the acquire pattern after atomic + for (auto &v : value) { + v = ident; + } + if (config.should_block_x_reduce()) { + index_t input_offset = threadIdx.x + threadIdx.y * blockDim.x; + index_t step = blockDim.x * blockDim.y; + for (; input_offset < config.ctas_per_output; input_offset += step) { + index_t idx = config.staging_memory_offset(input_offset); + arg_vec_t next = reduce_buffer[idx]; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = ops.combine(value[i], next[i]); + } + } + } else { + index_t input_offset = threadIdx.y; + index_t step = blockDim.y; + for (; input_offset < config.ctas_per_output; input_offset += step) { + index_t idx = config.staging_memory_offset(input_offset); + arg_vec_t next = reduce_buffer[idx]; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = ops.combine(value[i], next[i]); + } + } + } + value = block_y_reduce(value, shared_memory); + if (config.should_block_x_reduce()) { + value = block_x_reduce(value, shared_memory); + } + if (should_store) { + if (accumulate) { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = ops.translate_idx(value[i], base_idx); + } + } + + if (acc == nullptr) { + if (accumulate) { + value = accumulate_in_output(out, value); + } + if (final_output) { + set_results_to_output(value, base_offsets); + } else { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + *(out[i]) = get_accumulated_output(out[i], value[i]); + } + } + } else { + if (accumulate) { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = ops.combine((*acc)[i], value[i]); + } + } + if (final_output) { + set_results_to_output(value, base_offsets); + } else { + *acc = value; + } + } + } + } + + return value; + } +}; + +template +static void launch_reduce_kernel(const ReduceConfig& config, const R& reduction) { + dim3 block = config.block(); + dim3 grid = config.grid(); + + auto stream = at::cuda::getCurrentCUDAStream(); + int shared_memory = config.shared_memory_size(); + + switch(config.output_vec_size) { + case 4: + reduce_kernel<<>>(reduction); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + break; + case 2: + reduce_kernel<<>>(reduction); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + break; + default: + reduce_kernel<<>>(reduction); + C10_CUDA_KERNEL_LAUNCH_CHECK(); + } +} + +inline void launch_jitted_reduce_kernel( + std::mutex &jiterator_mutex, + std::array &fn_cache, + const at::cuda::jit::KernelDescriptor &desc, + int vt0, const ReduceConfig& config, const void *reduction) { + dim3 block = config.block(); + dim3 grid = config.grid(); + + int shared_memory = config.shared_memory_size(); + at::cuda::jit::NvrtcFunction* fn_ptr; + switch(config.output_vec_size) { + case 4: + fn_ptr = &fn_cache[0]; + break; + case 2: + fn_ptr = &fn_cache[1]; + break; + default: + fn_ptr = &fn_cache[2]; + } + if (!fn_ptr->function) { + int max_threads_codegen = + max_reduce_threads(desc.f_inputs_type) / config.output_vec_size; + auto code = at::cuda::jit::generate_reduction_code( + desc, vt0, true, false, config.output_vec_size, max_threads_codegen); + + *fn_ptr = at::cuda::jit::jit_pwise_function(code, "reduction_" + desc.name); + } + constexpr int kernel_args = 1; + const void* args[kernel_args]; + args[0] = reduction; + at::cuda::jit::launch_jitted_pwise_function(*fn_ptr, args, grid, block, shared_memory); +} + + +class AccumulationBuffer { + public: + AccumulationBuffer() {} + + AccumulationBuffer(size_t acc_t_size, size_t out_t_size, char* out_ptr, int64_t size) { + out_ptr_ = (char*)out_ptr; + if (out_t_size >= acc_t_size) { + // reusing output buffer for accumulation. + acc_ptr_ = (char*)out_ptr; + numerator_ = 1; + denominator_ = 1; + } else { + auto& allocator = *c10::cuda::CUDACachingAllocator::get(); + buffer_ = allocator.allocate(size); + acc_ptr_ = (char*)buffer_.get(); + numerator_ = acc_t_size; + denominator_ = out_t_size; + reduce_fraction(numerator_, denominator_); + } + } + + char* get_acc_slice(char* out_ptr) { + if (acc_ptr_ == nullptr) { + return nullptr; + } + return acc_ptr_ + ((out_ptr - out_ptr_) * numerator_ / denominator_); + } + + private: + char* acc_ptr_ = nullptr; + char* out_ptr_ = nullptr; + size_t numerator_; + size_t denominator_; + at::DataPtr buffer_; +}; + +template +int get_output_vec_size(const TensorIterator &iter) { + int vec_size = 4; + auto update_vec_size = [&vec_size](uint64_t n) { + while(n % vec_size != 0) { + vec_size /= 2; + } + }; + + uint64_t base_address = reinterpret_cast(iter.data_ptr(iter.noutputs())) / sizeof(scalar_t); + update_vec_size(base_address); + + const int output_index = iter.num_reduce_dims(); + update_vec_size(iter.shape()[output_index]); + + int j = 0; + for(auto i : iter.strides(iter.noutputs())) { + if (j != output_index) { + update_vec_size(i / sizeof(scalar_t)); + } + j++; + } + return vec_size; +} + +template +ReduceConfig setReduceConfig(const TensorIterator& iter){ + // Start by assuming that each thread handles a single output and all + // the inputs for that output. + int64_t num_outputs = iter.num_output_elements(); + int64_t inputs_per_output = iter.numel() / num_outputs; + int input_index = iter.ntensors() - 1; + + auto config = ReduceConfig(sizeof(arg_t), num_outputs, inputs_per_output); + + int64_t dim0; + int64_t dim1; + int64_t fastest_moving_stride; + bool reduction_on_fastest_striding_dimension; + + if (iter.ndim() > 0) { + // Adjust block size to map block width to fastest changing dimension of input + // tensor. This grants the best possible memory accessing pattern, given that + // for non-contiguous tensor with space in between, we cannot have perfect + // memory coalescing. + reduction_on_fastest_striding_dimension = + (iter.num_reduce_dims() == iter.ndim()) || + (iter.strides(/*arg=*/input_index)[0] < + iter.strides(/*arg=*/input_index)[iter.num_reduce_dims()]); + // Notice that dim0 & dim1 does NOT guarantee any launch configuration here! + // dim0 & dim1 are more like the upper bound of the block dimension. The + // actual launch config and reduction scheme is determined by setting values + // to `config.input_mult` and `config.output_mult`. + // We try to max out dim1 so that we have enough threads per CTA to deliver + // performance for larger problem size. + if (reduction_on_fastest_striding_dimension) { + // Map block.x to the fastest reducing dimension. It implies: + // 1. block_x_reduce is required. + // 2. block.y now max out to num_outputs. + dim0 = inputs_per_output; + dim1 = num_outputs; + fastest_moving_stride = iter.strides(/*arg=*/input_index)[0]; + } else { + // Map block.x to the fastest non reducing dimension. It implies: + // 1. block_x_reduce is turned off. + // 2. block.y now max out to inputs_per_output. + dim0 = num_outputs; + dim1 = inputs_per_output; + fastest_moving_stride = iter.strides(/*arg=*/input_index)[iter.num_reduce_dims()]; + } + } else { + reduction_on_fastest_striding_dimension = true; + fastest_moving_stride = sizeof(scalar_t); + dim0 = 1; + dim1 = 1; + } + + // We do vectorization to gain better memory access, there are two cases which we call + // "vectorize along input" and "vectorize along output". Note that the "input/output" + // here does not mean we are vectorizing load/store instructions. We always only vectorize + // load instructions. + // + // Case 1: "vectorize along input" + // This case happens when we are reducing along fastest moving dimesion. In such case, threads + // with the same threadIdx.y works on the same reduction cooperatively and will produce results + // for the same output. In such case, values in each loaded vector always correspond to the same output. + // + // Case 2: "vectorize along output" + // This case happens when the fastest moving dimesion is not the dimension of reduction. In such case, + // threads with different threadIdx.x are independent and will produce results for different outputs. + // In such case, values in each loaded vector always correspond to different outputs. + if (fastest_moving_stride == sizeof(scalar_t)) { +#ifdef USE_ROCM + if (reduction_on_fastest_striding_dimension && dim0 > 128 && iter.num_reduce_dims() == 1) { +#else + if (reduction_on_fastest_striding_dimension && dim0 > 128 && iter.num_reduce_dims() == 1 && vt0 >= input_vec_size) { +#endif + // Case 1: "vectorize along input" + // Note that if vt0 < ReduceConfig::vec_size, then this means the register pressure could be high, in such case, + // we should avoid vectorization. + config.vectorize_input = true; + dim0 /= input_vec_size; + } else if (!reduction_on_fastest_striding_dimension) { + // Case 2: "vectorize along output" + config.output_vec_size = get_output_vec_size(iter); + dim0 /= config.output_vec_size; + } + } + + // Adjust block_width and block_height + config.set_block_dimension(dim0, dim1); + + int block_width = config.block_width; + int block_height = config.block_height; + + if (iter.ndim() == 0 || reduction_on_fastest_striding_dimension) { + // Split the input across lanes if the input is contiguous in the reduced + // dimension. This will require reduction between threads using warp + // shuffle instructions and shared memory (if block_width > warpSize). + config.input_mult[0] = config.split_input(block_width); + } else { + // Otherwise split the output across lanes in a warp. + config.output_mult[0] = config.split_output(block_width); + } + + constexpr int min_values_per_thread = 16; + constexpr int max_values_per_thread = 256; + + const int warp_split_threshold = + std::min(block_height * 16, max_values_per_thread); + bool split_across_warps = config.values_per_thread() >= warp_split_threshold; + const int num_mp = + at::cuda::getCurrentDeviceProperties()->multiProcessorCount; +#ifdef USE_ROCM + bool force_splitting_output = iter.ndim() == 2 && + reduction_on_fastest_striding_dimension && + config.values_per_thread() < 1024 && num_mp < 100; + split_across_warps = !force_splitting_output && split_across_warps; +#endif + + if (split_across_warps) { + // Divide the input across warps in a thread-block, if that leaves at least + // 16 elements to be summed by each thread. This will require inter-warp + // reduction using shared memory. + config.input_mult[1] = config.split_input(block_height); + } else { + // Otherwise, each warp handles a separate output. + config.output_mult[1] = config.split_output(block_height); + } + + int max_threads_per_mp = + at::cuda::getCurrentDeviceProperties()->maxThreadsPerMultiProcessor; +#ifdef USE_ROCM + // Control the number of threadblocks by adjusting the maximum number of + // threads per multi-processor. These numbers better reflect the maximum + // theoretical achievable threads per MP for the reduction operation. + if (iter.ndim() == 1 || iter.ndim() == 3) + max_threads_per_mp = 512; + if (iter.ndim() == 2) + max_threads_per_mp = 256; +#endif + const int blocks_per_sm = max_threads_per_mp / config.num_threads; + const int target_grid_size = num_mp * blocks_per_sm; + int grid = config.grid().x; + if (config.input_mult[1] != 0 && config.values_per_thread() >= max_values_per_thread && grid <= target_grid_size) { + // Divide the input across thread-blocks if the amount of work per-thread + // is large enough and the size of the output is small enough. This will + // require a reduction using global memory. + // If we decide to split input across blocks, as long as we can get enough + // number of blocks (`target_grid_size`) to balance SM, we should still + // make the number of values per thread large for best performance. + int ctas_per_output1 = div_up(target_grid_size, grid); + int ctas_per_output2 = div_up(config.values_per_thread(), min_values_per_thread); + int ctas_per_output3 = div_up(config.values_per_thread(), max_values_per_thread); + // We want the minimum of ctas_per_output1 and ctas_per_output2, so that each thread can have + // a large number of values to deal with. But we don't want values_per_thread to be larger than + // max_values_per_thread + config.ctas_per_output = std::max(std::min(ctas_per_output1, ctas_per_output2), ctas_per_output3); +#ifdef USE_ROCM + // In cases where a number of threadblocks along the y direction of the grid + // is needed then make sure they are reduced to the number of MPs. For + // smaller sizes, use half the number of MPs. For smaller sizes than half + // the number of MPs use the original value unless the value is less than 16 + // blocks in which case it is more profitable to use just 1 block. + if (config.ctas_per_output > num_mp) + if (num_mp < 128) + config.ctas_per_output = + num_mp * (config.ctas_per_output > 512 ? 4 : 2); + else + config.ctas_per_output = num_mp; + else if (config.ctas_per_output > div_up(num_mp, 2)) + config.ctas_per_output = div_up(num_mp, 2); + else if (config.ctas_per_output < 16) + config.ctas_per_output = 1; + if (iter.ndim() == 3 && !reduction_on_fastest_striding_dimension) + config.ctas_per_output = 4; +#endif + if (config.ctas_per_output > 1) { + config.input_mult[2] = config.split_input(config.ctas_per_output); + } + } + return config; +}; + +template +inline void gpu_reduce_kernel(TensorIterator& iter, const ops_t& ops, ident_t ident=0, + AccumulationBuffer* acc_buf_ptr=nullptr, int64_t base_idx=0) { + AT_ASSERT(iter.numel() > 0 && iter.ntensors() - iter.noutputs() == 1 && iter.noutputs() >= 1); + + using traits = function_traits; + using arg_t = typename traits::template arg<0>::type; + // at::Half/at::ComplexHalf overflows easily as it's range is very small. + // So when scalar_t and out_scalar_t are at::Half/at::ComplexHalf, we + // set can_accumulate_in_output to False. + static constexpr bool is_inp_out_type_half_or_chalf = + (std::is_same_v && + std::is_same_v) || + (std::is_same_v, scalar_t> && + std::is_same_v, out_scalar_t>); + // at::BFloat16 has lower precision and can lead to rounding errors. + // So when scalar_t and out_scalar_t are at::BFloat16, we + // set can_accumulate_in_output to False. + static constexpr bool is_inp_out_type_bfloat16 = + (std::is_same_v && + std::is_same_v); + static constexpr bool can_accumulate_in_output = + std::is_convertible_v && + !(is_inp_out_type_half_or_chalf || is_inp_out_type_bfloat16); + + bool can_use_32bit_indexing = iter.can_use_32bit_indexing(); + std::unique_ptr owned_buf_ptr; + // The acc_buf_ptr is a shared pointer. It is create at the first entrance and + // reused by all recursive function calls. + if (acc_buf_ptr == NULL) { + // acc_buf_ptr holds buffer used for accumulation among multiple sub_iter + // when accumulation in output is not possible. + if (!can_accumulate_in_output && !can_use_32bit_indexing) { + int64_t output_memory_size = iter.element_size(0); + for (int dim = 0; dim < iter.ndim(); dim++) { + output_memory_size = std::max(output_memory_size, iter.shape()[dim] * iter.strides(0)[dim]); + } + output_memory_size /= iter.element_size(0); //iter.strides is in bytes + owned_buf_ptr.reset(new AccumulationBuffer(sizeof(arg_t), + sizeof(out_scalar_t), + (char*) iter.data_ptr(0), + output_memory_size * sizeof(arg_t))); + } else { + owned_buf_ptr.reset(new AccumulationBuffer()); + } + acc_buf_ptr = owned_buf_ptr.get(); + } + + if (!can_use_32bit_indexing) { + for (auto& sub_iter : iter.with_32bit_indexing()) { + int64_t sub_iter_base_idx = sub_iter.view_offsets()[0]; + + gpu_reduce_kernel(sub_iter, ops, ident, + acc_buf_ptr, sub_iter_base_idx); + } + return; + } + + const char* in_data = (char*)iter.data_ptr(iter.ntensors() - 1); + char* out_data = (char*)iter.data_ptr(0); + const auto noutputs = iter.noutputs(); + std::optional out_data_extra; + if (noutputs > 1) { + out_data_extra = (char*)iter.data_ptr(1); + } else { + out_data_extra = std::nullopt; + } + char* acc_data = acc_buf_ptr->get_acc_slice(out_data); + + ReduceConfig config = setReduceConfig(iter); + at::DataPtr buffer; + at::DataPtr semaphores; + if (config.should_global_reduce()) { + auto& allocator = *c10::cuda::CUDACachingAllocator::get(); + buffer = allocator.allocate(config.global_memory_size()); + semaphores = allocator.allocate(config.semaphore_size()); + + auto stream = at::cuda::getCurrentCUDAStream(); + AT_CUDA_CHECK(cudaMemsetAsync(semaphores.get(), 0, config.semaphore_size(), stream)); + } + + AT_ASSERT(can_use_32bit_indexing); + auto output_calc = make_output_calculator(iter); + auto input_calc = make_input_calculator(iter); + auto reduce = ReduceOp( + ops, + config, + input_calc, + output_calc, + in_data, + out_data, + out_data_extra, + acc_data, + buffer.get(), + (int*)semaphores.get(), + ident, + noutputs, + base_idx); + reduce.accumulate = iter.should_accumulate(); + reduce.final_output = iter.is_final_output(); + + launch_reduce_kernel::MAX_NUM_THREADS>(config, reduce); +} + +//TODO this is 100 lines of almost-copy-paste, because we have to have different template args for this function +//try unifying with gpu_reduce_kernel +template +inline void jitted_gpu_reduce_kernel(TensorIterator& iter, const std::string& func, ident_t ident=0, + AccumulationBuffer* acc_buf_ptr=nullptr, int64_t base_idx=0) { + AT_ASSERT(iter.numel() > 0 && iter.ntensors() - iter.noutputs() == 1 && iter.noutputs() >= 1); + + //TODO - this will be different for more complicated reductions, but for now reductions using + //func_wrapper all have arg_t = opmath + using arg_t = at::opmath_type; + // at::Half/at::ComplexHalf overflows easily as it's range is very small. + // So when scalar_t and out_scalar_t are at::Half/at::ComplexHalf, we + // set can_accumulate_in_output to False. + static constexpr bool is_inp_out_type_half_or_chalf = + (std::is_same_v && + std::is_same_v ) || + (std::is_same_v, scalar_t> && + std::is_same_v, out_scalar_t>); + // at::BFloat16 has lower precision and can lead to rounding errors. + // So when scalar_t and out_scalar_t are at::BFloat16, we + // set can_accumulate_in_output to False. + static constexpr bool is_inp_out_type_bfloat16 = + (std::is_same_v && + std::is_same_v); + static constexpr bool can_accumulate_in_output = + std::is_convertible_v && + !(is_inp_out_type_half_or_chalf || is_inp_out_type_bfloat16); + + bool can_use_32bit_indexing = iter.can_use_32bit_indexing(); + std::unique_ptr owned_buf_ptr; + + // The acc_buf_ptr is a shared pointer. It is create at the first entrance and + // reused by all recursive function calls. + if (acc_buf_ptr == NULL) { + // acc_buf_ptr holds buffer used for accumulation among multiple sub_iter + // when accumulation in output is not possible. + if (!can_accumulate_in_output && !can_use_32bit_indexing) { + int64_t output_memory_size = iter.element_size(0); + for (int dim = 0; dim < iter.ndim(); dim++) { + output_memory_size = std::max(output_memory_size, iter.shape()[dim] * iter.strides(0)[dim]); + } + output_memory_size /= iter.element_size(0); //iter.strides is in bytes + owned_buf_ptr.reset(new AccumulationBuffer(sizeof(out_scalar_t), //TODO + sizeof(out_scalar_t), + (char*) iter.data_ptr(0), + output_memory_size * sizeof(out_scalar_t))); //TODO + } else { + owned_buf_ptr.reset(new AccumulationBuffer()); + } + acc_buf_ptr = owned_buf_ptr.get(); + } + + if (!can_use_32bit_indexing) { + for (auto& sub_iter : iter.with_32bit_indexing()) { + int64_t sub_iter_base_idx = sub_iter.view_offsets()[0]; + + jitted_gpu_reduce_kernel(sub_iter, func, ident, + acc_buf_ptr, sub_iter_base_idx); + } + return; + } + + //TODO - for now we support a single input, we may be able to relax this constraint + const char* in_data = (char*)iter.data_ptr(iter.ntensors() - 1); + char* out_data = (char*)iter.data_ptr(0); + const auto noutputs = iter.noutputs(); + std::optional out_data_extra; + if (noutputs > 1) { + out_data_extra = (char*)iter.data_ptr(1); + } else { + out_data_extra = std::nullopt; + } + char* acc_data = acc_buf_ptr->get_acc_slice(out_data); + + ReduceConfig config = setReduceConfig(iter); + + at::DataPtr buffer; + at::DataPtr semaphores; + if (config.should_global_reduce()) { + auto& allocator = *c10::cuda::CUDACachingAllocator::get(); + buffer = allocator.allocate(config.global_memory_size()); + semaphores = allocator.allocate(config.semaphore_size()); + + auto stream = at::cuda::getCurrentCUDAStream(); + AT_CUDA_CHECK(cudaMemsetAsync(semaphores.get(), 0, config.semaphore_size(), stream)); + } + + AT_ASSERT(can_use_32bit_indexing); + auto output_calc = make_output_calculator(iter); + auto input_calc = make_input_calculator(iter); + auto reduce = ReduceJitOp( + config, + input_calc, + output_calc, + in_data, + out_data, + out_data_extra, + acc_data, + buffer.get(), + (int*)semaphores.get(), + ident, + noutputs, + base_idx); + reduce.accumulate = iter.should_accumulate(); + reduce.final_output = iter.is_final_output(); + + constexpr int nInputs = 1; + constexpr int nOutputs = 1; + static auto desc = at::cuda::jit::make_kernel_descriptor< + out_scalar_t, scalar_t>(name, func, nInputs, nOutputs); + + static std::mutex jiterator_mutex; + static std::vector> fn_cache(c10::cuda::device_count()); + auto &cache = fn_cache[iter.device().index()]; + + launch_jitted_reduce_kernel( + jiterator_mutex, cache, desc, vt0, config, &reduce); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ReduceOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ReduceOps.h new file mode 100644 index 0000000000000000000000000000000000000000..99c66812982e8e1b39c6807051d053a617aad170 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ReduceOps.h @@ -0,0 +1,20 @@ + +namespace at { +struct TensorIterator; +} + +namespace c10 { +class Scalar; +} + +namespace at::native { + +void norm_launch_kernel(TensorIterator &iter, double val); +void min_launch_kernel(TensorIterator &iter); +void max_launch_kernel(TensorIterator &iter); +void aminmax_launch_kernel(TensorIterator &iter); +void min_all_launch_kernel(TensorIterator &iter); +void max_all_launch_kernel(TensorIterator &iter); +void aminmax_allreduce_launch_kernel(TensorIterator &iter); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Resize.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Resize.h new file mode 100644 index 0000000000000000000000000000000000000000..d5de128cac1d2014cfa8274facbf9cea6f43bf4a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Resize.h @@ -0,0 +1,53 @@ +#pragma once + +#include +#include + +#include + +namespace at { namespace native { + +TORCH_CUDA_CPP_API void resize_bytes_cuda(StorageImpl* storage, size_t size_bytes); + +static inline void maybe_resize_storage_cuda(TensorImpl* self, size_t new_size_bytes) { + // It does not make sense to try to resize a storage + // to hold 0 elements, and this can break + // if storage_offset is positive but + // new_size is 0, so just bail in that case + // (same comment is in Resize.h) + if (self->numel() == 0) { + return; + } + + const Storage &storage = self->unsafe_storage(); + TORCH_CHECK(storage, "Tensor: invalid null storage"); + if (new_size_bytes > storage.nbytes()) { + resize_bytes_cuda(storage.unsafeGetStorageImpl(), new_size_bytes); + } +} + +inline TensorImpl* resize_impl_cuda_( + TensorImpl* self, + IntArrayRef size, + at::OptionalIntArrayRef stride) { + if (self->sizes() == size && (!stride || self->strides() == stride)) { + return self; + } + const auto itemsize = self->dtype().itemsize(); + const auto storage_offset = self->storage_offset(); + size_t storage_size = 1; + if (stride) { + self->set_sizes_and_strides(size, *stride); + storage_size = at::detail::computeStorageNbytes( + size, *stride, itemsize, storage_offset); + } else { + self->set_sizes_contiguous(size); + storage_size = at::detail::computeStorageNbytesContiguous( + size, itemsize, storage_offset); + } + maybe_resize_storage_cuda(self, storage_size); + + return self; +} + +}} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/RowwiseScaledMM.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/RowwiseScaledMM.h new file mode 100644 index 0000000000000000000000000000000000000000..533a702f301e89f41953f57e3ba2e4766ce52dd9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/RowwiseScaledMM.h @@ -0,0 +1,14 @@ +#pragma once +#include +#include + +namespace at::cuda::detail { +TORCH_API void f8f8bf16_rowwise( + at::Tensor XQ, // FP8 + at::Tensor WQ, // FP8 + at::Tensor x_scale, // FP32 + at::Tensor w_scale, // FP32 + std::optional bias, // BF16 + bool use_fast_accum, + at::Tensor& out); +} // namespace at::cuda::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ScaledGroupMM.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ScaledGroupMM.h new file mode 100644 index 0000000000000000000000000000000000000000..380851df538b41760a7ce3d7fd72fbe314d8269f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ScaledGroupMM.h @@ -0,0 +1,15 @@ +#pragma once +#include +#include + +namespace at::cuda::detail { +TORCH_API void f8f8bf16_grouped_mm( + at::Tensor mat_a, // FP8 + at::Tensor mat_b, // FP8 + at::Tensor scale_a, // FP32 + at::Tensor scale_b, // FP32 + std::optional offs, + std::optional bias, // BF16 + bool use_fast_accum, + at::Tensor& out); +} // namespace at::cuda::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ScanKernels.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ScanKernels.h new file mode 100644 index 0000000000000000000000000000000000000000..28e65372511bc7b50390a134e01554b6fa9ee171 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ScanKernels.h @@ -0,0 +1,18 @@ +#pragma once +#include + +namespace at { +class TensorBase; + +namespace native { + +// NOTE: these functions require output tensors to be contiguous +void launch_cummax_cuda_kernel(const TensorBase& self, const TensorBase& values, + const TensorBase& indices, int64_t dim); +void launch_cummin_cuda_kernel(const TensorBase& self, const TensorBase& values, + const TensorBase& indices, int64_t dim); +void launch_logcumsumexp_cuda_kernel(const TensorBase& result, const TensorBase& self, int64_t dim); +void launch_cumsum_cuda_kernel(const TensorBase& result, const TensorBase& self, int64_t dim); +void launch_cumprod_cuda_kernel(const TensorBase& result, const TensorBase& self, int64_t dim); + +}} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ScanUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ScanUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..1bb644730095426ab9ea51cd84f0529b9fb3ea80 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/ScanUtils.cuh @@ -0,0 +1,475 @@ +#pragma once +#include +#include +#include +#include + +#include +#include +#include + +namespace at::native { + +template +constexpr inline integer ceil_div(integer n, integer m) { + return (n + m - 1) / m; +} + +template +constexpr inline integer get_log_num_threads_x_inner_scan(integer num_rows, integer row_size) { + integer log_num_threads_x = 0; + integer log_num_threads_y = 0; + while (((integer)1 << log_num_threads_x) < row_size) { + ++log_num_threads_x; + } + while (((integer)1 << log_num_threads_y) < num_rows) { + ++log_num_threads_y; + } + // we want to keep the ratio between the x-threads and y-threads about the same as + // the ratio between the row_size and num_rows, but the total number of threads in + // a block should be about 512 + integer diff = log_num_threads_x - log_num_threads_y; + // 9 is from log2(512) + log_num_threads_x = ((integer)9 + diff) / (integer)2; + // I found that in having larger log_num_threads_x can give significant speed up in some cases, + // but detrimental in another case, so just keep the lower bound to be log2(16) == 4 to make it + // similar to the previous implementation + // Keeping the upper bound to be log2(512) == 9 as the maximum number of threads in a block. + log_num_threads_x = std::min(std::max((integer)4, log_num_threads_x), (integer)9); + return log_num_threads_x; +} + +template +__device__ void binary_op_update(const scalar_t lhs, scalar_t& rhs, const idx_t lhs_idx, idx_t& rhs_idx, BinaryOperation binary_op) { + if(!at::_isnan(rhs) && (at::_isnan(lhs) || !binary_op(rhs, lhs))) { + rhs = lhs; + rhs_idx = lhs_idx; + } +} +/* Perform an inclusive scan along the innermost dimension of a tensor. + * + * - num_rows is the size of the flattened outer dimensions; + * - row_size is the size of the innermost dimension; + * + * The outer dimensions of the tensor are considered as a single dimension, i.e. the tensor is + * considered as having 'num_rows' rows of size 'row_size'. + * Each thread block processes one or more sets of contiguous rows (processing multiple rows + * per thread block is quicker than processing a single row, especially for short rows). + */ +template +__global__ void tensor_kernel_scan_innermost_dim_with_indices(const scalar_t *self_, scalar_t *values_, int64_t *indices_, + int num_rows, int row_size, + const uint32_t num_threads, const uint32_t log_num_threads_x, + scalar_t init, BinaryFunction binary_op) { + // dynamic memory allocation for vbuf and ibuf + alignas(sizeof(double)) extern __shared__ char buf[]; + scalar_t* vbuf = reinterpret_cast(buf); // the size is num_threads * 2 + int64_t* ibuf = reinterpret_cast(vbuf + num_threads * 2); + const uint32_t num_threads_x = 1 << log_num_threads_x; + scalar_t* row_buf = vbuf + 2 * num_threads_x * threadIdx.y; + int64_t* row_idx_buf = ibuf + 2 * num_threads_x * threadIdx.y; + + for (int block_row = blockIdx.x * blockDim.y; + block_row < num_rows; + block_row += blockDim.y * gridDim.x) { + int row = block_row + threadIdx.y; + const scalar_t *row_self = self_ + row * row_size; + scalar_t *row_values = values_ + row * row_size; + int64_t *row_indices = indices_ + row * row_size; + scalar_t block_total = init; + int64_t block_idx_final = 0; + const bool row_exists = row < num_rows; + // Perform scan on one block at a time, keeping track of the total value of + // all blocks processed so far. + for (int block_col = 0; block_col < row_size; block_col += 2 * num_threads_x) { + // Load data into shared memory (two values per thread). + int col1 = block_col + threadIdx.x; + int col2 = block_col + num_threads_x + threadIdx.x; + if (row_exists) { + if (col1 < row_size) { + row_buf[threadIdx.x] = c10::load(&row_self[col1]); + row_idx_buf[threadIdx.x] = col1; + } else { + row_buf[threadIdx.x] = init; + // No need to set the index here as the value in init will never be selected + } + + if (col2 < row_size) { + row_buf[num_threads_x + threadIdx.x] = c10::load(&row_self[col2]); + row_idx_buf[num_threads_x + threadIdx.x] = col2; + } else { + row_buf[num_threads_x + threadIdx.x] = init; + // No need to set the index here as the value in init will never be selected + } + + // Add the total value of all previous blocks to the first value of this block. + if (threadIdx.x == 0) { + binary_op_update(block_total, row_buf[0], block_idx_final, row_idx_buf[0], binary_op); + } + } + __syncthreads(); + + // Parallel reduction with Sklansky method. The diagram can be seen on this paper: + // https://research.nvidia.com/publication/single-pass-parallel-prefix-scan-decoupled-look-back + for (uint32_t s = 1; s <= num_threads_x; s <<= 1) { + if (row_exists) { + uint32_t a = (threadIdx.x / s) * (2 * s) + s; + uint32_t ti = a + (threadIdx.x % s); + uint32_t si = a - 1; + binary_op_update(row_buf[si], row_buf[ti], row_idx_buf[si], row_idx_buf[ti], binary_op); + } + __syncthreads(); + } + + // Write back to output. + if (row_exists) { + if (col1 < row_size){ + row_values[col1] = row_buf[threadIdx.x]; + row_indices[col1] = row_idx_buf[threadIdx.x]; + } + if (col2 < row_size) { + row_values[col2] = row_buf[num_threads_x + threadIdx.x]; + row_indices[col2] = row_idx_buf[num_threads_x + threadIdx.x]; + } + } + block_total = row_buf[2 * num_threads_x - 1]; + block_idx_final = row_idx_buf[2 * num_threads_x - 1]; + __syncthreads(); + } + } +} + +/* Perform an inclusive scan along an outer dimension of a tensor. + * + * - num_orows is the size of the flattened outer dimensions; + * - num_irows is the size of the flattened inner dimensions; + * - row_size is the size of the dimension along which to compute the variance; + * + * The dimensions to the outside and inside of the specified dimension are considered as flattened. + * Thread blocks with the same blockIdx.y process an "outer row" (i.e. an element of the flattened + * outer dimensions, which contains several "inner rows"). + * Each thread processes a single inner row at a time. + */ +template +__global__ void tensor_kernel_scan_outer_dim_with_indices(const scalar_t *self_, scalar_t *values_, int64_t *indices_, + const uint32_t num_orows, const uint32_t num_irows, const uint32_t row_size, scalar_t init, BinaryFunction binary_op) { + for (uint32_t orow = blockIdx.x; orow < num_orows; orow += gridDim.x) { + for (uint32_t irow = blockIdx.y * blockDim.x + threadIdx.x; irow < num_irows; irow += gridDim.y * blockDim.x) { + const scalar_t *self = self_ + orow * row_size * num_irows + irow; + scalar_t *values = values_ + orow * row_size * num_irows + irow; + int64_t *indices = indices_ + orow * row_size * num_irows + irow; + scalar_t out = init; + int64_t out_idx = 0; + + for (auto col = decltype(row_size){0}; col < row_size; ++col) { + const auto val = c10::load(self); + if(at::_isnan(val) || (!at::_isnan(out) && binary_op(val, out))) { + out = val; + out_idx = col; + } + *values = out; + *indices = out_idx; + self += num_irows; + values += num_irows; + indices += num_irows; + } + } + } +} + +inline void check_fits_in_unsigned(int64_t val, const char* name) { + constexpr auto umax = std::numeric_limits::max(); + TORCH_CHECK( + val >= 0 && val <= umax, name, " must fit in a 32-bit uint32_t value"); +} + + +template +__host__ void scan_outer_dim_with_indices( + const TensorBase& self, const TensorBase& values, const TensorBase& indices, + int dim, scalar_t init, BinaryFunction binary_op) { + int64_t row_size = self.size(dim); + auto sizes = self.sizes(); + + // Treat all outer dimensions (i.e. dim_ < dim) as one. + const int64_t num_orows = c10::multiply_integers(sizes.begin(), sizes.begin() + dim); + + // Treat all inner dimensions (i.e. dim > dimension) as one. + const int64_t num_irows = c10::multiply_integers(sizes.begin() + dim + 1, sizes.end()); + //for performance reasons, cuda kernels use uint32_t for loops over irows, orows and row, + //make sure that input is not bigger than supported by uint32_t + check_fits_in_unsigned(num_irows, "num_irows"); + check_fits_in_unsigned(num_orows, "num_orows"); + check_fits_in_unsigned(row_size, "row_size"); + + + dim3 threads(std::min(512, int(num_irows))); + int64_t maxGridDim = at::cuda::getCurrentDeviceProperties()->maxGridSize[1]; + dim3 grid(std::min(maxGridDim, num_orows), std::min(maxGridDim, ceil_div(num_irows, int64_t{threads.x}))); + tensor_kernel_scan_outer_dim_with_indices<<>>( + self.const_data_ptr(), values.mutable_data_ptr(), indices.mutable_data_ptr(), + num_orows, num_irows, row_size, init, binary_op); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +__host__ void scan_innermost_dim_with_indices( + const TensorBase& self, const TensorBase& values, const TensorBase& indices, + scalar_t init, BinaryFunction binary_op) { + int ndim = self.dim(); + // Treat all outer dimensions as a single dimension. + int row_size = self.size(ndim - 1); + int num_rows = self.numel() / row_size; + + // assuming max_num_threads per block is 512 + const uint32_t num_threads = 512; + const uint32_t log_num_threads_x = get_log_num_threads_x_inner_scan(num_rows, row_size); + const uint32_t num_threads_x = (1 << log_num_threads_x); + const uint32_t num_threads_y = num_threads / num_threads_x; + dim3 threads(num_threads_x, num_threads_y); + dim3 grid(std::min(at::cuda::getCurrentDeviceProperties()->maxGridSize[0], ceil_div(num_rows, int(threads.y)))); + + const uint32_t mem_size = 2 * num_threads * (sizeof(scalar_t) + sizeof(int64_t)); + tensor_kernel_scan_innermost_dim_with_indices<<>>( + self.const_data_ptr(), values.mutable_data_ptr(), indices.mutable_data_ptr(), + num_rows, row_size, num_threads, log_num_threads_x, init, binary_op); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +void scan_dim_with_indices(const TensorBase& self, const TensorBase& values, const TensorBase& indices, //int64_t dim) { + int64_t dim, scalar_t init, BinaryFunction binary_op) { + int ndim = self.dim(); + auto self_ = self.expect_contiguous(); + TORCH_INTERNAL_ASSERT(values.is_contiguous() && indices.is_contiguous()); + if (dim == ndim - 1) { + scan_innermost_dim_with_indices(*self_, values, indices, init, binary_op); + } else { + scan_outer_dim_with_indices(*self_, values, indices, dim, init, binary_op); + } +} + +// TODO: The implementation of `tensor_kernel_scan_outer_dim` and +// `tensor_kernel_scan_innermost_dim` is similar to +// `tensor_kernel_scan_outer_dim_with_indices` +// `tensor_kernel_scan_outer_dim_with_indices` and should be refactored to +// remove the duplication. + +/* Perform an inclusive scan along an outer dimension of a tensor. + * + * - num_orows is the size of the flattened outer dimensions; + * - num_irows is the size of the flattened inner dimensions; + * - row_size is the size of the dimension along which to scan; + * + * The dimensions to the outside and inside of the specified dimension are considered as flattened. + * Thread blocks with the same blockIdx.y process an "outer row" (i.e. an element of the flattened + * outer dimensions, which contains several "inner rows"). + * Each thread processes a single inner row at a time. + */ +template +__global__ void tensor_kernel_scan_outer_dim(scalar_t *tgt_, const scalar_t *src_, + const uint32_t num_orows, const uint32_t num_irows, const uint32_t row_size, + const scalar_t init, BinaryOp binary_op) +{ + for (uint32_t orow = blockIdx.x; orow < num_orows; orow += gridDim.x) { + for (uint32_t irow = blockIdx.y * blockDim.x + threadIdx.x; irow < num_irows; irow += gridDim.y * blockDim.x) { + const scalar_t *src = src_ + orow * row_size * num_irows + irow; + scalar_t *tgt = tgt_ + orow * row_size * num_irows + irow; + scalar_t acc = init; + + for (uint32_t col = 0; col < row_size; ++col) { + acc = binary_op(acc, c10::load(src)); + *tgt = acc; + + src += num_irows; + tgt += num_irows; + } + } + } +} + +/* Perform an inclusive scan along the innermost dimension of a tensor. + * + * - num_rows is the size of the flattened outer dimensions; + * - row_size is the size of the innermost dimension; + * + * The outer dimensions of the tensor are considered as a single dimension, i.e. the tensor is + * considered as having 'num_rows' rows of size 'row_size'. + * Each thread block processes one or more sets of contiguous rows (processing multiple rows + * per thread block is quicker than processing a single row, especially for short rows). + */ +template +__device__ void tensor_kernel_scan_innermost_dim_impl(T* row_buf, T *tgt_, const T *src_, + const uint32_t num_rows, const uint32_t row_size, + const uint32_t log_num_threads_x, + T init, BinaryFunction binary_op){ + const index_t num_threads_x = 1 << log_num_threads_x; + for (index_t block_row = blockIdx.x * (index_t) blockDim.y; + block_row < num_rows; + block_row += blockDim.y * gridDim.x) { + index_t row = block_row + (index_t) threadIdx.y; + T block_total = init; + + const T *row_src = src_ + row * row_size; + T *row_tgt = tgt_ + row * row_size; + const bool row_exists = row < num_rows; + + // Perform scan on one block at a time, keeping track of the total value of + // all blocks processed so far. + for (index_t block_col = 0; block_col < row_size; block_col += 2 * num_threads_x) { + // Load data into shared memory (two values per thread). + index_t col1 = block_col + (index_t) threadIdx.x; + index_t col2 = block_col + num_threads_x + (index_t) threadIdx.x; + if (row_exists) { + if (col1 < row_size) { + row_buf[threadIdx.x] = row_src[col1]; + } else { + row_buf[threadIdx.x] = init; + } + + if (col2 < row_size) { + row_buf[num_threads_x + threadIdx.x] = row_src[col2]; + } else { + row_buf[num_threads_x + threadIdx.x] = init; + } + + // Add the total value of all previous blocks to the first value of this block. + if (threadIdx.x == 0) { + row_buf[0] = binary_op(row_buf[0], block_total); + } + } + __syncthreads(); + + // Parallel reduction with Sklansky method. The diagram can be seen on this paper: + // https://research.nvidia.com/publication/single-pass-parallel-prefix-scan-decoupled-look-back + for (int m = 0; m <= log_num_threads_x; ++m) { + if (row_exists) { + index_t s = 1 << m; // s = 2 ^ m + auto a = static_cast((threadIdx.x >> m) << (m + 1)) | s; // a = (threadIdx.x / s) * (2 * s) + s + index_t ti = a + (threadIdx.x % s); + index_t si = a - 1; + row_buf[ti] = binary_op(row_buf[ti], row_buf[si]); + } + __syncthreads(); + } + + // Write back to output. + if (row_exists) { + if (col1 < row_size) row_tgt[col1] = row_buf[threadIdx.x]; + if (col2 < row_size) row_tgt[col2] = row_buf[num_threads_x + threadIdx.x]; + } + block_total = row_buf[2 * num_threads_x - 1]; + __syncthreads(); + } + } +} + +template < + typename T, + class BinaryFunction> +__global__ void tensor_kernel_scan_innermost_dim( + T* tgt_, + const T* src_, + const uint32_t num_rows, + const uint32_t row_size, + const uint32_t log_num_threads_x, + T init, + BinaryFunction binary_op) { + alignas(sizeof(double)) extern __shared__ char sbuf[]; + T* sbuf2 = reinterpret_cast(sbuf); + const uint32_t num_threads_x = 1 << log_num_threads_x; + T* row_buf = reinterpret_cast(sbuf2 + num_threads_x * 2 * threadIdx.y); + if (num_rows * (size_t) row_size <= UINT_MAX) { + tensor_kernel_scan_innermost_dim_impl( + row_buf, tgt_, src_, num_rows, row_size, log_num_threads_x, init, binary_op); + } else { + tensor_kernel_scan_innermost_dim_impl( + row_buf, tgt_, src_, num_rows, row_size, log_num_threads_x, init, binary_op); + } +} + + +template +__host__ void scan_outer_dim(const TensorBase& self, const TensorBase& result, + int dim, scalar_t init, BinaryFunction binary_op) { + const int64_t row_size = self.size(dim); + auto sizes = self.sizes(); + + // Treat all outer dimensions (i.e. dim_ < dim) as one. + const int64_t num_orows = c10::multiply_integers(sizes.begin(), sizes.begin() + dim); + + // Treat all inner dimensions (i.e. dim > dimension) as one. + const int64_t num_irows = c10::multiply_integers(sizes.begin() + dim + 1, sizes.end()); + + dim3 threads(std::min(512, int(num_irows))); + int64_t maxGridDim = at::cuda::getCurrentDeviceProperties()->maxGridSize[1]; + dim3 grid(std::min(maxGridDim, num_orows), std::min(maxGridDim, ceil_div(num_irows, int64_t{threads.x}))); + + check_fits_in_unsigned(num_irows, "num_irows"); + check_fits_in_unsigned(num_orows, "num_orows"); + check_fits_in_unsigned(row_size, "row_size"); + + tensor_kernel_scan_outer_dim<<>>( + result.mutable_data_ptr(), self.const_data_ptr(), + num_orows, num_irows, row_size, init, binary_op); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +void scan_innermost_dim(const TensorBase& self, const TensorBase& result, + scalar_t init, BinaryFunction binary_op) { + int64_t ndim = self.dim(); + // Treat all outer dimensions as a single dimension. + int64_t row_size = self.size(ndim - 1); + int64_t num_rows = self.numel() / row_size; + + // assuming max_num_threads per block is 512 + const uint32_t num_threads = 512; + const uint32_t log_num_threads_x = get_log_num_threads_x_inner_scan(num_rows, row_size); + const uint32_t num_threads_x = (1 << log_num_threads_x); + const uint32_t num_threads_y = num_threads / num_threads_x; + dim3 threads(num_threads_x, num_threads_y); + int64_t maxGridDim = at::cuda::getCurrentDeviceProperties()->maxGridSize[0]; + dim3 grid(std::min(maxGridDim, ceil_div(num_rows, int64_t{threads.y}))); + + check_fits_in_unsigned(num_rows, "Number of rows (self.numel()/self.size(self.dim()-1))"); + check_fits_in_unsigned(row_size, "row_size"); + + tensor_kernel_scan_innermost_dim<<>>( + result.mutable_data_ptr(), self.const_data_ptr(), + num_rows, row_size, log_num_threads_x, init, binary_op); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +void scan_dim(const TensorBase& self, const TensorBase& result, + int64_t dim, scalar_t init, BinaryFunction binary_op) { + int ndim = self.dim(); + auto self_ = self.expect_contiguous(); + TORCH_INTERNAL_ASSERT(result.is_contiguous()); + + if (self.numel() == self.size(dim)) { + if constexpr (std::is_same_v>) { + if (C10_UNLIKELY(at::globalContext().deterministicAlgorithms()) && (self.is_floating_point() || self.is_complex())) { +# if (defined(CUDA_VERSION) && CUDA_VERSION > 11040) || defined(USE_ROCM) + cuda::cub::inclusive_deterministic_scan(self_->const_data_ptr(), result.mutable_data_ptr(), binary_op, self.numel()); +#else + globalContext().alertNotDeterministic("cumsum_cuda_kernel"); + cuda::cub::inclusive_scan(self_->const_data_ptr(), result.mutable_data_ptr(), binary_op, self.numel()); +#endif + } else { + cuda::cub::inclusive_scan(self_->const_data_ptr(), result.mutable_data_ptr(), binary_op, self.numel()); + } + } else { + cuda::cub::inclusive_scan(self_->const_data_ptr(), result.mutable_data_ptr(), binary_op, self.numel()); + } + } else if (dim == ndim - 1) { + scan_innermost_dim(*self_, result, init, binary_op); + } else { + scan_outer_dim(*self_, result, dim, init, binary_op); + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Sort.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Sort.h new file mode 100644 index 0000000000000000000000000000000000000000..4ad3e26b819b9a6b9eb240d1fdb0f6c0bca264b2 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Sort.h @@ -0,0 +1,17 @@ +#pragma once +#include +#include +#include + + +namespace at::native { + +inline bool should_use_small_sort(const TensorBase &self, int64_t dim) { + return self.size(dim) <= 4096; +} + +void sortKeyValueInplace( + const TensorBase &key, const TensorBase &value, int64_t dim, + bool descending, bool stable=false); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortStable.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortStable.h new file mode 100644 index 0000000000000000000000000000000000000000..d186345b3a93070e0b3d2b354dab12d9f71eae78 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortStable.h @@ -0,0 +1,17 @@ +#pragma once +#include +#include + +namespace at::native { + +// Stable-sort self into values, and set indices to the +// inverse-permutation from values back to self. +// Output tensors must be pre-allocated and contiguous. +void launch_stable_sort_kernel( + const TensorBase& self, + int64_t dim, + bool descending, + const TensorBase& values, + const TensorBase& indices); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortUtils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortUtils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..1d0df3741bb223df83110ff6c62d81d9681352f3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortUtils.cuh @@ -0,0 +1,343 @@ +#pragma once +#include + +#include +#include +#include +#include +#include +#include +#include + +#define HAS_WARP_MERGE_SORT() (CUDA_VERSION >= 110600) + + +namespace at::native { + +template +__device__ inline void swapVars(T& t1, T& t2) { + T tmp = t1; + t1 = t2; + t2 = tmp; +} + +template +__device__ inline void bitonicSwap(K& kA, V& vA, bool& validA, + K& kB, V& vB, bool& validB, + bool dir, + const Comparator& comp) { + // Invalid entries always sort to the end + bool swap = (comp(kA, kB) && validA) || !validB; + if (swap == dir) { + swapVars(kA, kB); + swapVars(vA, vB); + swapVars(validA, validB); + } +}; + +template +__device__ inline void bitonicSort(K *keys, + V *values, + bool *valid, + const Comparator& comp) { +#if !defined(USE_ROCM) +#pragma unroll +#endif + for (unsigned int size = 2; size < Power2SortSize; size *= 2) { + bool flag = ((threadIdx.x & (size / 2)) != 0); + +#if !defined(USE_ROCM) +#pragma unroll +#endif + for (unsigned int stride = size / 2; stride > 0; stride /= 2) { + + __syncthreads(); + + unsigned int pos = 2 * threadIdx.x - (threadIdx.x & (stride - 1)); + bitonicSwap( + keys[pos], values[pos], valid[pos], + keys[pos + stride], values[pos + stride], valid[pos + stride], + flag, comp); + } + } + +#if !defined(USE_ROCM) +#pragma unroll +#endif + for (unsigned int stride = Power2SortSize / 2; stride > 0; stride /= 2) { + + __syncthreads(); + + unsigned int pos = 2 * threadIdx.x - (threadIdx.x & (stride - 1)); + bitonicSwap( + keys[pos], values[pos], valid[pos], + keys[pos + stride], values[pos + stride], valid[pos + stride], + false, comp); + } + + __syncthreads(); + +} + +// at::cuda::detail::TensorInfo version +// Sorts (key, value) pairs (in different tensors) in-place; i.e., +// modifies the input `keys` and `values` +template +C10_LAUNCH_BOUNDS_1(block_dim_x * max_block_dim_y) +__global__ void +bitonicSortKVInPlace(at::cuda::detail::TensorInfo keys, + IndexType keySlices, + IndexType keySliceSize, + IndexType keySliceStride, + at::cuda::detail::TensorInfo values, + IndexType valueSliceStride, + Comparator comp) { + // Find the slice of the tensor that we are sorting + // NOTE: blockDim.y may be less max_block_dim_y + const IndexType blockIndex = getLinearBlockId(); + const IndexType linearIndex = blockIndex * blockDim.y + threadIdx.y; + + // If the entire block is out of bounds exit early + if (blockIndex * blockDim.y >= keySlices) { + return; + } + // It's also possible for some rows of a block to be out of bounds + // but all thread need to run for __syncthreads to work. + const bool row_valid = linearIndex < keySlices; + + constexpr int items_per_thread = 2; + constexpr int Power2SortSize = block_dim_x * items_per_thread; + + // Storage for max_block_dim_y sorts performed in parallel + __shared__ K blockSharedKeys[max_block_dim_y][Power2SortSize]; + __shared__ V blockSharedValues[max_block_dim_y][Power2SortSize]; + __shared__ bool blockSharedValid[max_block_dim_y][Power2SortSize]; + + auto sharedKeys = blockSharedKeys[threadIdx.y]; + auto sharedValues = blockSharedValues[threadIdx.y]; + auto sharedValid = blockSharedValid[threadIdx.y]; + + const IndexType keyStartOffset = + at::cuda::detail::IndexToOffset::get(linearIndex, keys); + const IndexType valueStartOffset = + at::cuda::detail::IndexToOffset::get(linearIndex, values); + + // Load 2 values per thread into the shared workspace + #pragma unroll + for (int k = 0; k < items_per_thread; ++k) { + auto idx = threadIdx.x + k * blockDim.x; + bool valid = row_valid && idx < keySliceSize; + + sharedKeys[idx] = valid ? + keys.data[idx * keySliceStride + keyStartOffset] : K{}; + sharedValues[idx] = valid ? + values.data[idx * valueSliceStride + valueStartOffset] : V{}; + sharedValid[idx] = valid; + } + + // Sort! + bitonicSort( + sharedKeys, sharedValues, sharedValid, comp); + + if (!row_valid) { + return; + } + + // Store outputs + #pragma unroll + for (int k = 0; k < items_per_thread; ++k) { + auto idx = threadIdx.x + k * blockDim.x; + if (idx < keySliceSize) { + keys.data[idx * keySliceStride + keyStartOffset] = sharedKeys[idx]; + values.data[idx * valueSliceStride + valueStartOffset] = sharedValues[idx]; + } + } +} + +#if HAS_WARP_MERGE_SORT() + +template +C10_LAUNCH_BOUNDS_1(C10_WARP_SIZE * max_block_dim_y) +__global__ void +warpMergeSortKVInPlace( + at::cuda::detail::TensorInfo keys, + IndexType keySlices, + IndexType keySliceSize, + IndexType keySliceStride, + at::cuda::detail::TensorInfo values, + IndexType valueSliceStride, + Comparator comp, + K invalid_key) { + // Find the slice of the tensor that we are sorting + // NOTE: blockDim.y may be less max_block_dim_y + const IndexType blockIndex = getLinearBlockId(); + const IndexType linearIndex = blockIndex * blockDim.y + threadIdx.y; + + // If this row is out of bounds exit early + if (linearIndex >= keySlices) { + return; + } + + const IndexType keyStartOffset = + at::cuda::detail::IndexToOffset::get(linearIndex, keys); + const IndexType valueStartOffset = + at::cuda::detail::IndexToOffset::get(linearIndex, values); + + K *keys_slice = &keys.data[keyStartOffset]; + V *values_slice = &values.data[valueStartOffset]; + + StridedRandomAccessor keys_iter(keys_slice, keySliceStride); + StridedRandomAccessor values_iter(values_slice, valueSliceStride); + + namespace cub = ROCM_HIPCUB(at_cuda_detail::cub); + + CUDA_KERNEL_ASSERT(blockDim.x == C10_WARP_SIZE); + CUDA_KERNEL_ASSERT(blockDim.y <= max_block_dim_y); + constexpr int items_per_thread = sort_size / C10_WARP_SIZE; + static_assert( + items_per_thread * C10_WARP_SIZE == sort_size, + "sort_size must be a multiple of C10_WARP_SIZE"); + + + using LoadKeys = cub::WarpLoad; + using LoadValues = cub::WarpLoad; + using Sort = cub::WarpMergeSort; + using StoreKeys = cub::WarpStore; + using StoreValues = cub::WarpStore; + + __shared__ union { + typename LoadKeys::TempStorage load_keys; + typename LoadValues::TempStorage load_values; + typename Sort::TempStorage sort; + typename StoreKeys::TempStorage store_keys; + typename StoreValues::TempStorage store_values; + } tmp_storage[max_block_dim_y]; + + auto& warp_storage = tmp_storage[threadIdx.y]; + + // Load inputs + K local_keys[items_per_thread]; + V local_values[items_per_thread]; + + const auto invalid_value = V{}; + LoadKeys(warp_storage.load_keys).Load(keys_iter, local_keys, keySliceSize, invalid_key); + WARP_SYNC(); + LoadValues(warp_storage.load_values).Load(values_iter, local_values, keySliceSize, invalid_value); + WARP_SYNC(); + + // Sort! We use stable sort to ensure that invalid values are never + // sorted before valid values. In testing it performed the same as + // .Sort, so there is no down-side. + Sort(warp_storage.sort).StableSort( + local_keys, local_values, comp, keySliceSize, invalid_key); + WARP_SYNC(); + + // Store outputs + StoreKeys(warp_storage.store_keys).Store(keys_iter, local_keys, keySliceSize); + WARP_SYNC(); + StoreValues(warp_storage.store_values).Store(values_iter, local_values, keySliceSize); +} + +#endif // HAS_WARP_MERGE_SORT() + +template +C10_LAUNCH_BOUNDS_1(block_size) +__global__ void +radixSortKVInPlace(at::cuda::detail::TensorInfo keys, + IndexType keySlices, + IndexType keySliceSize, + IndexType keySliceStride, + at::cuda::detail::TensorInfo values, + IndexType valueSliceStride, + bool descending) { + static_assert(block_size > 0, ""); + + // Find the slice of the tensor that we are sorting + const IndexType linearIndex = getLinearBlockId(); + // Tiling the slices could have us be out of bounds, if there are a + // lot of slices to sort + if (linearIndex >= keySlices) { + return; + } + + const IndexType keyStartOffset = + at::cuda::detail::IndexToOffset::get(linearIndex, keys); + const IndexType valueStartOffset = + at::cuda::detail::IndexToOffset::get(linearIndex, values); + + K *keys_slice = &keys.data[keyStartOffset]; + V *values_slice = &values.data[valueStartOffset]; + + StridedRandomAccessor keys_iter(keys_slice, keySliceStride); + StridedRandomAccessor values_iter(values_slice, valueSliceStride); + + namespace cub = ROCM_HIPCUB(at_cuda_detail::cub); + + using key_t = typename at::cuda::cub::detail::cuda_type::type; + using LoadKeys = cub::BlockLoad; + using LoadValues = cub::BlockLoad; + using Sort = cub::BlockRadixSort; + using StoreKeys = cub::BlockStore; + using StoreValues = cub::BlockStore; + + __shared__ union { + typename LoadKeys::TempStorage load_keys; + typename LoadValues::TempStorage load_values; + typename Sort::TempStorage sort; + typename StoreKeys::TempStorage store_keys; + typename StoreValues::TempStorage store_values; + } tmp_storage; + + // cub's Block operations operate on a fixed number of items, but the + // actual slice we are sorting might be smaller. So, we need to make + // up the difference with keys that will always sort higher. + const K invalid_key = [descending] { + using radix_t = typename cub::Traits::UnsignedBits; + union { + K key; + radix_t radix; + } tmp; + tmp.radix = descending ? + cub::Traits::LOWEST_KEY : + cub::Traits::MAX_KEY; + return tmp.key; + }(); + const V invalid_value = static_cast(0); + + // Load inputs + K local_keys[items_per_thread]; + V local_values[items_per_thread]; + + LoadKeys(tmp_storage.load_keys).Load(keys_iter, local_keys, keySliceSize, invalid_key); + __syncthreads(); + LoadValues(tmp_storage.load_values).Load(values_iter, local_values, keySliceSize, invalid_value); + __syncthreads(); + + // Sort! + if (descending) { + Sort(tmp_storage.sort).SortDescending( + reinterpret_cast(local_keys), + local_values); + } else { + Sort(tmp_storage.sort).Sort( + reinterpret_cast(local_keys), + local_values); + } + __syncthreads(); + + // Store outputs + StoreKeys(tmp_storage.store_keys).Store(keys_iter, local_keys, keySliceSize); + __syncthreads(); + StoreValues(tmp_storage.store_values).Store(values_iter, local_values, keySliceSize); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Sorting.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Sorting.h new file mode 100644 index 0000000000000000000000000000000000000000..667ea2c2629218f9e59b8f059d2ab9a76fbabb8c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/Sorting.h @@ -0,0 +1,17 @@ +#pragma once +#include + +namespace at { +class TensorBase; +} + +namespace at::native { + +void launch_kthvalue_kernel( + const TensorBase &values, const TensorBase &indices, + const TensorBase &self, int64_t dim, int64_t k); +void launch_median_kernel( + const TensorBase &vals, const TensorBase &inds, + const TensorBase &in, int64_t dim, bool ignore_nan); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortingCommon.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortingCommon.cuh new file mode 100644 index 0000000000000000000000000000000000000000..ba2f6f7c38e527526ad8d9762310f4112b647891 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortingCommon.cuh @@ -0,0 +1,193 @@ +#pragma once +#include +#include +#include +#include +#include +#include +#include + +namespace at::native { + +// Is this questionable namespace pollution? +#if defined(USE_ROCM) +constexpr int MAX_BLOCK_SIZE = 256; + +#else +constexpr int MAX_BLOCK_SIZE = 1024; +#endif + +// Maximum size per grid dimension that we assume (compute capability >= 2.0) +constexpr int64_t MAX_GRID_SIZE = 65535LL; + +inline bool getGridFromTiles(int64_t gridTiles, dim3& grid) { + if (gridTiles > MAX_GRID_SIZE * MAX_GRID_SIZE * MAX_GRID_SIZE) { + return false; + } + + int64_t gridX = gridTiles > MAX_GRID_SIZE ? MAX_GRID_SIZE : gridTiles; + int64_t gridY = 1; + int64_t gridZ = 1; + + if (gridTiles > MAX_GRID_SIZE) { + gridTiles = ceil_div(gridTiles, MAX_GRID_SIZE); + gridY = gridTiles > MAX_GRID_SIZE ? MAX_GRID_SIZE : gridTiles; + + if (gridTiles > MAX_GRID_SIZE) { + gridTiles = ceil_div(gridTiles, MAX_GRID_SIZE); + gridZ = gridTiles > MAX_GRID_SIZE ? MAX_GRID_SIZE : gridTiles; + } + } + + grid = dim3(gridX, gridY, gridZ); + return true; +} + +template +struct GTOp { + __device__ bool operator()(const scalar_t& lhs, const scalar_t& rhs) const { + return (handleNaN && at::_isnan(lhs) && !at::_isnan(rhs)) || + (static_cast(lhs) > static_cast(rhs)); + } +}; + +template +struct LTOp { + __device__ bool operator()(const scalar_t& lhs, const scalar_t& rhs) const { + return (handleNaN && at::_isnan(rhs) && !at::_isnan(lhs)) || + (static_cast(lhs) < static_cast(rhs)); + } +}; + +template +__device__ __forceinline__ index_t getLinearBlockId() { + return blockIdx.z * gridDim.y * gridDim.x + blockIdx.y * gridDim.x + + blockIdx.x; +} + +// For slice sorting in Thrust; extracts a slice index from a linear +// index and uses that for comparison +struct SliceComp { + SliceComp(int64_t size) : sliceSize(size) {} + + __device__ bool operator()(const int64_t& a, const int64_t& b) const { + // Since the slices are guaranteed to be innermost, + // the segment is just via int64_t division + int64_t segA = a / sliceSize; + int64_t segB = b / sliceSize; + return segA < segB; + } + + const int64_t sliceSize; +}; + +// For sorting in Thurst; extracts a within-slice index from a linear index +struct GlobalIndexToPerSliceIndex { + GlobalIndexToPerSliceIndex(int64_t size) : sliceSize(size) {} + + __device__ inline void operator()(int64_t& v) const { + v = v % sliceSize; + } + + const int64_t sliceSize; +}; + +// Returns 2^(ceil(lg(n)) from Stanford bit twiddling hacks +inline uint64_t nextHighestPowerOf2(uint64_t n) { + n--; + n |= n >> 1; + n |= n >> 2; + n |= n >> 4; + n |= n >> 8; + n |= n >> 16; +#ifndef _MSC_VER + n |= n >> 32; +#endif + n++; + + return n; +} + + +// WARNING: This function assumes input tensors are contiguous +template +void run_launcher( + const TensorBase &values, + const TensorBase &indices, + const TensorBase &self, + int64_t dim, + Launcher l) { + auto self_info = cuda::detail::getTensorInfo(self); + auto values_info = cuda::detail::getTensorInfo(values); + auto indices_info = cuda::detail::getTensorInfo(indices); + + int64_t slice_size = self.size(dim); + /* We use these structures solely to find the offset to */ + /* each slice we are operating on */ + self_info.reduceDim(dim); + values_info.reduceDim(dim); + indices_info.reduceDim(dim); + + /* Collapse all other dims */ + int collapse_self_dim = self_info.collapseDims(dim); + int collapse_values_dim = values_info.collapseDims(dim); + int collapse_indices_dim = indices_info.collapseDims(dim); + + int64_t num_slices = 1; + for (int i = 0; i < self_info.dims; ++i) { + num_slices *= self_info.sizes[i]; + } + + /* This is used as a template parameter to calculate indices. */ + /* We only specialize it if all collapsed dim sizes are the */ + /* same; otherwise, we use -1 which is the specialization */ + /* parameter for arbitrary dimensions */ + int all_dims = self_info.dims; + if (values_info.dims != all_dims || indices_info.dims != all_dims) { + all_dims = -1; + } + + if (all_dims == 1) { + l.template launch( + values_info, + collapse_values_dim, + indices_info, + collapse_indices_dim, + self_info, + collapse_self_dim, + num_slices, + slice_size); + } else if (all_dims == 2) { + l.template launch( + values_info, + collapse_values_dim, + indices_info, + collapse_indices_dim, + self_info, + collapse_self_dim, + num_slices, + slice_size); + } else if (all_dims == 3) { + l.template launch( + values_info, + collapse_values_dim, + indices_info, + collapse_indices_dim, + self_info, + collapse_self_dim, + num_slices, + slice_size); + } else { + l.template launch( + values_info, + collapse_values_dim, + indices_info, + collapse_indices_dim, + self_info, + collapse_self_dim, + num_slices, + slice_size); + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortingRadixSelect.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortingRadixSelect.cuh new file mode 100644 index 0000000000000000000000000000000000000000..e1496d4828a02e73257e945cea6de824d87ae354 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/SortingRadixSelect.cuh @@ -0,0 +1,427 @@ +#include +#include +#include +#include +#include + +namespace at::native { + +template +struct TopKTypeConfig {}; + +template <> +struct TopKTypeConfig { + typedef uint32_t RadixType; + + // Converts a float to an integer representation with the same + // sorting; i.e., for floats f1, f2: + // if f1 < f2 then convert(f1) < convert(f2) + // We use this to enable radix selection of floating-point values. + // This also gives a relative order for NaNs, but that's ok, as they + // will all be adjacent + // neg inf: signbit=1 exp=ff fraction=0 --> radix = 0 00 ff.. + // pos inf: signbit=0 exp=ff fraction=0 --> radix = 1 ff 00.. + // pos nan: signbit=0 exp=ff fraction>0 --> radix = 1 ff x>0 + // neg nan: signbit=1 exp=ff fraction>0 --> radix = 0 00 x +struct TopKTypeConfig { + typedef uint32_t RadixType; + + static inline __device__ RadixType convert(uint8_t v) { + return v; + } + + static inline __device__ uint8_t deconvert(RadixType v) { + return v; + } +}; + +template <> +struct TopKTypeConfig { + typedef uint32_t RadixType; + + static inline __device__ RadixType convert(int8_t v) { + return 128u + v; + } + + static inline __device__ int8_t deconvert(RadixType v) { + return v - 128; + } +}; + +template <> +struct TopKTypeConfig { + typedef uint32_t RadixType; + + static inline __device__ RadixType convert(int16_t v) { + static_assert(sizeof(short) == 2, ""); + return 32768u + v; + } + + static inline __device__ int16_t deconvert(RadixType v) { + return v - 32768; + } +}; + +template <> +struct TopKTypeConfig { + typedef uint32_t RadixType; + + static inline __device__ RadixType convert(int32_t v) { + static_assert(sizeof(int) == 4, ""); + return 2147483648u + v; + } + + static inline __device__ int32_t deconvert(RadixType v) { + return v - 2147483648u; + } +}; + +template <> +struct TopKTypeConfig { + typedef uint64_t RadixType; + + static inline __device__ RadixType convert(int64_t v) { + static_assert(sizeof(int64_t) == 8, ""); + return 9223372036854775808ull + v; + } + + static inline __device__ int64_t deconvert(RadixType v) { + return v - 9223372036854775808ull; + } +}; + +template <> +struct TopKTypeConfig { + typedef uint64_t RadixType; + + static inline __device__ RadixType convert(double v) { + RadixType x = __double_as_longlong(v); + RadixType mask = -((x >> 63)) | 0x8000000000000000; + return (v == v) ? (x ^ mask) : 0xffffffffffffffff; + } + + static inline __device__ double deconvert(RadixType v) { + RadixType mask = ((v >> 63) - 1) | 0x8000000000000000; + return __longlong_as_double(v ^ mask); + } +}; + +template <> +struct TopKTypeConfig { + typedef uint32_t RadixType; + + static inline __device__ RadixType convert(at::Half v) { +#if defined(__CUDA_ARCH__) || defined(USE_ROCM) + RadixType x = __half_as_ushort(v); + RadixType mask = (x & 0x00008000) ? 0x0000ffff : 0x00008000; + return (v == v) ? (x ^ mask) : 0xffff; +#else + CUDA_KERNEL_ASSERT(false); + return 0u; +#endif + } + + static inline __device__ at::Half deconvert(RadixType v) { +#if defined(__CUDA_ARCH__) || defined(USE_ROCM) + RadixType mask = (v & 0x00008000) ? 0x00008000 : 0x0000ffff; + return __ushort_as_half(v ^ mask); +#else + CUDA_KERNEL_ASSERT(false); + return static_cast(0); +#endif + } +}; + +template <> +struct TopKTypeConfig { + typedef uint32_t RadixType; + + static inline __device__ RadixType convert(at::BFloat16 v) { + RadixType x = v.x; + RadixType mask = (x & 0x00008000) ? 0x0000ffff : 0x00008000; + return (v == v) ? (x ^ mask) : 0xffff; + } + + static inline __device__ at::BFloat16 deconvert(RadixType v) { + RadixType mask = (v & 0x00008000) ? 0x00008000 : 0x0000ffff; + at::BFloat16 r; + r.x = (v ^ mask); + return r; + } +}; + +// This function counts the distribution of all input values in a +// slice we are selecting by radix digit at `radixDigitPos`, but only +// those that pass the filter `((v & desiredMask) == desired)`. +// This produces and broadcasts the seen counts for a single block only. +// `smem` must have at least `RadixSize` elements. +template < + typename scalar_t, + typename bitwise_t, + typename index_t, + typename CountType, + int RadixSize, + int RadixBits> +__device__ void countRadixUsingMask( + CountType counts[RadixSize], + CountType* smem, + bitwise_t desired, + bitwise_t desiredMask, + int radixDigitPos, + index_t sliceSize, + index_t withinSliceStride, + const scalar_t* data) { + // Clear out per-thread counts from a previous round +#pragma unroll + for (int i = 0; i < RadixSize; ++i) { + counts[i] = 0; + } + + if (threadIdx.x < RadixSize) { + smem[threadIdx.x] = 0; + } + __syncthreads(); + + // Scan over all the data. Upon a read, the warp will accumulate + // counts per each digit in the radix using warp voting. +#if !defined(USE_ROCM) + // Must be called outside of loop to ensure all threads participate + unsigned mask = WARP_BALLOT(threadIdx.x < sliceSize); +#endif + for (index_t i = threadIdx.x; i < sliceSize;) { + bitwise_t val = + TopKTypeConfig::convert(doLdg(&data[i * withinSliceStride])); + + bool hasVal = ((val & desiredMask) == desired); + bitwise_t digitInRadix = at::cuda::Bitfield::getBitfield( + val, radixDigitPos, RadixBits); + +#pragma unroll + for (uint32_t j = 0; j < RadixSize; ++j) { + bool vote = hasVal && (digitInRadix == j); +#if defined(USE_ROCM) + counts[j] += __popcll(WARP_BALLOT(vote)); +#else + counts[j] += __popc(WARP_BALLOT(vote, mask)); +#endif + } + i += blockDim.x; +#if !defined(USE_ROCM) + mask = WARP_BALLOT(i < sliceSize, mask); +#endif + } + + // Now, for each warp, sum values + if (at::cuda::getLaneId() == 0) { +#pragma unroll + for (uint32_t i = 0; i < RadixSize; ++i) { + gpuAtomicAddNoReturn(&smem[i], counts[i]); + } + } + + __syncthreads(); + + // For each thread, read in the total counts +#pragma unroll + for (uint32_t i = 0; i < RadixSize; ++i) { + counts[i] = smem[i]; + } + + __syncthreads(); +} + +// Over what radix we are selecting values +constexpr int RADIX_BITS = 2; // digits are base-(2 ^ RADIX_BITS) +constexpr int RADIX_SIZE = 4; // 2 ^ RADIX_BITS +constexpr int RADIX_MASK = (RADIX_SIZE - 1); + +// This finds the unique value `v` that matches the pattern +// ((v & desired) == desiredMask) in our sorted int format +template +__device__ scalar_t findPattern( + scalar_t* smem, + const scalar_t* data, + index_t sliceSize, + index_t withinSliceStride, + bitwise_t desired, + bitwise_t desiredMask) { + if (threadIdx.x < 2) { + smem[threadIdx.x] = static_cast(0); + } + __syncthreads(); + + // All threads participate in the loop, in order to sync on the flag + index_t numIterations = + round_up(sliceSize, static_cast(blockDim.x)); + for (index_t i = threadIdx.x; i < numIterations; i += blockDim.x) { + bool inRange = (i < sliceSize); + scalar_t v = inRange ? doLdg(&data[i * withinSliceStride]) + : static_cast(0); + + if (inRange && + ((TopKTypeConfig::convert(v) & desiredMask) == desired)) { + // There should not be conflicts if we are using findPattern, + // since the result is unique + smem[0] = static_cast(1); + smem[1] = v; // can't use val as the flag, since it could be 0 + } + + __syncthreads(); + + scalar_t found = smem[0]; + scalar_t val = smem[1]; + + __syncthreads(); + + // Check to see if a thread found the value + if (found != static_cast(0)) { + // all threads return this value + return val; + } + } + + // should not get here + CUDA_KERNEL_ASSERT(false); + return static_cast(0); +} + +// Returns the top-Kth element found in the data using radix selection +template +__device__ void radixSelect( + const scalar_t* data, + index_t k, + bool largest, + index_t sliceSize, + index_t withinSliceStride, + int* smem, + scalar_t* topK) { + // Per-thread buckets into which we accumulate digit counts in our + // radix + int counts[RADIX_SIZE]; + + // We only consider elements x such that (x & desiredMask) == desired + // Initially, we consider all elements of the array, so the above + // statement is true regardless of input. + bitwise_t desired = 0; + bitwise_t desiredMask = 0; + + // We are looking for the top kToFind-th element when iterating over + // digits; this count gets reduced by elimination when counting + // successive digits + int kToFind = k; + + // We start at the most significant digit in our radix, scanning + // through to the least significant digit + for (int digitPos = sizeof(scalar_t) * 8 - RADIX_BITS; digitPos >= 0; + digitPos -= RADIX_BITS) { + // Count radix distribution for the current position and reduce + // across all threads + countRadixUsingMask< + scalar_t, + bitwise_t, + index_t, + int, + RADIX_SIZE, + RADIX_BITS>( + counts, + smem, + desired, + desiredMask, + digitPos, + sliceSize, + withinSliceStride, + data); + + auto found_unique = [&](int i, int count) -> bool { + /* All threads have the same value in counts here, so all */ + /* threads will return from the function. */ + if (count == 1 && kToFind == 1) { + /* There is a unique answer. */ + desired = at::cuda::Bitfield::setBitfield( + desired, i, digitPos, RADIX_BITS); + desiredMask = at::cuda::Bitfield::setBitfield( + desiredMask, RADIX_MASK, digitPos, RADIX_BITS); + + /* The answer is now the unique element v such that: */ + /* (v & desiredMask) == desired */ + /* However, we do not yet know what the actual element is. We */ + /* need to perform a search through the data to find the */ + /* element that matches this pattern. */ + *topK = findPattern( + (scalar_t*)smem, + data, + sliceSize, + withinSliceStride, + desired, + desiredMask); + return true; + } + return false; + }; + auto found_non_unique = [&](int i, int count) -> bool { + if (count >= kToFind) { + desired = + at::cuda::Bitfield::setBitfield( + desired, i, digitPos, RADIX_BITS); + desiredMask = at::cuda::Bitfield::setBitfield( + desiredMask, RADIX_MASK, digitPos, RADIX_BITS); + + /* The top-Kth element v must now be one such that: */ + /* (v & desiredMask == desired) */ + /* but we haven't narrowed it down; we must check the next */ + /* least-significant digit */ + return true; + } + kToFind -= count; + return false; // continue the loop + }; + + // All threads participate in the comparisons below to know the + // final result + if (largest) { + // Process in descending order +#pragma unroll + for (int i = RADIX_SIZE - 1; i >= 0; --i) { + int count = counts[i]; + if (found_unique(i, count)) { + return; + } + if (found_non_unique(i, count)) { + break; + } + } + } else { + // Process in ascending order +#pragma unroll + for (int i = 0; i < RADIX_SIZE; ++i) { + int count = counts[i]; + if (found_unique(i, count)) { + return; + } + if (found_non_unique(i, count)) { + break; + } + } + } + } // end digitPos for + + // There is no unique result, but there is a non-unique result + // matching `desired` exactly + *topK = TopKTypeConfig::deconvert(desired); +} +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/TensorModeKernel.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/TensorModeKernel.cuh new file mode 100644 index 0000000000000000000000000000000000000000..fb43e0d8f347436c758665030082907f4d277bba --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/TensorModeKernel.cuh @@ -0,0 +1,433 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::native { + +// Used for a segmented reduction +struct ModeUnsignedBoolPair { + unsigned int val; + bool flag; +}; + +// In the kernel below, we have a common pattern of reducing (unsigned int, +// unsigned int) pairs of data +struct ModeUnsignedPair { + unsigned int val; + unsigned int index; +}; + +// Inclusive Scan via an upsweep/downsweep mechanism. Assumes: +// +// 1. Power2ScanSize is a power of 2. This code still works for collections that +// do not exactly contain a power of 2 number of elements, simply round up to +// the nearest power of 2 and then call. +// +// 2. That there are two-elements per thread, i.e. the size of the smem storage +// is 2 * blockDim.x * sizeof(T). +// +// Consider a (+)-Scan on the following elements: +// +// Upsweep: +// +// 0 1 2 3 4 5 6 7 +// 1 5 9 13 +// 6 22 +// 28 +// +// Downsweep: +// 15 +// 3 10 21 +template +__device__ void inclusivePrefixScan(T* smem, BinaryOp binop) { + // Reduce step ("upsweep") +#pragma unroll + for (int stride = 1; stride < Power2ScanSize; stride <<= 1) { + int index = (threadIdx.x + 1) * stride * 2 - 1; + if (index < Power2ScanSize) { + smem[index] = binop(smem[index], smem[index - stride]); + } + __syncthreads(); + } + + // Post-reduce step ("downsweep") +#pragma unroll + for (int stride = Power2ScanSize / 4; stride > 0; stride >>= 1) { + int index = (threadIdx.x + 1) * stride * 2 - 1; + if ((index + stride) < Power2ScanSize) { + smem[index + stride] = binop(smem[index + stride], smem[index]); + } + __syncthreads(); + } +} + +// Block-wide reduction where each thread locally reduces N +// values before letting a single warp take over - assumes +// threadVals is in registers, not shared memory +// +// If smem is not used again, there is no need to __syncthreads before this +// call. However, if smem will be used, e.g., this function is called in a loop, +// then __syncthreads is needed either before or afterwards to prevent non-0 +// threads overriding smem in the next loop before num-0 thread reads from it. +template +__device__ T reduceBlockWithNThreadLocalReductions( + T* smem, + T threadVals[N], + const unsigned int numVals, + ReduceOp reduceOp, + T init) { + int offset = threadIdx.x * N; + T local = offset < numVals ? threadVals[0] : init; + +#pragma unroll + for (int i = 1; i < N; ++i) { + ++offset; + T next = offset < numVals ? threadVals[i] : init; + local = reduceOp.combine(local, next); + } + + return cuda_utils::BlockReduce(local, reduceOp, init, smem); +} + +template +__device__ inline void swapVars(T& t1, T& t2) { + T tmp = t1; + t1 = t2; + t2 = tmp; +} + +template +__device__ inline void bitonicSwap( + K& kA, + V& vA, + bool& validA, + K& kB, + V& vB, + bool& validB, + bool dir, + const Comparator& comp) { + // Invalid entries always sort to the end + bool swap = (comp(kA, kB) && validA) || !validB; + if (swap == dir) { + swapVars(kA, kB); + swapVars(vA, vB); + swapVars(validA, validB); + } +}; + +template +__device__ inline void bitonicSwapKeys( + K& kA, + bool& validA, + K& kB, + bool& validB, + bool dir, + const Comparator& comp) { + bool swap = (comp(kA, kB) && validA) || !validB; + if (swap == dir) { + swapVars(kA, kB); + swapVars(validA, validB); + } +} + +template < + typename K, + typename IndexType, + int Power2SortSize, + typename Comparator> +__device__ inline void bitonicSortKeys( + K keys[Power2SortSize], + bool valid[Power2SortSize], + const Comparator& comp) { +#if !defined(USE_ROCM) +#pragma unroll +#endif + for (unsigned int size = 2; size < Power2SortSize; size *= 2) { + bool flag = ((threadIdx.x & (size / 2)) != 0); + +#if !defined(USE_ROCM) +#pragma unroll +#endif + for (unsigned int stride = size / 2; stride > 0; stride /= 2) { + __syncthreads(); + + unsigned int pos = 2 * threadIdx.x - (threadIdx.x & (stride - 1)); + bitonicSwapKeys( + keys[pos], + valid[pos], + keys[pos + stride], + valid[pos + stride], + flag, + comp); + } + } + +#if !defined(USE_ROCM) +#pragma unroll +#endif + for (unsigned int stride = Power2SortSize / 2; stride > 0; stride /= 2) { + __syncthreads(); + + unsigned int pos = 2 * threadIdx.x - (threadIdx.x & (stride - 1)); + bitonicSwapKeys( + keys[pos], + valid[pos], + keys[pos + stride], + valid[pos + stride], + false, + comp); + } + + __syncthreads(); +} + +// The mode kernel has the following characteristics: It uses internal shared +// memory buffers of Power2Size, which must be greater than the number of +// elements. Additionally, there is one block for every slice to calculate the +// mode for, and in each block there is one thread for every two elements. +// +// Both sorted and positions are assumed to be contiguous Tensors with the mode +// dimension as the innermost dim, such that we can get the particular slice for +// a Tensor via its linear block dimension * the slice size. +template +#if defined(CUDA_VERSION) && CUDA_VERSION >= 11070 +__launch_bounds__(1024, 1) +#endif +__global__ void compute_mode( + const T* input, + at::cuda::detail::TensorInfo values, + at::cuda::detail::TensorInfo indices, + int64_t sliceSize, + int64_t slices) { + int tidx = threadIdx.x; + int stidx = blockDim.x + threadIdx.x; // Second index this thread responsible for + + // First, we need to calculate the offset into the sorted Tensor that + // represents the start of the slice for this block to calculate the mode for. + // This offset is a combination of the gridIndices, and the number of elements + // in the slice. + unsigned int blockId = getLinearBlockId(); + unsigned int linearOffset = blockId * sliceSize; + + if (blockId >= slices) { + return; + } + + // shmem is a dynamically sized buffer we will use throughout the kernel to + // handle computation efficiently. The size of this shmem must be + // sizeof(T) * Power2Size + (2 * sizeof(unsigned int) * Power2Size) + // + // Initially, the buffer will be organized as follows: + // + // [smem (slice elements) | bmem (valid indices) | ] + extern __shared__ char shmem[]; + + // smem represents a proportion of the shared memory buffer that is used to + // store the elements from the slice: + T* smem = reinterpret_cast(shmem); + + // Each thread loads up to two elements from the Tensor into shared memory + if (tidx < sliceSize) { + smem[tidx] = c10::load(&input[linearOffset + tidx]); + } + if (stidx < sliceSize) { + smem[stidx] = c10::load(&input[linearOffset + stidx]); + } + + // Next, we initialize a boolean region of the buffer, offset by the loaded + // element smem region + bool* bmem = reinterpret_cast(&smem[Power2Size]); + + // The first use of this region stores bmem[i] = i < sliceSize to mark the + // valid components in the smem buffer + bmem[tidx] = tidx < sliceSize; + bmem[stidx] = stidx < sliceSize; + __syncthreads(); // barrier for smem, bmem initialization + + // First, sort the input slice in ascending order. smem contains the input + // elements, and bmem marks the valid indices + bitonicSortKeys( + smem, bmem, [&] GPU_LAMBDA(const auto& a, const auto& b) { + return a < b; + }); + __syncthreads(); // make no assumptions that the sort syncs at end + + // The next step of our algorithm is performing a block-wide comparison of + // neighboring elements. In particular, given an sorted input slice A, we + // produce an output slice B, such that B[i] = 1 if A[i-i] != A[i], otherwise + // 0. + // + // Given the input A = [0, 0, 1, 1, 2, 2, 2, 4, 5, 6, 6, 7, 8] + // B = [1, 0, 1, 0, 1, 0, 0, 1, 1, 1, 0, 1, 1] + // + // In particular, we can think of B[i] true indicating the start of a sequence + // of equal values in the sorted list. Similarly, we will also store the + // negation of B, which we'll call C. In particular, we can think of C[i] = + // true iff A[i-1] == A[i] in our original sorted slice. + // + // C = [0, 1, 0, 1, 0, 1, 1, 0, 0, 0, 1, 0, 0] + + // We overwrite bmem, and treat the rest of shared memory as a buffer of + // (index, flag) pairs where the index represents values from C, and the flag + // represents values from B. + // + // [smem (sorted slice) | ubpmem (index, flag pairs)] + + struct ModeUnsignedBoolPair* ubpmem = + reinterpret_cast(&smem[Power2Size]); + + if (tidx == 0) { + ubpmem[0].flag = true; + ubpmem[0].val = 0; + } + + // Compares elements (0, 1), (2, 3), ... and sets 1, 3, ... + ubpmem[tidx * 2 + 1].flag = + smem[tidx * 2] != smem[tidx * 2 + 1]; // (0, 1), (1, 2), etc. + ubpmem[tidx * 2 + 1].val = !ubpmem[tidx * 2 + 1].flag; + + // Compares elements (1, 2), (3, 4), ... and sets 2, 4, ... + if (((tidx + 1) * 2) < Power2Size) { + ubpmem[(tidx + 1) * 2].flag = + smem[((tidx + 1) * 2) - 1] != smem[(tidx + 1) * 2]; + ubpmem[(tidx + 1) * 2].val = !ubpmem[(tidx + 1) * 2].flag; + } + __syncthreads(); // barrier for ubpmem initialization + + // Next, we perform a segmented prefix sum on the neighboring elements, where + // the presence of a one indicates the start of a segment. In this case B acts + // as the segment start flags, and C is the buffer to be summed: + // + // Input (C) = [0, 1, 0, 1, 0, 1, 1, 0, 0, 0, 1, 0, 0] + // Flag (B) = [1, 0, 1, 0, 1, 0, 0, 1, 1, 1, 0, 1, 1] + // Output (C) = [0, 1, 0, 1, 0, 1, 2, 0, 0, 0, 1, 0, 0] + // + // Afterwards, the (index) components of the ubpmem buffer contain the lengths + // of the segments (minus 1), i.e. the counts of each element in the original + // input. + inclusivePrefixScan( + ubpmem, [=] GPU_LAMBDA(const auto& a, const auto& b) { + ModeUnsignedBoolPair c; + c.val = a.flag ? a.val : a.val + b.val; + c.flag = a.flag | b.flag; + return c; + }); + // assumes scan syncs at the end + + // Next, we reinterpret the ubpmem buffer as pairs of unsigned integers (i.e. + // we treat the boolean flag regions as integers). We initialize these to + // represent indices, and we'll call this buffer I + struct ModeUnsignedPair* uupmem = + reinterpret_cast(ubpmem); + + // At this point, we need to find the maximum element in lengths buffer C. + // This element will represent the count (-1) of the mode. Because of the + // way we have set up the problem, the index where this mode occurs will + // also be the location of the mode value in the sorted array, e.g. + // + // smem = [0, 0, 1, 1, 1, 2] + // C = [0, 1, 0, 1, 2, 0] + // I = [0, 1, 2, 3, 4, 5] + // ^ + // maximum value, also aligned with mode = 1 + // + // We perform a block wide max-reduction of the C buffer, but we also need the + // indices to come along with it, so we utilize the uupmem construction. + // + // At the end we need to return the ModeUnsignedPair containing index = 4, val + // = 2, which represents the max + + // In practice, we will make each thread locally reduce 2 values in its + // registers prior to the global block-wide reduction. Note that instead of + // tidx/stidx, we utilize tidx * 2, tidx * 2 + 1, so each thread deals with + // adjacent elements. This is because the reduce code below relies on thread + // elements to be adjacent. + struct ModeUnsignedPair uup[2]; + uup[0].index = tidx * 2; + uup[0].val = ubpmem[tidx * 2].val; + uup[1].index = tidx * 2 + 1; + uup[1].val = ubpmem[tidx * 2 + 1].val; + __syncthreads(); + + struct ModeUnsignedPair max = {0, 0}; + + struct MaxOp { + inline __device__ ModeUnsignedPair combine(ModeUnsignedPair a, ModeUnsignedPair b) const { + return b.val > a.val ? b : a; + } + + inline __device__ ModeUnsignedPair warp_shfl_down(ModeUnsignedPair acc, int offset) const { + ModeUnsignedPair ret; + ret.index = WARP_SHFL_DOWN(acc.index, offset); + ret.val = WARP_SHFL_DOWN(acc.val, offset); + return ret; + } + } max_op; + + max = reduceBlockWithNThreadLocalReductions<2>( + uupmem, + uup, + sliceSize, + max_op, + max); + + // Store the mode in shared memory for use in finding the mode in the input + // slice + __shared__ T mode; + + // Given the above constraints, the mode is the value at the reduced index in + // the original sorted element buffer + if (tidx == 0) { + mode = smem[max.index]; + } + __syncthreads(); // broadcast mode + + // Finally, we need to find "an" index of the mode in the input + // Tensor. The API does not constrain which index we pick, but here + // we always pick the largest index. We store the index if the value + // is the mode, or 0 otherwise. Then find the maximum value. + // + // Again we reduce 2 elements in the thread's registers prior to the + // block-wide reduction + unsigned mode_index[2] = {0u, 0u}; + if (tidx * 2 < sliceSize) { + const unsigned idx = tidx * 2; + mode_index[0] = c10::load(&input[linearOffset + idx]) == mode ? idx : 0u; + } + if (tidx * 2 + 1 < sliceSize) { + const unsigned idx = tidx * 2 + 1; + mode_index[1] = c10::load(&input[linearOffset + idx]) == mode ? idx : 0u; + } + + struct MaxIndexOp { + inline __device__ unsigned combine(unsigned a, unsigned b) const { + return b > a ? b : a; + } + + inline __device__ unsigned warp_shfl_down(unsigned acc, int offset) const { + return WARP_SHFL_DOWN(acc, offset); + } + } max_index_op; + + int64_t index = reduceBlockWithNThreadLocalReductions<2>( + reinterpret_cast(&shmem[0]), + mode_index, + sliceSize, + max_index_op, + 0u); + + // Finally, we have the mode, and an index where it occurs. We use a single + // thread to place this in the appropriate output position + if (tidx == 0) { + unsigned int outputOffset = + at::cuda::detail::IndexToOffset::get( + blockId, values); + values.data[outputOffset] = mode; + indices.data[outputOffset] = index; + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/TensorModeKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/TensorModeKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..edf505fc4b8619d5c615e5b1cc36c648a0588ea2 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/TensorModeKernel.h @@ -0,0 +1,18 @@ +#pragma once +#include + +namespace at { +class TensorBase; +} + +namespace at::native { + +void launch_fused_mode_kernel( + const TensorBase &values, const TensorBase &indices, + const TensorBase &self, int64_t slice_size, int64_t slices); + +void launch_apply_mode_kernel( + const TensorBase &values, const TensorBase &indices, + const TensorBase &self, int64_t dim, int64_t ndim); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/TensorTopK.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/TensorTopK.h new file mode 100644 index 0000000000000000000000000000000000000000..74b615d34d00fa97a9bfe3405ca59a015aa19ca7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/TensorTopK.h @@ -0,0 +1,13 @@ +#pragma once +#include + +namespace at { +class TensorBase; +} + +namespace at::native { +void launch_gather_topk_kernel( + const TensorBase& self, + int64_t k, int64_t dim, bool largest, + const TensorBase& values, const TensorBase& indices); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/UniqueCub.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/UniqueCub.cuh new file mode 100644 index 0000000000000000000000000000000000000000..e19ba94b3fb8e6e36e5fa0205e7cdcd824f8feec --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/UniqueCub.cuh @@ -0,0 +1,12 @@ +#include + +namespace at::native::internal { + +template +std::tuple unique_cuda_template( + const Tensor& self, + const bool consecutive, + const bool return_inverse, + const bool return_counts); + +} // namespace at::native::internal diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/UpSample.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/UpSample.cuh new file mode 100644 index 0000000000000000000000000000000000000000..50428b377da85ddac718d05053b59617a39bdb27 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/UpSample.cuh @@ -0,0 +1,368 @@ +#pragma once +#include +#include + +#include +#include +#include + +#include +#include + +namespace at::native { + +namespace upsample { +// TODO: Remove duplicate declaration. +TORCH_API c10::SmallVector compute_output_size( + c10::IntArrayRef input_size, // Full input tensor size. + at::OptionalIntArrayRef output_size, + std::optional> scale_factors); +} // namespace upsample + +namespace upsample_cuda { + +// TODO: Remove duplication with Upsample.h (CPU). +inline std::optional get_scale_value(std::optional> scales, int idx) { + if (!scales) { + return std::nullopt; + } + return scales->at(idx); +} + +} // namespace upsample_cuda + + +/* TODO: move this to a common place */ +template +__device__ inline scalar_t min(scalar_t a, scalar_t b) { + return a < b ? a : b; +} + +template +__device__ inline scalar_t max(scalar_t a, scalar_t b) { + return a > b ? a : b; +} + +// NOTE [ Nearest neighbor upsampling kernel implementation ] +// +// The nearest neighbor upsampling kernel implementation is symmetrical as +// expected. We launch kernels with threads mapping to destination tensors where +// kernels write data to, each thread reads data from the source tensor, this +// means: +// 1. In the forward kernel, +// src_xxx refers to properties of input tensors; +// dst_xxx refers to properties of output tensors; +// scale_factor is the ratio of src_size to dst_size; +// 2. In the backward kernel, +// src_xxx refers to properties of grad_output tensors; +// dst_xxx refers to properties of grad_input tensors; +// scale_factor is the ratio of src_size to dst_size; +// +// Because of this, we need to take the reciprocal of the scale defined by +// upsample layer during forward path. The motivation is to avoid slow +// division in the kernel code, so we can use faster multiplication instead. +// This is not necessary during backward path, since the scale_factor is already +// the reciprocal of corresponding scale_factor used in the forward path due to +// the swap of source and destination tensor. +// +// Similarly, since the mapping from grad_input to grad_output during backward +// is the reverse of the mapping of output to input, we need to have opposite +// mapping functions to compute the source index. + +// see NOTE [ Nearest neighbor upsampling kernel implementation ] +template +__host__ __forceinline__ accscalar_t compute_scales_value( + const std::optional scale, + int64_t src_size, + int64_t dst_size) { + // FIXME: remove magic > 0 after we ensure no models were serialized with -1 defaults. + return (scale.has_value() && scale.value() > 0.) ? (accscalar_t)(1.0 / scale.value()) + : (accscalar_t)src_size / dst_size; +} + +// see NOTE [ Nearest neighbor upsampling kernel implementation ] +template +__host__ __forceinline__ accscalar_t compute_scales_value_backwards( + const std::optional scale, + int64_t src_size, + int64_t dst_size) { + // FIXME: remove magic > 0 after we ensure no models were serialized with -1 defaults. + return (scale.has_value() && scale.value() > 0.) ? (accscalar_t)scale.value() + : (accscalar_t)src_size / dst_size; +} + +template +__host__ __forceinline__ accscalar_t area_pixel_compute_scale( + int input_size, + int output_size, + bool align_corners, + const std::optional scale) { + if(align_corners) { + if(output_size > 1) { + return (accscalar_t)(input_size - 1) / (output_size - 1); + } + else { + return static_cast(0); + } + } + else{ + return compute_scales_value(scale, input_size, output_size); + } +} + +template +__device__ __forceinline__ accscalar_t area_pixel_compute_source_index( + accscalar_t scale, + int dst_index, + bool align_corners, + bool cubic) { + if (align_corners) { + return scale * dst_index; + } else { + accscalar_t src_idx = scale * (dst_index + static_cast(0.5)) - + static_cast(0.5); + // See Note[Follow Opencv resize logic] + return (!cubic && src_idx < static_cast(0)) + ? static_cast(0) + : src_idx; + } +} + +// see NOTE [ Nearest neighbor upsampling kernel implementation ] +__device__ __forceinline__ int nearest_neighbor_compute_source_index( + const float scale, + int dst_index, + int input_size) { + // index_f32 = (output_index) * scale + // input_index = round(index_f32) + // Same as a buggy OpenCV INTER_NEAREST + // We keep this method for BC and consider as deprecated. + // See nearest_neighbor_exact_compute_source_index as replacement + const int src_index = + min(static_cast(floorf((dst_index) * scale)), input_size - 1); + return src_index; +} + +__device__ __forceinline__ int nearest_neighbor_exact_compute_source_index( + const float scale, + int dst_index, + int input_size) { + // index_f32 = (output_index + 0.5) * scale - 0.5 + // input_index = round(index_f32) + // Same as Pillow and Scikit-Image/Scipy ndi.zoom + const int src_index = + min(static_cast(floorf((dst_index + static_cast(0.5)) * scale)), input_size - 1); + return src_index; +} + +// see NOTE [ Nearest neighbor upsampling kernel implementation ] +__device__ __forceinline__ int nearest_neighbor_bw_compute_source_index( + const float scale, + int dst_index, + int output_size) { + // Equivalent to buggy OpenCV INTER_NEAREST + // We keep this method for BC and consider as deprecated. + // See nearest_neighbor_exact_bw_compute_source_index as replacement + const int src_index = + min(static_cast(ceilf(dst_index * scale)), output_size); + return src_index; +} + +// see NOTE [ Nearest neighbor upsampling kernel implementation ] +__device__ __forceinline__ int nearest_neighbor_exact_bw_compute_source_index( + const float scale, + int dst_index, + int output_size) { + // Equivalent to Pillow and Scikit-Image/Scipy ndi.zoom + const int src_index = + min(static_cast(ceilf(dst_index * scale - static_cast(0.5))), output_size); + return src_index; +} + +/* Used by UpSampleBicubic2d.cu */ +template +__device__ __forceinline__ scalar_t upsample_get_value_bounded( + const PackedTensorAccessor64& data, + int batch, + int channel, + int height, + int width, + int y, + int x) { + int access_y = max(min(y, height - 1), 0); + int access_x = max(min(x, width - 1), 0); + return data[batch][channel][access_y][access_x]; +} + +/* Used by UpSampleBicubic2d.cu */ +template +__device__ __forceinline__ void upsample_increment_value_bounded( + PackedTensorAccessor64& data, + int batch, + int channel, + int height, + int width, + int y, + int x, + accscalar_t value) { + int access_y = max(min(y, height - 1), 0); + int access_x = max(min(x, width - 1), 0); + /* TODO: result here is truncated to scalar_t, + check: https://github.com/pytorch/pytorch/pull/19630#discussion_r281426912 + */ + gpuAtomicAddNoReturn( + &data[batch][channel][access_y][access_x], static_cast(value)); +} + +// Based on +// https://en.wikipedia.org/wiki/Bicubic_interpolation#Bicubic_convolution_algorithm +template +__device__ __forceinline__ accscalar_t cubic_convolution1( + accscalar_t x, + accscalar_t A) { + return ((A + 2) * x - (A + 3)) * x * x + 1; +} + +template +__device__ __forceinline__ accscalar_t cubic_convolution2( + accscalar_t x, + accscalar_t A) { + return ((A * x - 5 * A) * x + 8 * A) * x - 4 * A; +} + +template +__device__ __forceinline__ void get_cubic_upsampling_coefficients( + accscalar_t coeffs[4], + accscalar_t t) { + accscalar_t A = -0.75; + + accscalar_t x1 = t; + coeffs[0] = cubic_convolution2(x1 + 1.0, A); + coeffs[1] = cubic_convolution1(x1, A); + + // opposite coefficients + accscalar_t x2 = 1.0 - t; + coeffs[2] = cubic_convolution1(x2, A); + coeffs[3] = cubic_convolution2(x2 + 1.0, A); +} + +template +__device__ __forceinline__ accscalar_t cubic_interp1d( + scalar_t x0, + scalar_t x1, + scalar_t x2, + scalar_t x3, + accscalar_t t) { + accscalar_t coeffs[4]; + get_cubic_upsampling_coefficients(coeffs, t); + + return x0 * coeffs[0] + x1 * coeffs[1] + x2 * coeffs[2] + x3 * coeffs[3]; +} + +namespace upsample_antialias { + +// taken from +// https://github.com/python-pillow/Pillow/blob/6812205f18ca4ef54372e87e1a13ce4a859434df/ +// src/libImaging/Resample.c#L20-L29 +struct BilinearFilterFunctor { + + template + __device__ accscalar_t operator()(accscalar_t x) const { + if (x < 0) { + x = -x; + } + if (x < 1) { + return 1 - x; + } + return 0; + } + + static const int size = 2; +}; + +// taken from +// https://github.com/python-pillow/Pillow/blob/6812205f18ca4ef54372e87e1a13ce4a859434df/ +// src/libImaging/Resample.c#L46-L62 +struct BicubicFilterFunctor { + + template + __device__ accscalar_t operator()(accscalar_t x) const { + // https://en.wikipedia.org/wiki/Bicubic_interpolation#Bicubic_convolution_algorithm + const accscalar_t a = -0.5; + if (x < 0) { + x = -x; + } + if (x < 1) { + return ((a + 2) * x - (a + 3)) * x * x + 1; + } + if (x < 2) { + return (((x - 5) * x + 8) * x - 4) * a; + } + return 0; + } + + static const int size = 4; +}; + +template +__device__ __forceinline__ void _compute_weights_span( + const int i, + const int input_size, + const accscalar_t scale, + const accscalar_t support, + int& xmin, + int& xsize, + accscalar_t& center) { + center = scale * (i + static_cast(0.5)); + xmin = max(static_cast(center - support + static_cast(0.5)), static_cast(0)); + xsize = min(static_cast(center + support + static_cast(0.5)), input_size) - xmin; +} + +template +__device__ __forceinline__ void _compute_weights( + scalar_t* wt_ptr, + const accscalar_t scale, + int interp_size, + const interp_filter_t& interp_filter, + accscalar_t xmin_m_center, + int xsize) { + + accscalar_t invscale = (scale >= 1.0) ? 1.0 / scale : 1.0; + accscalar_t total_w = 0.0; + int j = 0; + for (j = 0; j < xsize; j++) { + accscalar_t w = interp_filter((j + xmin_m_center + static_cast(0.5)) * invscale); + wt_ptr[j] = static_cast(w); + total_w += w; + } + for (j = 0; j < xsize; j++) { + if (total_w != 0.0) { + wt_ptr[j] /= total_w; + } + } + for (; j < interp_size; j++) { + wt_ptr[j] = static_cast(0.0); + } +} + +template +__device__ __forceinline__ accscalar_t interpolate_aa_single_dim( + const scalar_t* src, + const scalar_t* weights, + int size) { + scalar_t t = static_cast(*src); + scalar_t wts = static_cast(weights[0]); + accscalar_t output = t * wts; + + int j = 1; + for (; j < size; j++) { + wts = static_cast(weights[j]); + t = static_cast(*(src + j)); + output += t * wts; + } + return output; +} + +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/block_reduce.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/block_reduce.cuh new file mode 100644 index 0000000000000000000000000000000000000000..2a272d22c0c60edf450363f762c0cf47523bd1ed --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/block_reduce.cuh @@ -0,0 +1,139 @@ +#pragma once + +#include + +#include +#include + +namespace at::native::cuda_utils { + +constexpr int kCUDABlockReduceNumThreads = 512; +// Algorithmic limitation: BlockReduce does two WarpReduce calls, each +// of which reduces C10_WARP_SIZE elements. So, at most +// C10_WARP_SIZE**2 elements can be reduced at a time. +// NOTE: This is >= the max block size on current hardware anyway (1024). +constexpr int kCUDABlockReduceMaxThreads = C10_WARP_SIZE * C10_WARP_SIZE; + +// Sums `val` across all threads in a warp. +// +// Assumptions: +// - The size of each block should be a multiple of `C10_WARP_SIZE` +template +__inline__ __device__ T WarpReduceSum(T val) { +#pragma unroll + for (int offset = (C10_WARP_SIZE >> 1); offset > 0; offset >>= 1) { + val += WARP_SHFL_DOWN(val, offset); + } + return val; +} + +// Picks the maximum `val` across all threads in a warp. +// +// Assumptions: +// - The size of each block should be a multiple of `C10_WARP_SIZE` +template +__inline__ __device__ T WarpReduceMax(T val) { +#pragma unroll + for (int offset = (C10_WARP_SIZE >> 1); offset > 0; offset >>= 1) { + val = max_propagate_nan(val, WARP_SHFL_DOWN(val, offset)); + } + return val; +} + +struct Block1D { + static __forceinline__ __device__ int Tid() { return threadIdx.x; } + + static __forceinline__ __device__ int Warps() { + return blockDim.x / C10_WARP_SIZE; + } +}; + +struct Block2D { + static __forceinline__ __device__ int Tid() { + return threadIdx.x + threadIdx.y * blockDim.x; + } + + static __forceinline__ __device__ int Warps() { + return blockDim.x * blockDim.y / C10_WARP_SIZE; + } +}; + +// Sums `val` across all threads in a block. +// +// Warning: the return value is only valid for thread 0. +// Assumptions: +// - The size of each block should be a multiple of `C10_WARP_SIZE` +// - `shared` should be a pointer to shared memory with size of, at least, +// `sizeof(T) * number_of_warps` +template +__inline__ __device__ T BlockReduceSum(T val, T* shared) { + const int tid = B::Tid(); + const int lid = tid % C10_WARP_SIZE; + const int wid = tid / C10_WARP_SIZE; + val = WarpReduceSum(val); + __syncthreads(); // prevent races when BlockReduces are called in a row. + if (lid == 0) { + shared[wid] = val; + } + __syncthreads(); + val = (tid < B::Warps()) ? shared[lid] : T(0); + if (wid == 0) { + val = WarpReduceSum(val); + } + return val; +} + +// Picks out the maximum `val` across all threads in a block. +// +// Warning: the return value is only valid for thread 0. +// Assumptions: +// - The size of each block should be a multiple of `C10_WARP_SIZE` +// - `shared` should be a pointer to shared memory with size of, at least, +// `sizeof(T) * number_of_warps` +template +__inline__ __device__ T BlockReduceMax(T val, T* shared) { + const int tid = B::Tid(); + const int lid = tid % C10_WARP_SIZE; + const int wid = tid / C10_WARP_SIZE; + val = WarpReduceMax(val); + __syncthreads(); // prevent races when BlockReduces are called in a row. + if (lid == 0) { + shared[wid] = val; + } + __syncthreads(); + val = (tid < B::Warps()) ? shared[lid] : T(std::numeric_limits::lowest()); + if (wid == 0) { + val = WarpReduceMax(val); + } + return val; +} + +template +__inline__ __device__ T WarpReduce(T val, const ReduceOp& op) { +#pragma unroll + for (int offset = (C10_WARP_SIZE >> 1); offset > 0; offset >>= 1) { + val = op.combine(val, op.warp_shfl_down(val, offset)); + } + return val; +} + +template +__inline__ __device__ T +BlockReduce(T val, const ReduceOp& op, const T& identity_element, T* shared) { + const int tid = B::Tid(); + const int lid = tid % C10_WARP_SIZE; + const int wid = tid / C10_WARP_SIZE; + val = WarpReduce(val, op); + __syncthreads(); // prevent races when BlockReduces are called in a row. + if (lid == 0) { + shared[wid] = val; + } + __syncthreads(); + val = (tid < B::Warps()) ? shared[lid] : identity_element; + if (wid == 0) { + val = WarpReduce(val, op); + } + return val; +} + +} // namespace at::native::cuda_utils diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/cutlass_utils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/cutlass_utils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..9d9cafb7426bff97ef64a8bd953ac8c62813c0a2 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/cutlass_utils.cuh @@ -0,0 +1,654 @@ +#pragma once + +#include +#include +#include + +#include + +// TODO remove *BroadcastPtrArrays and replace with just Broadcast +// when https://github.com/NVIDIA/cutlass/pull/2120/ is in the tagged cutlass version + + +namespace cutlass::epilogue::fusion { + using namespace cute; + using namespace detail; + // Row vector broadcast with grouping. +template< + int Stages, + class CtaTileShapeMNK, + class ElementInput, + class ElementCompute = ElementInput, + class StrideMNL_ = Stride<_0,_1,_0>, + int Alignment = 128 / sizeof_bits_v, + bool EnableNullptr = true // Fallback scalar broadcast for nullptr params +> +struct Sm90RowBroadcastPtrArray { + using StrideMNL = StrideMNL_; + static_assert(Stages == 0, "Row broadcast doesn't support smem pipelining"); + + static constexpr bool IsDynamicBroadcast = is_same_v(StrideMNL{}))>, bool>; // row vector or scalar broadcast + static_assert(is_static_v(StrideMNL{}))> || IsDynamicBroadcast); // batch stride can be dynamic or static + static_assert(take<0,2>(StrideMNL{}) == Stride<_0,_1>{} || IsDynamicBroadcast); + + struct SharedStorage { + array_aligned(CtaTileShapeMNK{})> smem; + }; + + struct Arguments { + ElementInput const* const* ptr_row_array = nullptr; + ElementInput null_default = ElementInput(0); + StrideMNL dRow = {}; + }; + + struct Params { + ElementInput const* const* ptr_row_array = nullptr; + ElementCompute null_default = ElementCompute(0); + StrideMNL dRow = {}; + }; + + template + static constexpr Params + to_underlying_arguments(ProblemShape const& problem_shape, Arguments const& args, void* workspace) { + return {args.ptr_row_array, ElementCompute(args.null_default), args.dRow}; + } + + template + static bool + can_implement(ProblemShape const& problem_shape, Arguments const& args) { + return true; + } + + template + static size_t + get_workspace_size(ProblemShape const& problem_shape, Arguments const& args) { + return 0; + } + + template + static cutlass::Status + initialize_workspace(ProblemShape const& problem_shape, Arguments const& args, void* workspace, cudaStream_t stream, + CudaHostAdapter* cuda_adapter = nullptr) { + return cutlass::Status::kSuccess; + } + + CUTLASS_HOST_DEVICE + Sm90RowBroadcastPtrArray() { } + + CUTLASS_HOST_DEVICE + Sm90RowBroadcastPtrArray(Params const& params, SharedStorage const& shared_storage) + : params(params), is_zero_(false), + smem(const_cast(shared_storage.smem.data())) { + auto const& [stride_M, stride_N, stride_L] = params.dRow; + // Nullptr default + if (EnableNullptr && params.ptr_row_array == nullptr) { + is_zero_ = params.null_default == ElementCompute(0); + } + // Dynamic non-batched scalar broadcast + else if (IsDynamicBroadcast && stride_N == bool(0) && stride_L == repeat_like(stride_L, 0)) { + is_zero_ = params.ptr_row_array[0][0] == ElementInput(0); + } + } + + Params params; + bool is_zero_ = false; + ElementInput *smem = nullptr; + + CUTLASS_DEVICE bool + is_producer_load_needed() const { + return false; + } + + CUTLASS_DEVICE bool + is_C_load_needed() const { + return false; + } + + CUTLASS_DEVICE bool + is_zero() const { + return is_zero_; + } + + template + CUTLASS_DEVICE auto + get_producer_load_callbacks(ProducerLoadArgs const& args) { + return EmptyProducerLoadCallbacks{}; + } + + template + struct ConsumerStoreCallbacks : EmptyConsumerStoreCallbacks { + CUTLASS_DEVICE + ConsumerStoreCallbacks( + GS_GTensor tGS_gRow_, GS_STensor tGS_sRow_, + GS_CTensor tGS_cRow_, Tiled_G2S tiled_g2s_, + SR_STensor tSR_sRow_, SR_RTensor tSR_rRow_, + Residue residue_cRow_, ThrNum thr_num_, Params const& params_) + : tGS_gRow(tGS_gRow_) + , tGS_sRow(tGS_sRow_) + , tGS_cRow(tGS_cRow_) + , tiled_G2S(tiled_g2s_) + , tSR_sRow(tSR_sRow_) + , tSR_rRow(tSR_rRow_) + , residue_cRow(residue_cRow_) + , params(params_) + , is_nullptr(EnableNullptr && params_.ptr_row_array == nullptr) { + if (is_nullptr) { + fill(tSR_rRow, params.null_default); + } + } + + GS_GTensor tGS_gRow; // (CPY,CPY_M,CPY_N) + GS_STensor tGS_sRow; // (CPY,CPY_M,CPY_N) + GS_CTensor tGS_cRow; // (CPY,CPY_M,CPY_N) + Tiled_G2S tiled_G2S; + + SR_STensor tSR_sRow; // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + SR_RTensor tSR_rRow; // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + + Residue residue_cRow; // (m, n) + ThrNum thr_num; + Params const& params; + bool is_nullptr; + + CUTLASS_DEVICE void + begin() { + if (is_nullptr) { + return; + } + + auto synchronize = [&] () { cutlass::arch::NamedBarrier::sync(thr_num, cutlass::arch::ReservedNamedBarriers::EpilogueBarrier); }; + Tensor tGS_gRow_flt = filter_zeros(tGS_gRow); + Tensor tGS_sRow_flt = filter_zeros(tGS_sRow); + Tensor tGS_cRow_flt = filter_zeros(tGS_cRow, tGS_gRow.stride()); + + for (int i = 0; i < size(tGS_gRow_flt); ++i) { + if (get<1>(tGS_cRow_flt(i)) >= size<1>(CtaTileShapeMNK{})) { + continue; // OOB of SMEM, + } + if (elem_less(tGS_cRow_flt(i), residue_cRow)) { + tGS_sRow_flt(i) = tGS_gRow_flt(i); + } + else { + tGS_sRow_flt(i) = ElementInput(0); // Set to Zero when OOB so LDS can be issued without any preds. + } + } + synchronize(); + } + + CUTLASS_DEVICE void + begin_loop(int epi_m, int epi_n) { + if (epi_m == 0 and not is_nullptr) { // Assumes M-major subtile loop + Tensor tSR_sRow_flt = filter_zeros(tSR_sRow(_,_,_,epi_m,epi_n)); + Tensor tSR_rRow_flt = make_tensor_like(tSR_sRow_flt); + copy_aligned(tSR_sRow_flt, tSR_rRow_flt); + + constexpr int FrgSize = size(tSR_rRow_flt); + using FrgInput = Array; + using FrgCompute = Array; + using ConvertInput = NumericArrayConverter; + + Tensor tSR_rRow_input_frg = recast(coalesce(tSR_rRow_flt)); + Tensor tSR_rRow_compute_frg = recast(filter(tSR_rRow)); + ConvertInput convert_input{}; + + tSR_rRow_compute_frg(_0{}) = convert_input(tSR_rRow_input_frg(_0{})); + } + } + + template + CUTLASS_DEVICE Array + visit(Array const& frg_acc, int epi_v, int epi_m, int epi_n) { + Array frg_row; + + CUTLASS_PRAGMA_UNROLL + for (int i = 0; i < FragmentSize; ++i) { + frg_row[i] = tSR_rRow(epi_v * FragmentSize + i); + } + + return frg_row; + } + }; + + template < + bool ReferenceSrc, // do register tensors reference the src or dst layout of the tiled copy + class... Args + > + CUTLASS_DEVICE auto + get_consumer_store_callbacks(ConsumerStoreArgs const& args) { + auto [M, N, K, L] = args.problem_shape_mnkl; + auto [m, n, k, l] = args.tile_coord_mnkl; + using ThreadCount = decltype(size(args.tiled_copy)); + + auto layout_N = [&] () { + auto shape_N = get<1>(args.problem_shape_mnkl); + if constexpr (IsDynamicBroadcast) { + auto stride_N = repeat_like(shape_N, int(0)); + if (get<1>(params.dRow) == bool(1)) { + stride_N = transform_leaf(compact_major(shape_N), + [] (auto const& stride) { return static_cast(stride); } + ); + } + return make_layout(shape_N, stride_N); + } + else { + return make_layout(shape_N); + } + }(); + + auto layout_M = make_layout(M, repeat_like(M, _0{})); + auto layout_L = make_layout(L, get<2>(params.dRow)); + Tensor mRow = make_tensor(make_gmem_ptr(params.ptr_row_array[l]), make_layout(layout_M,layout_N,layout_L)); + Tensor gRow = local_tile(mRow(_,_,l), take<0,2>(args.tile_shape_mnk), make_coord(m, n)); // (CTA_M, CTA_N) + Tensor sRow = make_tensor(make_smem_ptr(smem), + make_shape(size<0>(CtaTileShapeMNK{}), size<1>(CtaTileShapeMNK{})), make_shape(_0{}, _1{})); // (CTA_M, CTA_N) + //// G2S: Gmem to Smem + auto tiled_g2s = make_tiled_copy(Copy_Atom{}, + Layout< Shape<_1, ThreadCount>, + Stride<_0, _1>>{}, + Layout<_1>{}); + auto thr_g2s = tiled_g2s.get_slice(args.thread_idx); + Tensor tGS_gRow = thr_g2s.partition_S(gRow); + Tensor tGS_sRow = thr_g2s.partition_D(sRow); + + //// G2S: Coord + Tensor tGS_cRow = thr_g2s.partition_S(args.cD); + + //// S2R: Smem to Reg + Tensor tSR_sRow = sm90_partition_for_epilogue(sRow, args.epi_tile, args.tiled_copy, args.thread_idx); + Tensor tSR_rRow = make_tensor_like(take<0,3>(tSR_sRow)); // (CPY,CPY_M,CPY_N) + + return ConsumerStoreCallbacks( + tGS_gRow, + tGS_sRow, + tGS_cRow, tiled_g2s, + tSR_sRow, + tSR_rRow, + args.residue_cD, + ThreadCount{}, + params); + } +}; + + +// Column vector broadcast with support for grouping. +template< + int Stages, + class CtaTileShapeMNK, + class ElementInput, + class ElementCompute = ElementInput, + class StrideMNL_ = Stride<_1,_0,_0>, + int Alignment = 128 / sizeof_bits_v, + bool EnableNullptr = true // Fallback scalar broadcast for nullptr params +> +struct Sm90ColBroadcastPtrArray { + using StrideMNL = StrideMNL_; + static_assert(Stages == 0, "Column broadcast doesn't support smem pipelining"); + + static constexpr bool IsDynamicBroadcast = is_same_v(StrideMNL{}))>, bool>; // Column vector or scalar broadcast + static_assert(is_static_v(StrideMNL{}))> || IsDynamicBroadcast); // batch stride can be dynamic or static + static_assert(take<0,2>(StrideMNL{}) == Stride<_1,_0>{} || IsDynamicBroadcast); + + // Accumulator distributes col elements evenly amongst threads so we can just directly load from gmem + struct SharedStorage { }; + + struct Arguments { + ElementInput const* const* ptr_col_array = nullptr; + ElementInput null_default = ElementInput(0); + StrideMNL dCol = {}; + }; + + struct Params { + ElementInput const* const* ptr_col_array = nullptr; + ElementCompute null_default = ElementCompute(0); + StrideMNL dCol = {}; + }; + + template + static constexpr Params + to_underlying_arguments(ProblemShape const& problem_shape, Arguments const& args, void* workspace) { + return {args.ptr_col_array, ElementCompute(args.null_default), args.dCol}; + } + + template + static bool + can_implement(ProblemShape const& problem_shape, Arguments const& args) { + return true; + } + + template + static size_t + get_workspace_size(ProblemShape const& problem_shape, Arguments const& args) { + return 0; + } + + template + static cutlass::Status + initialize_workspace(ProblemShape const& problem_shape, Arguments const& args, void* workspace, cudaStream_t stream, + CudaHostAdapter* cuda_adapter = nullptr) { + return cutlass::Status::kSuccess; + } + + CUTLASS_DEVICE bool + is_producer_load_needed() const { + return false; + } + + CUTLASS_DEVICE bool + is_C_load_needed() const { + return false; + } + + CUTLASS_DEVICE bool + is_zero() const { + return is_zero_; + } + + CUTLASS_HOST_DEVICE + Sm90ColBroadcastPtrArray() { } + + CUTLASS_HOST_DEVICE + Sm90ColBroadcastPtrArray(Params const& params, SharedStorage const& shared_storage) + : params(params), is_zero_(false) { + auto const& [stride_M, stride_N, stride_L] = params.dCol; + // Nullptr default + if (EnableNullptr && params.ptr_col_array == nullptr) { + is_zero_ = params.null_default == ElementCompute(0); + } + // Dynamic non-batched scalar broadcast + else if (IsDynamicBroadcast && stride_M == bool(0) && stride_L == repeat_like(stride_L, 0)) { + is_zero_ = params.ptr_col_array[0][0] == ElementInput(0); + } + } + + Params params; + bool is_zero_; + + template + CUTLASS_DEVICE auto + get_producer_load_callbacks(ProducerLoadArgs const& args) { + return EmptyProducerLoadCallbacks{}; + } + + template + struct ConsumerStoreCallbacks : EmptyConsumerStoreCallbacks { + CUTLASS_DEVICE + ConsumerStoreCallbacks(GTensor tCgCol_, RTensor tCrCol_, CTensor tCcCol_, ThrResidue residue_tCcCol_, Params const& params_) + : tCgCol(tCgCol_), + tCrCol(tCrCol_), + tCcCol(tCcCol_), + residue_tCcCol(residue_tCcCol_), + params(params_) { + if (EnableNullptr && params.ptr_col_array == nullptr) { + fill(tCrCol, params.null_default); + } + } + + GTensor tCgCol; // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + RTensor tCrCol; // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + CTensor tCcCol; // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + ThrResidue residue_tCcCol; + Params const& params; + + CUTLASS_DEVICE void + begin() { + if (EnableNullptr && params.ptr_col_array == nullptr) { + return; + } + + // Filter so we don't issue redundant copies over stride-0 modes + // (only works if 0-strides are in same location, which is by construction) + Tensor tCgCol_flt = filter_zeros(tCgCol); + Tensor tCrCol_flt = make_tensor_like(filter_zeros(tCrCol)); + Tensor tCcCol_flt = filter_zeros(tCcCol, tCgCol.stride()); + + constexpr auto MCL = decltype(max_common_layout(tCgCol_flt, tCrCol_flt)){}; + constexpr int V = cute::min(Alignment, size(MCL)); + if constexpr (V > 1) { + using VecType = uint_bit_t>; + Tensor tCgCol_vec = recast(coalesce(tCgCol_flt)); + Tensor tCrCol_vec = recast(coalesce(tCrCol_flt)); + Tensor tCcCol_vec = tensor<1>(zipped_divide(tCcCol_flt, MCL.compose(Int{}))); + auto pred_fn = [&] (auto const&... coords) { return elem_less(tCcCol_vec(coords...), residue_tCcCol); }; + copy_if(pred_fn, tCgCol_vec, tCrCol_vec); + } + else { + auto pred_fn = [&] (auto const&... coords) { return elem_less(tCcCol_flt(coords...), residue_tCcCol); }; + copy_if(pred_fn, tCgCol_flt, tCrCol_flt); + } + + constexpr int FrgSize = size(tCrCol_flt); + using FrgInput = Array; + using FrgCompute = Array; + using ConvertInput = NumericArrayConverter; + + Tensor tCrCol_input_frg = recast(coalesce(tCrCol_flt)); + Tensor tCrCol_compute_frg = recast(filter(tCrCol)); + ConvertInput convert_input{}; + + tCrCol_compute_frg(_0{}) = convert_input(tCrCol_input_frg(_0{})); + } + + template + CUTLASS_DEVICE Array + visit(Array const& frg_acc, int epi_v, int epi_m, int epi_n) { + Array frg_col; + Tensor tCrCol_mn = tCrCol(_,_,_,epi_m,epi_n); + + CUTLASS_PRAGMA_UNROLL + for (int i = 0; i < FragmentSize; ++i) { + frg_col[i] = tCrCol_mn(epi_v * FragmentSize + i); + } + + return frg_col; + } + + }; + + template < + bool ReferenceSrc, // do register tensors reference the src or dst layout of the tiled copy + class... Args + > + CUTLASS_DEVICE auto + get_consumer_store_callbacks(ConsumerStoreArgs const& args) { + + auto [M, N, K, L] = args.problem_shape_mnkl; + auto [m, n, k, l] = args.tile_coord_mnkl; + auto layout_M = [&] () { + auto shape_M = get<0>(args.problem_shape_mnkl); + if constexpr (IsDynamicBroadcast) { + auto stride_M = repeat_like(shape_M, int(0)); + if (get<0>(params.dCol) == bool(1)) { + stride_M = transform_leaf(compact_major(shape_M), + [] (auto const& stride) { return static_cast(stride); } + ); + } + return make_layout(shape_M, stride_M); + } + else { + return make_layout(shape_M); + } + }(); + + auto layout_N = make_layout(N, repeat_like(N, _0{})); + auto layout_L = make_layout(L, get<2>(params.dCol)); + Tensor mCol = make_tensor(make_gmem_ptr(params.ptr_col_array[l]), make_layout(layout_M,layout_N,layout_L)); + Tensor tCgCol = sm90_partition_for_epilogue( // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + mCol, args.tile_shape_mnk, args.tile_coord_mnkl, args.epi_tile, args.tiled_copy, args.thread_idx); + + Tensor mCol_static = make_tensor(make_gmem_ptr(params.ptr_col_array[l]), make_layout(make_layout(M),layout_N,layout_L)); + Tensor tCgCol_static = sm90_partition_for_epilogue( // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + mCol_static, args.tile_shape_mnk, args.tile_coord_mnkl, args.epi_tile, args.tiled_copy, args.thread_idx); + Tensor tCrCol = make_tensor_like(tCgCol_static); // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + + return ConsumerStoreCallbacks(tCgCol, tCrCol, args.tCcD, args.residue_tCcD, params); + } +}; + +///////////////////////////////////////////////////////////////////////////////////////////////// +// +// Do outer product from the column and row loaded +// +template< + int Stages, + class CtaTileShapeMNK, + class ElementScalar, + class StrideColMNL_ = Stride<_1,_0,int64_t>, /// NOTE: Batched scaling untested for now + class StrideRowMNL_ = Stride<_0,_1,int64_t>, + int Alignment = 128 / sizeof_bits_v, + bool EnableNullptr = false // Fallback scalar broadcast for nullptr params +> +struct Sm90OuterProduct { + using StrideColMNL = StrideColMNL_; + using StrideRowMNL = StrideRowMNL_; + static_assert(Stages == 0, "OuterProduct doesn't support smem usage"); + static_assert(Alignment * sizeof_bits_v % 128 == 0, "sub-16B alignment not supported yet"); + static_assert(!EnableNullptr, "Nullptr fallback not implemented"); + static_assert(is_static_v(StrideColMNL{}))> && + is_static_v(StrideRowMNL{}))>, "Only batch stride can be dynamic"); + static_assert(take<0,2>(StrideColMNL{}) == Stride<_1,_0>{} && + take<0,2>(StrideRowMNL{}) == Stride<_0,_1>{}, "Row and column incorrectly formatted"); + + // Accumulator distributes col/row elements evenly amongst threads so we can just directly load from gmem + struct SharedStorage { }; + + struct Arguments { + ElementScalar const* ptr_col = nullptr; + ElementScalar const* ptr_row = nullptr; + StrideColMNL dCol = {}; + StrideRowMNL dRow = {}; + }; + + using Params = Arguments; + + template + static constexpr Params + to_underlying_arguments(ProblemShape const& problem_shape, Arguments const& args, void* workspace) { + return args; + } + + template + static bool + can_implement(ProblemShape const& problem_shape, Arguments const& args) { + return true; + } + + template + static size_t + get_workspace_size(ProblemShape const& problem_shape, Arguments const& args) { + return 0; + } + + template + static cutlass::Status + initialize_workspace(ProblemShape const& problem_shape, Arguments const& args, void* workspace, cudaStream_t stream, + CudaHostAdapter* cuda_adapter = nullptr) { + return cutlass::Status::kSuccess; + } + + CUTLASS_DEVICE bool + is_producer_load_needed() const { + return false; + } + + CUTLASS_DEVICE bool + is_C_load_needed() const { + return false; + } + + CUTLASS_DEVICE bool + is_zero() const { + return false; + } + + CUTLASS_HOST_DEVICE + Sm90OuterProduct() { } + + CUTLASS_HOST_DEVICE + Sm90OuterProduct(Params const& params, SharedStorage const& shared_storage) + : params(params) { } + + Params params; + + template + CUTLASS_DEVICE auto + get_producer_load_callbacks(ProducerLoadArgs const& args) { + return EmptyProducerLoadCallbacks{}; + } + + template< + class GTensorCol, class RTensorCol, + class GTensorRow, class RTensorRow + > + struct ConsumerStoreCallbacks : EmptyConsumerStoreCallbacks { + CUTLASS_DEVICE + ConsumerStoreCallbacks(GTensorCol&& tCgCol, RTensorCol&& tCrCol, + GTensorRow&& tCgRow, RTensorRow&& tCrRow, + Params const& params) + : tCgCol(cute::forward(tCgCol)) + , tCrCol(cute::forward(tCrCol)) + , tCgRow(cute::forward(tCgRow)) + , tCrRow(cute::forward(tCrRow)) + , params(params) {} + + GTensorCol tCgCol; // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + RTensorCol tCrCol; // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + GTensorRow tCgRow; // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + RTensorRow tCrRow; // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + Params const& params; + + CUTLASS_DEVICE void + begin() { + + // Filter so we don't issue redundant copies over stride-0 modes + copy(filter(tCgCol), filter(tCrCol)); + copy(filter(tCgRow), filter(tCrRow)); + } + + template + CUTLASS_DEVICE Array + visit(Array const& frg_acc, int epi_v, int epi_m, int epi_n) { + Array frg_colrow; + Tensor tCrCol_mn = tCrCol(_,_,_,epi_m,epi_n); + Tensor tCrRow_mn = tCrRow(_,_,_,epi_m,epi_n); + + CUTLASS_PRAGMA_UNROLL + for (int i = 0; i < FragmentSize; ++i) { + frg_colrow[i] = static_cast(tCrCol_mn(epi_v * FragmentSize + i) * tCrRow_mn(epi_v * FragmentSize + i)); + } + return frg_colrow; + } + + }; + + template < + bool ReferenceSrc, // do register tensors reference the src or dst layout of the tiled copy + class... Args + > + CUTLASS_DEVICE auto + get_consumer_store_callbacks(ConsumerStoreArgs const& args) { + + auto [M, N, K, L] = args.problem_shape_mnkl; + Tensor mCol = make_tensor(make_gmem_ptr(params.ptr_col), make_shape(M,N,L), params.dCol); + Tensor mRow = make_tensor(make_gmem_ptr(params.ptr_row), make_shape(M,N,L), params.dRow); + Tensor tCgCol = sm90_partition_for_epilogue( // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + mCol, args.tile_shape_mnk, args.tile_coord_mnkl, args.epi_tile, args.tiled_copy, args.thread_idx); + Tensor tCgRow = sm90_partition_for_epilogue( // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + mRow, args.tile_shape_mnk, args.tile_coord_mnkl, args.epi_tile, args.tiled_copy, args.thread_idx); + Tensor tCrCol = make_tensor_like(tCgCol); // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + Tensor tCrRow = make_tensor_like(tCgRow); // (CPY,CPY_M,CPY_N,EPI_M,EPI_N) + + return ConsumerStoreCallbacks< + decltype(tCgCol), decltype(tCrCol), + decltype(tCgRow), decltype(tCrRow) + >( + cute::move(tCgCol), cute::move(tCrCol), + cute::move(tCgRow), cute::move(tCrRow), + params + ); + } + +}; + + + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adam_amsgrad_impl.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adam_amsgrad_impl.cuh new file mode 100644 index 0000000000000000000000000000000000000000..43ce2999862787e6d0bb78c307078cfd62a35a61 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adam_amsgrad_impl.cuh @@ -0,0 +1,38 @@ +#pragma once +#include + +namespace at::native { + +void _fused_adam_amsgrad_cuda_impl_( + at::TensorList params, + at::TensorList grads, + at::TensorList exp_avgs, + at::TensorList exp_avg_sqs, + at::TensorList max_exp_avg_sqs, + at::TensorList state_steps, + const double lr, + const double beta1, + const double beta2, + const double weight_decay, + const double eps, + const bool maximize, + const std::optional& grad_scale, + const std::optional& found_inf); + +void _fused_adam_amsgrad_cuda_impl_( + at::TensorList params, + at::TensorList grads, + at::TensorList exp_avgs, + at::TensorList exp_avg_sqs, + at::TensorList max_exp_avg_sqs, + at::TensorList state_steps, + const at::Tensor& lr, + const double beta1, + const double beta2, + const double weight_decay, + const double eps, + const bool maximize, + const std::optional& grad_scale, + const std::optional& found_inf); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adam_impl.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adam_impl.cuh new file mode 100644 index 0000000000000000000000000000000000000000..676569a762cb5c602296f60e0b4205f96687cd00 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adam_impl.cuh @@ -0,0 +1,36 @@ +#pragma once +#include + +namespace at::native { + +void _fused_adam_cuda_impl_( + at::TensorList params, + at::TensorList grads, + at::TensorList exp_avgs, + at::TensorList exp_avg_sqs, + at::TensorList state_steps, + const double lr, + const double beta1, + const double beta2, + const double weight_decay, + const double eps, + const bool maximize, + const std::optional& grad_scale, + const std::optional& found_inf); + +void _fused_adam_cuda_impl_( + at::TensorList params, + at::TensorList grads, + at::TensorList exp_avgs, + at::TensorList exp_avg_sqs, + at::TensorList state_steps, + const at::Tensor& lr, + const double beta1, + const double beta2, + const double weight_decay, + const double eps, + const bool maximize, + const std::optional& grad_scale, + const std::optional& found_inf); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adam_utils.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adam_utils.cuh new file mode 100644 index 0000000000000000000000000000000000000000..f6949e69f2ca80a39542201fc47a27b4a8fe9a99 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adam_utils.cuh @@ -0,0 +1,200 @@ +#pragma once +#include +#include +#include +#include +#include + +namespace at::native { + +enum class ADAM_MODE : uint8_t { ORIGINAL = 0, ADAMW = 1 }; + +namespace { + +constexpr uint8_t kParamIdx = 0; +constexpr uint8_t kGradIdx = 1; +constexpr uint8_t kExpAvgIdx = 2; +constexpr uint8_t kExpAvgSqIdx = 3; +constexpr uint8_t kMaxExpAvgSqIdx = 4; + +template < + typename scalar_type, + typename opmath_t, + int depth, + ADAM_MODE adam_mode, + bool amsgrad> +C10_DEVICE inline void adam_math( + scalar_type r_args[depth][kILP], + const double& lr, + const double& beta1, + const double& beta2, + const double& weight_decay, + const double& eps, + const bool& maximize, + const float* grad_scale_ptr, + const float* found_inf_ptr, + const opmath_t& bias_correction1, + const opmath_t& bias_correction2_sqrt) { + static_assert(depth == 4 || depth == 5); +#pragma unroll + for (int ii = 0; ii < kILP; ii++) { + // Load values. + opmath_t param = static_cast(r_args[kParamIdx][ii]); + opmath_t grad = static_cast(r_args[kGradIdx][ii]); + if (grad_scale_ptr) { + grad /= (static_cast(*grad_scale_ptr)); + } + const opmath_t grad_to_store = grad; + if (maximize) { + grad = -grad; + } + opmath_t exp_avg = static_cast(r_args[kExpAvgIdx][ii]); + opmath_t exp_avg_sq = static_cast(r_args[kExpAvgSqIdx][ii]); + opmath_t max_exp_avg_sq; + if (amsgrad) { + max_exp_avg_sq = static_cast(r_args[kMaxExpAvgSqIdx][ii]); + } + // Update param, grad, 1st and 2nd order momentum. + if (weight_decay != 0) { + if constexpr (adam_mode == ADAM_MODE::ORIGINAL) { + grad += param * weight_decay; + } else if constexpr (adam_mode == ADAM_MODE::ADAMW) { + param -= lr * weight_decay * param; + } + } + // todo(crcrpar): use lerp + // ref: https://developer.nvidia.com/blog/lerp-faster-cuda/ + exp_avg = beta1 * exp_avg + (1 - beta1) * grad; + exp_avg_sq = beta2 * exp_avg_sq + (1 - beta2) * grad * grad; + const opmath_t step_size = lr / bias_correction1; + opmath_t denom; + if (amsgrad) { + max_exp_avg_sq = std::max(max_exp_avg_sq, exp_avg_sq); + denom = (std::sqrt(max_exp_avg_sq) / bias_correction2_sqrt) + eps; + } else { + denom = (std::sqrt(exp_avg_sq) / bias_correction2_sqrt) + eps; + } + param -= step_size * exp_avg / denom; + + // Store results. + r_args[kParamIdx][ii] = param; + if (grad_scale_ptr) { + r_args[kGradIdx][ii] = grad_to_store; + } + r_args[kExpAvgIdx][ii] = exp_avg; + r_args[kExpAvgSqIdx][ii] = exp_avg_sq; + if (amsgrad) { + r_args[kMaxExpAvgSqIdx][ii] = max_exp_avg_sq; + } + } +} + +// [note: Conditional Gradient Store when `optimizer.step` is called by +// GradScaler] When a user is training their model(s) with an FP16 AMP recipe, +// parameter updates are done via `grad_scaler.step(optimizer)` instead of +// `optimizer.step()`. For most optimizers, GradScaler unscales gradients on +// behalf of those optimizers. Also, before `.step`, it makes sure that all the +// gradients involved are finite, which incurs a device sync. On the other hand, +// fused optimizers set their member variable of `_step_supports_amp_scaling` to +// `True` in order to remove the device sync above. This means that fused +// optimizers have to have their CUDA kernels (a) unscale gradients and (b) skip +// parameter updates accordingly. To be functionally on par with `torch.optim` +// optimizers and `_multi_tensor` ones, the kernel below writes out gradients +// only when `grad_scale_ptr != nullptr. +template +struct FusedAdamMathFunctor { + static_assert( + depth == 4 || depth == 5, + "depth of 4 for Adam, depth of 5 for Adam with AMSGrad."); + using opmath_t = at::opmath_type; + C10_DEVICE __forceinline__ void operator()( + int chunk_size, + FusedOptimizerTensorListMetadata& tl, + const float* lr_ptr, + const double& lr, + const double& beta1, + const double& beta2, + const double& weight_decay, + const double& eps, + const bool& maximize, + const float* grad_scale_ptr, + const float* found_inf_ptr) { + const auto tensor_loc = tl.block_to_tensor[blockIdx.x]; + const auto chunk_idx = tl.block_to_chunk[blockIdx.x]; + const double lr_double = lr_ptr ? *lr_ptr : lr; + + if (found_inf_ptr && *found_inf_ptr == 1) { + return; + } + const auto [bias_correction1, bias_correction2_sqrt] = + [&]() -> std::pair { + auto* step_count = + reinterpret_cast(tl.state_steps_addresses[tensor_loc]); + const auto bias_correction1 = 1 - at::native::pow_(beta1, *step_count); + const auto bias_correction2 = 1 - at::native::pow_(beta2, *step_count); + const auto bias_correction2_sqrt = std::sqrt(bias_correction2); + return {bias_correction1, bias_correction2_sqrt}; + }(); + + scalar_type* args[depth]; + scalar_type r_args[depth][kILP]; + const auto n = tl.numel_for_tensor[tensor_loc] - chunk_idx * chunk_size; + + const bool all_aligned{ + init_args(args, tl, chunk_idx, chunk_size, tensor_loc)}; + if ((n % kILP == 0) && (chunk_size % kILP == 0) && all_aligned) { + for (int64_t i_start = threadIdx.x; + i_start * kILP < n && i_start * kILP < chunk_size; + i_start += blockDim.x) { +#pragma unroll + for (int i = 0; i < depth; i++) { + load_store(r_args[i], args[i], 0, i_start); + } + adam_math( + r_args, + lr_double, + beta1, + beta2, + weight_decay, + eps, + maximize, + grad_scale_ptr, + found_inf_ptr, + bias_correction1, + bias_correction2_sqrt); +#pragma unroll + for (int i = 0; i < depth; i++) { + if (i != kGradIdx || grad_scale_ptr) { + load_store(args[i], r_args[i], i_start, 0); + } + } + } + } else { + for (int64_t i_start = 0; i_start < n && i_start < chunk_size; + i_start += blockDim.x * kILP) { + load_args(r_args, args, i_start, chunk_size, n); + adam_math( + r_args, + lr_double, + beta1, + beta2, + weight_decay, + eps, + maximize, + grad_scale_ptr, + found_inf_ptr, + bias_correction1, + bias_correction2_sqrt); +#pragma unroll + for (int i = 0; i < depth; i++) { + if (i != kGradIdx || grad_scale_ptr) { + store_args(args[i], r_args[i], i_start, chunk_size, n); + } + } + } + } + } +}; +} // namespace + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adamw_amsgrad_impl.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adamw_amsgrad_impl.cuh new file mode 100644 index 0000000000000000000000000000000000000000..18d9baa6200ff10d2b9df491269f5e779fe93969 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adamw_amsgrad_impl.cuh @@ -0,0 +1,38 @@ +#pragma once +#include + +namespace at::native { + +void _fused_adamw_amsgrad_cuda_impl_( + at::TensorList params, + at::TensorList grads, + at::TensorList exp_avgs, + at::TensorList exp_avg_sqs, + at::TensorList max_exp_avg_sqs, + at::TensorList state_steps, + const double lr, + const double beta1, + const double beta2, + const double weight_decay, + const double eps, + const bool maximize, + const std::optional& grad_scale, + const std::optional& found_inf); + +void _fused_adamw_amsgrad_cuda_impl_( + at::TensorList params, + at::TensorList grads, + at::TensorList exp_avgs, + at::TensorList exp_avg_sqs, + at::TensorList max_exp_avg_sqs, + at::TensorList state_steps, + const at::Tensor& lr, + const double beta1, + const double beta2, + const double weight_decay, + const double eps, + const bool maximize, + const std::optional& grad_scale, + const std::optional& found_inf); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adamw_impl.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adamw_impl.cuh new file mode 100644 index 0000000000000000000000000000000000000000..cae11356dd3c1df9c4924a20f9a984981bbcff2e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/fused_adamw_impl.cuh @@ -0,0 +1,36 @@ +#pragma once +#include + +namespace at::native { + +void _fused_adamw_cuda_impl_( + at::TensorList params, + at::TensorList grads, + at::TensorList exp_avgs, + at::TensorList exp_avg_sqs, + at::TensorList state_steps, + const double lr, + const double beta1, + const double beta2, + const double weight_decay, + const double eps, + const bool maximize, + const std::optional& grad_scale, + const std::optional& found_inf); + +void _fused_adamw_cuda_impl_( + at::TensorList params, + at::TensorList grads, + at::TensorList exp_avgs, + at::TensorList exp_avg_sqs, + at::TensorList state_steps, + const at::Tensor& lr, + const double beta1, + const double beta2, + const double weight_decay, + const double eps, + const bool maximize, + const std::optional& grad_scale, + const std::optional& found_inf); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/im2col.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/im2col.cuh new file mode 100644 index 0000000000000000000000000000000000000000..6b694cee3fbdf1a3bf9befb258e2cca8664f5eb3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/im2col.cuh @@ -0,0 +1,336 @@ +#pragma once + +#include +#include +#include + +#include + +namespace at::native { + +using namespace at::cuda::detail; + +// Kernel for fast unfold+copy +// (borrowed from Caffe: +// https://github.com/BVLC/caffe/blob/master/src/caffe/layers/conv_layer.cu) +// CUDA_NUM_THREADS = 1024 + +template +C10_LAUNCH_BOUNDS_1(1024) +__global__ void im2col_kernel( + const int64_t n, + const dt* data_im, + const int64_t height, + const int64_t width, + const int64_t kernel_height, + const int64_t kernel_width, + const int64_t pad_height, + const int64_t pad_width, + const int64_t stride_height, + const int64_t stride_width, + const int64_t dilation_height, + const int64_t dilation_width, + const int64_t height_col, + const int64_t width_col, + dt* data_col) { + CUDA_KERNEL_LOOP_TYPE(index, n, int64_t) { + int64_t w_out = index % width_col; + + int64_t idx = index / width_col; + + int64_t h_out = idx % height_col; + int64_t channel_in = idx / height_col; + int64_t channel_out = channel_in * kernel_height * kernel_width; + int64_t h_in = h_out * stride_height - pad_height; + int64_t w_in = w_out * stride_width - pad_width; + + dt* col = data_col + (channel_out * height_col + h_out) * width_col + w_out; + const dt* im = data_im + (channel_in * height + h_in) * width + w_in; + + for (int64_t i = 0; i < kernel_height; ++i) { + for (int64_t j = 0; j < kernel_width; ++j) { + int64_t h = h_in + i * dilation_height; + int64_t w = w_in + j * dilation_width; + *col = (h >= 0 && w >= 0 && h < height && w < width) + ? im[i * dilation_height * width + j * dilation_width] + : static_cast
(0); + col += height_col * width_col; + } + } + } +} + +template +void im2col( + cudaStream_t stream, + const dt* data_im, + const int64_t channels, + const int64_t height, + const int64_t width, + const int64_t height_col, + const int64_t width_col, + const int64_t kernel_height, + const int64_t kernel_width, + const int64_t pad_height, + const int64_t pad_width, + const int64_t stride_height, + const int64_t stride_width, + const int64_t dilation_height, + const int64_t dilation_width, + dt* data_col) { + // We are going to launch channels * height_col * width_col kernels, each + // kernel responsible for copying a single-channel grid. + int64_t num_kernels = channels * height_col * width_col; + // Launch CUDA_NUM_THREADS = 1024 + im2col_kernel<<>>( + num_kernels, + data_im, + height, + width, + kernel_height, + kernel_width, + pad_height, + pad_width, + stride_height, + stride_width, + dilation_height, + dilation_width, + height_col, + width_col, + data_col); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +__forceinline__ __device__ void col2im_device( + const int64_t index, + const dt* data_col, + const int64_t height, + const int64_t width, + const int64_t kernel_h, + const int64_t kernel_w, + const int64_t pad_height, + const int64_t pad_width, + const int64_t stride_height, + const int64_t stride_width, + const int64_t dilation_height, + const int64_t dilation_width, + const int64_t height_col, + const int64_t width_col, + dt* data_im) { + accT val = static_cast(0); + const int64_t w_im = index % width + pad_width; + const int64_t h_im = (index / width) % height + pad_height; + const int64_t c_im = index / (width * height); + int64_t kernel_extent_w = (kernel_w - 1) * dilation_width + 1; + int64_t kernel_extent_h = (kernel_h - 1) * dilation_height + 1; + // compute the start and end of the output + const int64_t w_col_start = (w_im < kernel_extent_w) + ? 0 + : (w_im - kernel_extent_w) / stride_width + 1; + const int64_t w_col_end = ::min(w_im / stride_width + 1, width_col); + const int64_t h_col_start = (h_im < kernel_extent_h) + ? 0 + : (h_im - kernel_extent_h) / stride_height + 1; + const int64_t h_col_end = ::min(h_im / stride_height + 1, height_col); + + // TODO: use LCM of stride and dilation to avoid unnecessary loops + for (int64_t h_col = h_col_start; h_col < h_col_end; h_col += 1) { + for (int64_t w_col = w_col_start; w_col < w_col_end; w_col += 1) { + int64_t h_k = (h_im - h_col * stride_height); + int64_t w_k = (w_im - w_col * stride_width); + if (h_k % dilation_height == 0 && w_k % dilation_width == 0) { + h_k /= dilation_height; + w_k /= dilation_width; + int64_t data_col_index = + (((c_im * kernel_h + h_k) * kernel_w + w_k) * height_col + + h_col) * + width_col + + w_col; + val += data_col[data_col_index]; + } + } + } + data_im[index] = static_cast
(val); +} + +template +C10_LAUNCH_BOUNDS_1(512) +__global__ void col2im_kernel( + const int64_t n, + const dt* data_col, + const int64_t height, + const int64_t width, + const int64_t kernel_h, + const int64_t kernel_w, + const int64_t pad_height, + const int64_t pad_width, + const int64_t stride_height, + const int64_t stride_width, + const int64_t dilation_height, + const int64_t dilation_width, + const int64_t height_col, + const int64_t width_col, + dt* data_im) { + CUDA_KERNEL_LOOP(index, n) { + col2im_device( + index, + data_col, + height, + width, + kernel_h, + kernel_w, + pad_height, + pad_width, + stride_height, + stride_width, + dilation_height, + dilation_width, + height_col, + width_col, + data_im); + } +} + +template +void col2im( + cudaStream_t stream, + const dt* data_col, + const int64_t channels, + const int64_t height, + const int64_t width, + const int64_t height_col, + const int64_t width_col, + const int64_t patch_height, + const int64_t patch_width, + const int64_t pad_height, + const int64_t pad_width, + const int64_t stride_height, + const int64_t stride_width, + const int64_t dilation_height, + const int64_t dilation_width, + dt* data_im) { + int64_t num_kernels = channels * height * width; + // To avoid involving atomic operations, we will launch one kernel per + // bottom dimension, and then in the kernel add up the top dimensions. + // CUDA_NUM_THREADS = 1024 + col2im_kernel + <<>>( + num_kernels, + data_col, + height, + width, + patch_height, + patch_width, + pad_height, + pad_width, + stride_height, + stride_width, + dilation_height, + dilation_width, + height_col, + width_col, + data_im); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +C10_LAUNCH_BOUNDS_1(512) +__global__ void col2im_batched_kernel( + const int64_t n, + const dt* data_col, + const int64_t col_batch_stride, + const int64_t nbatch, + const int64_t height, + const int64_t width, + const int64_t kernel_h, + const int64_t kernel_w, + const int64_t pad_height, + const int64_t pad_width, + const int64_t stride_height, + const int64_t stride_width, + const int64_t dilation_height, + const int64_t dilation_width, + const int64_t height_col, + const int64_t width_col, + dt* data_im, + const int64_t im_batch_stride) { + using accT = at::acc_type; + const auto im_numel = n * nbatch; + + CUDA_KERNEL_LOOP_TYPE(index, im_numel, int64_t) { + const auto ibatch = index / n; + const auto slice_index = index % n; + + col2im_device( + slice_index, + data_col + ibatch * col_batch_stride, + height, + width, + kernel_h, + kernel_w, + pad_height, + pad_width, + stride_height, + stride_width, + dilation_height, + dilation_width, + height_col, + width_col, + data_im + ibatch * im_batch_stride); + } +} + +template +void col2im_batched( + cudaStream_t stream, + const dt* data_col, + const int64_t col_batch_stride, + const int64_t nbatch, + const int64_t channels, + const int64_t height, + const int64_t width, + const int64_t height_col, + const int64_t width_col, + const int64_t patch_height, + const int64_t patch_width, + const int64_t pad_height, + const int64_t pad_width, + const int64_t stride_height, + const int64_t stride_width, + const int64_t dilation_height, + const int64_t dilation_width, + dt* data_im, + const int64_t im_batch_stride) { + const int64_t num_kernels = channels * height * width; + const int64_t output_numel = nbatch * num_kernels; + if (output_numel == 0) { + return; // No work to do + } + + // To avoid involving atomic operations, we will launch one kernel per + // bottom dimension, and then in the kernel add up the top dimensions. + // CUDA_NUM_THREADS = 1024 + col2im_batched_kernel<<>>( + num_kernels, + data_col, + col_batch_stride, + nbatch, + height, + width, + patch_height, + patch_width, + pad_height, + pad_width, + stride_height, + stride_width, + dilation_height, + dilation_width, + height_col, + width_col, + data_im, + im_batch_stride); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/jit_utils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/jit_utils.h new file mode 100644 index 0000000000000000000000000000000000000000..7961af63cced26b93a1fcadba1a6ade25f1adb0c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/jit_utils.h @@ -0,0 +1,249 @@ +#pragma once + +#include + +#include +#include +#include + +namespace at::cuda::jit { + +enum class BinaryFuncVariant {NoScalar, RhsScalar, LhsScalar}; + +struct NvrtcFunction { + CUmodule module = CUmodule(); + CUfunction function = nullptr; +}; + +struct KernelDescriptor { + std::string name; + std::string f; + c10::ScalarType f_inputs_type; + c10::ScalarType result_type; + c10::SmallVector extra_args_types; + int nInputs, nOutputs; +}; + +// Helper function to return a vector +// corresponding to the type of the arguments in parameter pack. +template +c10::SmallVector get_extra_args_types() { + return {c10::CppTypeToScalarType::value ...}; +} + +template < + typename result_type, + typename f_inputs_type, + typename... ExtraArgs> +KernelDescriptor make_kernel_descriptor( + std::string name, + std::string f, + int nInputs, + int nOutputs) { + KernelDescriptor ret; + ret.name = std::move(name); + ret.f = std::move(f); + ret.f_inputs_type = c10::CppTypeToScalarType::value; + ret.result_type = c10::CppTypeToScalarType::value; + ret.extra_args_types = get_extra_args_types(); + ret.nInputs = nInputs; + ret.nOutputs = nOutputs; + return ret; +} + +inline int can_vectorize_up_to(size_t default_alignment, void *pointer) { + auto ip = reinterpret_cast(pointer); +#ifdef USE_ROCM + if ((default_alignment == 1) && (ip % (16 * default_alignment) == 0)) { + return 16; + } + if ((default_alignment <= 2) && (ip % (8 * default_alignment) == 0)) { + return 8; + } +#else + if (ip % (8 * default_alignment) == 0) { + return 8; + } +#endif + if (ip % (4 * default_alignment) == 0) { + return 4; + } + if (ip % (2 * default_alignment) == 0) { + return 2; + } + return 1; +} + +inline int can_vectorize_up_to(const KernelDescriptor &desc, c10::ArrayRef pointers) { + TORCH_INTERNAL_ASSERT(desc.nOutputs == 1); + TORCH_INTERNAL_ASSERT(static_cast(pointers.size()) == 1 + desc.nInputs); + + // Deals with output + auto result_size = c10::scalarTypeToTypeMeta(desc.result_type).itemsize(); + auto result = can_vectorize_up_to(result_size, pointers[0]); + + // Incorporates input(s) + auto input_size = c10::scalarTypeToTypeMeta(desc.f_inputs_type).itemsize(); + for (auto i : c10::irange(1, pointers.size())) { + result = std::min(result, can_vectorize_up_to(input_size, pointers[i])); + } + + return result; +} + +//FIXME - this are defined in Loops.cuh, but including Loops.cuh here would lead to circular includes Loops.cuh -> CUDALoops.cuh -> jit_utils.h -> Loops.cuh +#ifdef USE_ROCM +#define JIT_THREAD_WORK_SIZE 4 +#else +#define JIT_THREAD_WORK_SIZE 8 +#endif + +int calc_io_size( + const int nInputs, + const int nOutputs, + const c10::ScalarType& inputs_type, + const c10::ScalarType& result_type); + +int calc_thread_work_size( + const int nInputs, + const int nOutputs, + const c10::ScalarType& inputs_type, + const c10::ScalarType& result_type); + +std::string generate_code( + int nInputs, + int nOutputs, + const std::string& func, + const std::string& name, + const std::string& f_inputs_type, + const std::string& compute_type, + const std::string& result_type, + bool contiguous, + bool dynamic_casting, + BinaryFuncVariant scalar_pos, + c10::SmallVector& extra_args_typenames, + int thread_work_size=JIT_THREAD_WORK_SIZE, + bool vectorized=false, + int vec_size=0, + bool return_by_ref=false); + +std::string generate_code( + const KernelDescriptor &desc, + bool contiguous, + bool dynamic_casting, + BinaryFuncVariant scalar_pos, + int thread_work_size=JIT_THREAD_WORK_SIZE, + bool vectorized=false, + int vec_size=0, + bool return_by_ref=false); + +std::string generate_reduction_code( + int nOutputs, + const std::string& func, + const std::string& name, + const int vt0, + const std::string& f_inputs_type, + const std::string& reduction_accum_type, + const std::string& result_type, + bool contiguous, + bool vectorized, + int vec_size, + int max_threads_codegen); + +std::string generate_reduction_code( + const KernelDescriptor &desc, + const int vt0, + bool contiguous, + bool vectorized, + int vec_size, + int max_threads_codegen); + +NvrtcFunction jit_pwise_function( + const std::string& code, + const std::string& kernel_name); + +void launch_jitted_pwise_function( + NvrtcFunction function, + const void* args[], + const dim3 nBlocks, + const dim3 kBlockSize, + const int smem=0); + +template +struct delayed_false : std::false_type { +}; + +// Defines type names +// NOTE: General case is instantiated only for invalid types. +// All the valid types have specialization using the TYPE_NAME_FN +// macro below. +template +inline std::string typeName() { + // we can't use static_assert(false) directly as the + // program will be not compiled even if the template is not + // instantiated, so we use `delayed_false` + // to make sure compiler doesn't eagerly raise + // fail this assertion. + static_assert(delayed_false::value, "invalid type for jiterator"); + return "void"; +} + +#define TYPE_NAME_FN(ctype, name) \ +template <> inline std::string typeName(){ \ + return std::string(#ctype); \ +} + +AT_FORALL_SCALAR_TYPES(TYPE_NAME_FN) +#undef TYPE_NAME_FN +// JIT uses std::complex directly, because nvRTC compile programs +// with -default-device, so there is no such issue like: +// "std::sin(complex) is __host__ only" +template <> inline std::string typeName(){ + return "bool"; +} +template <> inline std::string typeName>(){ + return "std::complex"; +} +template <> inline std::string typeName>(){ + return "std::complex"; +} +template <> inline std::string typeName>(){ + return "std::complex"; +} +template <> inline std::string typeName(){ + return "at::Half"; +} +template <> inline std::string typeName(){ + return "at::BFloat16"; +} +template <> inline std::string typeName(){ + return "at::Float8_e5m2"; +} +template <> inline std::string typeName(){ + return "at::Float8_e4m3fn"; +} +template <> inline std::string typeName() { + return "at::Float8_e5m2fnuz"; +} +template <> inline std::string typeName() { + return "at::Float8_e4m3fnuz"; +} +template <> inline std::string typeName() { + // TODO(#146647): Can the code here be made generic for any scalartype? + return "at::Float8_e8m0fnu"; +} + +#define TYPE_NAME_CASE(ctype, scalartype) \ + case ScalarType::scalartype: return typeName(); +inline std::string typeName(ScalarType t) { + switch (t) { + AT_FORALL_SCALAR_TYPES_WITH_COMPLEX(TYPE_NAME_CASE) + default: + TORCH_CHECK(false, "invalid type for jiterator"); + } +} +#undef TYPE_NAME_CASE + +TORCH_CUDA_CPP_API void initializeCudaContext(); + +} // namespace at::cuda::jit diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/reduction_template.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/reduction_template.cuh new file mode 100644 index 0000000000000000000000000000000000000000..98c4639682477f497f30e64b4b184e6211a20c1c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/reduction_template.cuh @@ -0,0 +1,680 @@ +namespace at::cuda { +//windows doesn't like large string literals, so split in two +const std::string reduction_template_0 = R"ESCAPE( + #define C10_HOST_DEVICE __host__ __device__ + #define C10_DEVICE __device__ + #if defined(__clang__) && defined(__HIP__) + #ifndef __forceinline__ + #define __forceinline__ inline __attribute__((always_inline)) + #endif + // until ROCm support for kernel asserts is restored + #define assert(expr) (static_cast(0)) + #endif + + template + __device__ __forceinline__ T WARP_SHFL_DOWN(T value, unsigned int delta, int width = warpSize, unsigned int mask = 0xffffffff) + { + #if defined(__clang__) && defined(__HIP__) + return __shfl_down(value, delta, width); + #else + return __shfl_down_sync(mask, value, delta, width); + #endif + } + + + #if ${complex} + template + __device__ __forceinline__ std::complex WARP_SHFL_DOWN(std::complex value, unsigned int delta, int width = warpSize, unsigned int mask = 0xffffffff) + { + return std::complex( + #if defined(__clang__) && defined(__HIP__) + __shfl_down(value.real(), delta, width), + __shfl_down(value.imag(), delta, width)); + #else + __shfl_down_sync(mask, value.real(), delta, width), + __shfl_down_sync(mask, value.imag(), delta, width)); + #endif + } + #endif + + // aligned vector generates vectorized load/store on CUDA + template + struct alignas(sizeof(scalar_t) * vec_size) aligned_vector { + scalar_t val[vec_size]; + }; + + + C10_HOST_DEVICE static void reduce_fraction(size_t &numerator, size_t &denominator) { + // get GCD of num and denom using Euclid's algorithm. + // Can replace this with std::gcd if we ever support c++17. + size_t a = denominator; + size_t b = numerator; + while (b != 0) { + a %= b; + // swap(a,b) + size_t tmp = a; + a = b; + b = tmp; + } + + // a is now the GCD + numerator /= a; + denominator /= a; + } + + + + + struct ReduceConfig { + //has to match host-side ReduceConfig in the eager code + static constexpr int BLOCK_X = 0; + static constexpr int BLOCK_Y = 1; + static constexpr int CTA = 2; + + static constexpr int input_vec_size = 4; + int element_size_bytes; + int num_inputs; + int num_outputs; + int step_input = 1; + int step_output = 1; + int ctas_per_output = 1; + int input_mult[3] = {0, 0, 0}; + int output_mult[2] = {0, 0}; + + int block_width; + int block_height; + int num_threads; + + bool vectorize_input = false; + int output_vec_size = 1; + + C10_HOST_DEVICE bool should_block_x_reduce() const { + return input_mult[BLOCK_X] != 0; + } + + C10_HOST_DEVICE bool should_block_y_reduce() const { + return input_mult[BLOCK_Y] != 0; + } + + C10_HOST_DEVICE bool should_global_reduce() const { + return input_mult[CTA] != 0; + } + + C10_DEVICE bool should_store(int output_idx) const { + return output_idx < num_outputs && + (!should_block_x_reduce() || threadIdx.x == 0) && + (!should_block_y_reduce() || threadIdx.y == 0); + } + + C10_DEVICE bool should_reduce_tail() const { + return (!should_block_y_reduce() || threadIdx.y == 0) && + (!should_global_reduce() || blockIdx.y == 0); + } + + C10_HOST_DEVICE int input_idx() const { + int lane = threadIdx.x; + int warp = threadIdx.y; + int cta2 = blockIdx.y; + return (lane * input_mult[BLOCK_X] + + warp * input_mult[BLOCK_Y] + + cta2 * input_mult[CTA]); + } + + template + C10_HOST_DEVICE int output_idx() const { + int lane = threadIdx.x; + int warp = threadIdx.y; + int cta1 = blockIdx.x; + return (lane * output_mult[BLOCK_X] + + warp * output_mult[BLOCK_Y] + + cta1 * step_output) * output_vec_size; + } + + C10_DEVICE int shared_memory_offset(int offset) const { + return threadIdx.x + (threadIdx.y + offset) * blockDim.x; + } + + C10_DEVICE int staging_memory_offset(int cta2) const { + int offset = cta2 + blockIdx.x * gridDim.y; + if (!should_block_x_reduce()) { + offset = threadIdx.x + offset * blockDim.x; + } + return offset; + } + + + }; + + +//TODO this will need to be different for more generic reduction functions +namespace reducer { + + using scalar_t = ${scalar_type}; + using arg_t = ${reduction_accum_type}; + using out_scalar_t = ${result_type}; + + + inline __device__ ${functor} + + inline __device__ out_scalar_t project(arg_t arg) { + return (out_scalar_t) arg; + } + + inline __device__ arg_t warp_shfl_down(arg_t arg, int offset) { + return WARP_SHFL_DOWN(arg, offset); + } + + inline __device__ arg_t translate_idx(arg_t acc, int64_t /*idx*/) { + return acc; + } + + // wrap a normal reduction that ignores the index + inline __device__ arg_t reduce(arg_t acc, arg_t val, int64_t idx) { + return combine(acc, val); + } +} + + +struct ReduceJitOp { + using scalar_t = ${scalar_type}; + using arg_t = ${reduction_accum_type}; + using out_scalar_t = ${result_type}; + + using InputCalculator = OffsetCalculator<1>; + using OutputCalculator = OffsetCalculator<2>; + +// static constexpr bool can_accumulate_in_output = +// std::is_convertible_v +// && std::is_convertible_v; + + static constexpr int input_vec_size = ReduceConfig::input_vec_size; + + arg_t ident; + ReduceConfig config; + InputCalculator input_calc; + OutputCalculator output_calc; + const void* src; + const char* dst[2]; //it accepts at most two destinations + // acc_buf used for accumulation among sub Tensor Iterator when accumulation on + // output is not permissible + void* acc_buf; + // cta_buf used for accumulation between blocks during global reduction + void* cta_buf; + int* semaphores; + int64_t base_idx; + bool accumulate; + bool final_output; + int noutputs; + + + C10_DEVICE void run() const { + extern __shared__ char shared_memory[]; + uint32_t output_idx = config.output_idx<${output_vec_size}>(); + uint32_t input_idx = config.input_idx(); + auto base_offsets1 = output_calc.get(output_idx)[1]; + + using arg_vec_t = Array; + arg_vec_t value; + + if (output_idx < config.num_outputs && input_idx < config.num_inputs) { + const scalar_t* input_slice = (const scalar_t*)((const char*)src + base_offsets1); + + value = thread_reduce<${output_vec_size}>(input_slice); + } + + if (config.should_block_y_reduce()) { + value = block_y_reduce<${output_vec_size}>(value, shared_memory); + } + if (config.should_block_x_reduce()) { + value = block_x_reduce<${output_vec_size}>(value, shared_memory); + } + + using out_ptr_vec_t = Array; + using offset_vec_t = Array; + offset_vec_t base_offsets; + out_ptr_vec_t out; + + #pragma unroll + for (int i = 0; i < ${output_vec_size}; i++) { + base_offsets[i] = output_calc.get(output_idx + i)[0]; + out[i] = (out_scalar_t*)((char*)dst[0] + base_offsets[i]); + } + + arg_vec_t* acc = nullptr; + if (acc_buf != nullptr) { + size_t numerator = sizeof(arg_t); + size_t denominator = sizeof(out_scalar_t); + reduce_fraction(numerator, denominator); + acc = (arg_vec_t*)((char*)acc_buf + (base_offsets[0] * numerator / denominator)); + } + + if (config.should_global_reduce()) { + value = global_reduce<${output_vec_size}>(value, acc, shared_memory); + } else if (config.should_store(output_idx)) { + if (accumulate) { + #pragma unroll + for (int i = 0; i < ${output_vec_size}; i++) { + value[i] = reducer::translate_idx(value[i], base_idx); + } + } + + if (acc == nullptr) { + if (accumulate) { + value = accumulate_in_output<${output_vec_size}>(out, value); + } + if (final_output) { + set_results_to_output<${output_vec_size}>(value, base_offsets); + } else { + #pragma unroll + for (int i = 0; i < ${output_vec_size}; i++) { + *(out[i]) = get_accumulated_output(out[i], value[i]); + } + } + } else { + if (accumulate) { + #pragma unroll + for (int i = 0; i < ${output_vec_size}; i++) { + value[i] = reducer::combine((*acc)[i], value[i]); + } + } + if (final_output) { + set_results_to_output<${output_vec_size}>(value, base_offsets); + } else { + *acc = value; + } + } + } + } + + template + C10_DEVICE Array thread_reduce(const scalar_t* data) const { + if (config.vectorize_input) { + assert(output_vec_size == 1); + // reduce at the header of input_slice where memory is not aligned, + // so that thread_reduce will have an aligned memory to work on. + return {input_vectorized_thread_reduce_impl(data)}; + } else { + uint32_t element_stride = input_calc.strides_[0][0] / sizeof(scalar_t); + bool is_contiguous = (input_calc.dims == 1 && element_stride == 1); + if (is_contiguous) { + return thread_reduce_impl(data, [](uint32_t idx) { return idx; }); + } else if (input_calc.dims == 1) { + return thread_reduce_impl(data, [&](uint32_t idx) { return idx * element_stride; }); + } else { + return thread_reduce_impl(data, [&](uint32_t idx) { return input_calc.get(idx)[0] / sizeof(scalar_t); }); + } + } + } + + C10_DEVICE arg_t input_vectorized_thread_reduce_impl(const scalar_t* data) const { + uint32_t end = config.num_inputs; + + // Handle the head of input slice where data is not aligned + arg_t value = ident; + constexpr int align_bytes = alignof(aligned_vector); + constexpr int align_elements = align_bytes / sizeof(scalar_t); + int shift = ((int64_t)data) % align_bytes / sizeof(scalar_t); + if (shift > 0) { + data -= shift; + end += shift; + if(threadIdx.x >= shift && threadIdx.x < align_elements && config.should_reduce_tail()){ + value = reducer::reduce(value, data[threadIdx.x], threadIdx.x - shift); + } + end -= align_elements; + data += align_elements; + shift = align_elements - shift; + } + + // Do the vectorized reduction + using load_t = aligned_vector; + + uint32_t idx = config.input_idx(); + const uint32_t stride = config.step_input; + + // Multiple accumulators to remove dependency between unrolled loops. + arg_t value_list[input_vec_size]; + value_list[0] = value; + + #pragma unroll + for (int i = 1; i < input_vec_size; i++) { + value_list[i] = ident; + } + + scalar_t values[input_vec_size]; + + load_t *values_vector = reinterpret_cast(&values[0]); + + while (idx * input_vec_size + input_vec_size - 1 < end) { + *values_vector = reinterpret_cast(data)[idx]; + #pragma unroll + for (uint32_t i = 0; i < input_vec_size; i++) { + value_list[i] = reducer::reduce(value_list[i], values[i], shift + idx * input_vec_size + i); + } + idx += stride; + } + + // tail + uint32_t tail_start = end - end % input_vec_size; + if (config.should_reduce_tail()) { + int idx = tail_start + threadIdx.x; + if (idx < end) { + value_list[0] = reducer::reduce(value_list[0], data[idx], idx + shift); + } + } + + // combine accumulators + #pragma unroll + for (int i = 1; i < input_vec_size; i++) { + value_list[0] = reducer::combine(value_list[0], value_list[i]); + } + return value_list[0]; + } + + template + C10_DEVICE Array thread_reduce_impl(const scalar_t* data_, offset_calc_t calc) const { + uint32_t idx = config.input_idx(); + const uint32_t end = config.num_inputs; + const uint32_t stride = config.step_input; + const int vt0=${vt0}; + + using arg_vec_t = Array; + using load_t = aligned_vector; + const load_t* data = reinterpret_cast(data_); + + // Multiple accumulators to remove dependency between unrolled loops. + arg_vec_t value_list[vt0]; + + #pragma unroll + for (int i = 0; i < vt0; i++) { + #pragma unroll + for (int j = 0; j < output_vec_size; j++) { + value_list[i][j] = ident; + } + } + + load_t values[vt0]; + + while (idx + (vt0 - 1) * stride < end) { + #pragma unroll + for (uint32_t i = 0; i < vt0; i++) { + values[i] = data[calc(idx + i * stride) / output_vec_size]; + } + #pragma unroll + for (uint32_t i = 0; i < vt0; i++) { + #pragma unroll + for (uint32_t j = 0; j < output_vec_size; j++) { + value_list[i][j] = reducer::reduce(value_list[i][j], values[i].val[j], idx + i * stride); + } + } + idx += stride * vt0; + } + + // tail + int idx_ = idx; + #pragma unroll + for (uint32_t i = 0; i < vt0; i++) { + if (idx >= end) { + break; + } + values[i] = data[calc(idx) / output_vec_size]; + idx += stride; + } + idx = idx_; + #pragma unroll + for (uint32_t i = 0; i < vt0; i++) { + if (idx >= end) { + break; + } + #pragma unroll + for (uint32_t j = 0; j < output_vec_size; j++) { + value_list[i][j] = reducer::reduce(value_list[i][j], values[i].val[j], idx); + } + idx += stride; + } + + // combine accumulators + #pragma unroll + for (int i = 1; i < vt0; i++) { + #pragma unroll + for (uint32_t j = 0; j < output_vec_size; j++) { + value_list[0][j] = reducer::combine(value_list[0][j], value_list[i][j]); + } + } + return value_list[0]; + } + template + C10_DEVICE Array block_x_reduce(Array value, char* shared_memory) const { + using args_vec_t = Array; + int dim_x = blockDim.x; + args_vec_t* shared = (args_vec_t*)shared_memory; + if (dim_x > warpSize) { + int address_base = threadIdx.x + threadIdx.y*blockDim.x; + shared[address_base] = value; + for (int offset = dim_x/2; offset >= warpSize; offset >>= 1) { + __syncthreads(); + if (threadIdx.x < offset && threadIdx.x + offset < blockDim.x) { + args_vec_t other = shared[address_base + offset]; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = reducer::combine(value[i], other[i]); + } + shared[address_base] = value; + } + } + dim_x = warpSize; + } + + __syncthreads(); + + for (int offset = 1; offset < dim_x; offset <<= 1) { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + arg_t other = reducer::warp_shfl_down(value[i], offset); + value[i] = reducer::combine(value[i], other); + } + } + return value; + } + + template + C10_DEVICE Array block_y_reduce(Array value, char* shared_memory) const { + using args_vec_t = Array; + args_vec_t* shared = (args_vec_t*)shared_memory; + shared[config.shared_memory_offset(0)] = value; + for (int offset = blockDim.y / 2; offset > 0; offset >>= 1) { + __syncthreads(); + if (threadIdx.y < offset && threadIdx.y + offset < blockDim.y) { + args_vec_t other = shared[config.shared_memory_offset(offset)]; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = reducer::combine(value[i], other[i]); + } + shared[config.shared_memory_offset(0)] = value; + } + } + return value; + } + )ESCAPE"; + + const std::string reduction_template_1 = R"ESCAPE( + + C10_DEVICE bool mark_block_finished() const { + __shared__ bool is_last_block_done_shared; + + __syncthreads(); + if (threadIdx.x == 0 && threadIdx.y == 0) { + int prev_blocks_finished = atomicAdd(&semaphores[blockIdx.x], 1); + is_last_block_done_shared = (prev_blocks_finished == gridDim.y - 1); + } + + __syncthreads(); + + return is_last_block_done_shared; + } + + template + C10_DEVICE Array accumulate_in_output( + Array out, + Array value + ) const { + Array ret; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + ret[i] = reducer::combine(*(out[i]), value[i]); + } + return ret; + } + + + C10_DEVICE out_scalar_t get_accumulated_output( + out_scalar_t* out, arg_t value + ) const { + assert(!final_output); + return (out_scalar_t)value; + } + + template + C10_DEVICE void set_results(const T x, const uint32_t base_offset) const { + assert(noutputs == 1); + auto res = (out_scalar_t*)((char*)dst[0] + base_offset); + *res = x; + } + +//TODO - multi-output reduction - we won't be able to use thrust::pair +//just explicitly specify typed output reads/writes +//Currently implemented for max of two outputs +// template +// C10_DEVICE void set_results(const thrust::pair x, const index_t base_offset) const { +// if (noutputs >= 1) { +// auto res0 = (T1*)((char*)dst[0] + base_offset); +// *res0 = x.first; +// } +// if (noutputs >= 2) { +// // base offset is computed assuming element size being sizeof(T1), so we need to make a +// // correction to obtain the correct base offset +// auto res1 = (T2*) ((char *) dst[1] + base_offset / sizeof(T1) * sizeof(T2)); +// *res1 = x.second; +// } +// } + + template + C10_DEVICE void set_results_to_output(Array value, Array base_offset) const { + assert(final_output); + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + set_results(reducer::project(value[i]), base_offset[i]); + } + } + + template + C10_DEVICE Array global_reduce(Array value, Array *acc, char* shared_memory) const { + using arg_vec_t = Array; + using out_ptr_vec_t = Array; + using offset_vec_t = Array; + + arg_vec_t* reduce_buffer = (arg_vec_t*)cta_buf; + uint32_t output_idx = config.output_idx(); + offset_vec_t base_offsets; + out_ptr_vec_t out; + + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + base_offsets[i] = output_calc.get(output_idx + i)[0]; + out[i] = (out_scalar_t*)((char*)dst[0] + base_offsets[i]); + } + + bool should_store = config.should_store(output_idx); + if (should_store) { + uint32_t offset = config.staging_memory_offset(blockIdx.y); + reduce_buffer[offset] = value; + } + + __threadfence(); // make sure writes are globally visible + __syncthreads(); // if multiple warps in this block wrote to staging, make sure they're all done + bool is_last_block_done = mark_block_finished(); + + if (is_last_block_done) { + __threadfence(); //complete acquire pattern + value = ident; + if (config.should_block_x_reduce()) { + uint32_t input_offset = threadIdx.x + threadIdx.y * blockDim.x; + uint32_t step = blockDim.x * blockDim.y; + for (; input_offset < config.ctas_per_output; input_offset += step) { + uint32_t idx = config.staging_memory_offset(input_offset); + arg_vec_t next = reduce_buffer[idx]; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = reducer::combine(value[i], next[i]); + } + } + } else { + uint32_t input_offset = threadIdx.y; + uint32_t step = blockDim.y; + for (; input_offset < config.ctas_per_output; input_offset += step) { + uint32_t idx = config.staging_memory_offset(input_offset); + arg_vec_t next = reduce_buffer[idx]; + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = reducer::combine(value[i], next[i]); + } + } + } + value = block_y_reduce(value, shared_memory); + if (config.should_block_x_reduce()) { + value = block_x_reduce(value, shared_memory); + } + if (should_store) { + if (accumulate) { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = reducer::translate_idx(value[i], base_idx); + } + } + + if (acc == nullptr) { + if (accumulate) { + value = accumulate_in_output(out, value); + } + if (final_output) { + set_results_to_output(value, base_offsets); + } else { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + *(out[i]) = get_accumulated_output(out[i], value[i]); + } + } + } else { + if (accumulate) { + #pragma unroll + for (int i = 0; i < output_vec_size; i++) { + value[i] = reducer::combine((*acc)[i], value[i]); + } + } + if (final_output) { + set_results_to_output(value, base_offsets); + } else { + *acc = value; + } + } + } + } + + return value; + } +}; + +extern "C" +__launch_bounds__(${max_threads_lb}, 4) +__global__ void reduction_${name}_kernel(ReduceJitOp r){ + r.run(); +} +)ESCAPE"; + +const std::string reduction_template = reduction_template_0 + reduction_template_1; + + +const std::string &get_reduction_template() { + return reduction_template; +} + +} // namespace at::cuda diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/thread_constants.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/thread_constants.h new file mode 100644 index 0000000000000000000000000000000000000000..bcc797a26e1ce53032922d5654a4b771209ceca7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/thread_constants.h @@ -0,0 +1,25 @@ +#pragma once +#include + +// Marks a lambda as executable on both the host and device. The __host__ +// attribute is important so that we can access static type information from +// the host, even if the function is typically only executed on the device. +#ifndef GPU_LAMBDA +#define GPU_LAMBDA __host__ __device__ +#endif + +#if defined(USE_ROCM) +constexpr int num_threads() { + return 256; +} + +constexpr int thread_work_size() { return 4; } +#else +constexpr uint32_t num_threads() { + return C10_WARP_SIZE * 4; +} + +constexpr int thread_work_size() { return 8; } +#endif + +constexpr int block_work_size() { return thread_work_size() * num_threads(); } diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/vol2col.cuh b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/vol2col.cuh new file mode 100644 index 0000000000000000000000000000000000000000..e69463fa42224c31abd4f2446f62bb16d81e4fb0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/cuda/vol2col.cuh @@ -0,0 +1,262 @@ +#pragma once + +#include +#include +#include +#include + +#include + +namespace at::native { + +using namespace at::cuda::detail; + +// Kernel for fast unfold+copy on volumes +template +C10_LAUNCH_BOUNDS_1(1024) +__global__ void vol2col_kernel( + const int64_t n, + const T* data_vol, + const int depth, + const int height, + const int width, + const int ksize_t, + const int ksize_h, + const int ksize_w, + const int pad_t, + const int pad_h, + const int pad_w, + const int stride_t, + const int stride_h, + const int stride_w, + const int dilation_t, + const int dilation_h, + const int dilation_w, + const int depth_col, + const int height_col, + const int width_col, + T* data_col) { + CUDA_KERNEL_LOOP_TYPE(index, n, int64_t) { + auto w_out = index % width_col; + index /= width_col; + auto h_out = index % height_col; + index /= height_col; + auto t_out = index % depth_col; + auto channel_in = index / depth_col; + auto channel_out = channel_in * ksize_t * ksize_h * ksize_w; + auto t_in = t_out * stride_t - pad_t; + auto h_in = h_out * stride_h - pad_h; + auto w_in = w_out * stride_w - pad_w; + data_col += + ((channel_out * depth_col + t_out) * height_col + h_out) * width_col + + w_out; + data_vol += ((channel_in * depth + t_in) * height + h_in) * width + w_in; + for (int i = 0; i < ksize_t; ++i) { + for (int j = 0; j < ksize_h; ++j) { + for (int k = 0; k < ksize_w; ++k) { + auto t = t_in + i * dilation_t; + auto h = h_in + j * dilation_h; + auto w = w_in + k * dilation_w; + *data_col = (t >= 0 && h >= 0 && w >= 0 && t < depth && h < height && + w < width) + ? data_vol + [i * dilation_t * height * width + j * dilation_h * width + + k * dilation_w] + : static_cast(0); + data_col += depth_col * height_col * width_col; + } + } + } + } +} + +template +void vol2col( + cudaStream_t stream, + const T* data_vol, + const int channels, + const int depth, + const int height, + const int width, + const int depth_col, + const int height_col, + const int width_col, + const int ksize_t, + const int ksize_h, + const int ksize_w, + const int pad_t, + const int pad_h, + const int pad_w, + const int stride_t, + const int stride_h, + const int stride_w, + const int dilation_t, + const int dilation_h, + const int dilation_w, + T* data_col) { + // We are going to launch channels * depth_col * height_col * width_col + // kernels, each kernel responsible for copying a single-channel grid. + // We cast an operand to int64 so that the product will not overflow + const auto num_kernels = static_cast(channels) * depth_col * height_col * width_col; + // Launch + vol2col_kernel<<>>( + num_kernels, + data_vol, + depth, + height, + width, + ksize_t, + ksize_h, + ksize_w, + pad_t, + pad_h, + pad_w, + stride_t, + stride_h, + stride_w, + dilation_t, + dilation_h, + dilation_w, + depth_col, + height_col, + width_col, + data_col); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +template +__global__ void vol2im_kernel( + const int64_t n, + const T* data_col, + const unsigned depth, + const unsigned height, + const unsigned width, + const unsigned channels, + const unsigned kernel_t, + const unsigned kernel_h, + const unsigned kernel_w, + const unsigned pad_t, + const unsigned pad_h, + const unsigned pad_w, + const unsigned stride_t, + const unsigned stride_h, + const unsigned stride_w, + const unsigned dilation_t, + const unsigned dilation_h, + const unsigned dilation_w, + const unsigned depth_col, + const unsigned height_col, + const unsigned width_col, + T* data_vol) { + CUDA_KERNEL_LOOP(index, n) { + accT val = static_cast(0); + const auto w_im = index % width + pad_w; + const auto h_im = (index / width) % height + pad_h; + const auto t_im = (index / width / height) % depth + pad_t; + const auto c_im = index / (width * height * depth); + auto kernel_extent_w = (kernel_w - 1) * dilation_w + 1; + auto kernel_extent_h = (kernel_h - 1) * dilation_h + 1; + auto kernel_extent_t = (kernel_t - 1) * dilation_t + 1; + // compute the start and end of the output + const auto w_col_start = + (w_im < kernel_extent_w) ? 0 : (w_im - kernel_extent_w) / stride_w + 1; + const auto w_col_end = std::min(w_im / stride_w + 1, width_col); + const auto h_col_start = + (h_im < kernel_extent_h) ? 0 : (h_im - kernel_extent_h) / stride_h + 1; + const auto h_col_end = std::min(h_im / stride_h + 1, height_col); + const auto t_col_start = + (t_im < kernel_extent_t) ? 0 : (t_im - kernel_extent_t) / stride_t + 1; + const auto t_col_end = std::min(t_im / stride_t + 1, depth_col); + // TODO: use LCM of stride and dilation to avoid unnecessary loops + for (unsigned t_col = t_col_start; t_col < t_col_end; t_col += 1) { + for (unsigned h_col = h_col_start; h_col < h_col_end; h_col += 1) { + for (unsigned w_col = w_col_start; w_col < w_col_end; w_col += 1) { + uint64_t t_k = (t_im - t_col * stride_t); + uint64_t h_k = (h_im - h_col * stride_h); + uint64_t w_k = (w_im - w_col * stride_w); + if (t_k % dilation_t == 0 && h_k % dilation_h == 0 && + w_k % dilation_w == 0) { + t_k /= dilation_t; + h_k /= dilation_h; + w_k /= dilation_w; + const int64_t idx_k = + ((c_im * kernel_t + t_k) * kernel_h + h_k) * kernel_w + w_k; + const int64_t data_col_index = + ((idx_k * depth_col + t_col) * + height_col + h_col) * + width_col + w_col; + val += data_col[data_col_index]; + } + } + } + } + data_vol[index] = static_cast(val); + } +} + +template +void col2vol( + cudaStream_t stream, + const T* data_col, + const int64_t channels, + const int64_t depth, + const int64_t height, + const int64_t width, + const int64_t output_depth, + const int64_t output_height, + const int64_t output_width, + const int64_t patch_t, + const int64_t patch_h, + const int64_t patch_w, + const int64_t pad_t, + const int64_t pad_h, + const int64_t pad_w, + const int64_t stride_t, + const int64_t stride_h, + const int64_t stride_w, + const int64_t dilation_t, + const int64_t dilation_h, + const int64_t dilation_w, + T* data_vol) { + const auto num_kernels = channels * depth * height * width; + + auto check_fits_in_unsigned = + [](int64_t val, const char * name) { + constexpr auto umax = std::numeric_limits::max(); + TORCH_CHECK(val >= 0 && val <= umax, + name, " must fit in a 32-bit unsigned value"); + }; + check_fits_in_unsigned(num_kernels, "input size"); + check_fits_in_unsigned( + channels * patch_t * patch_h * patch_w, "channels x kernel size"); + + // To avoid involving atomic operations, we will launch one kernel per + // bottom dimension, and then in the kernel add up the top dimensions. + vol2im_kernel + <<>>( + num_kernels, + data_col, + depth, + height, + width, + channels, + patch_t, + patch_h, + patch_w, + pad_t, + pad_h, + pad_w, + stride_t, + stride_h, + stride_w, + dilation_t, + dilation_h, + dilation_w, + output_depth, + output_height, + output_width, + data_vol); + C10_CUDA_KERNEL_LAUNCH_CHECK(); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/group_norm.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/group_norm.h new file mode 100644 index 0000000000000000000000000000000000000000..05b041416ebad639cdc7f3c0e421260a388cf749 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/group_norm.h @@ -0,0 +1,42 @@ +#pragma once + +#include +#include + +namespace at { +class Tensor; + +namespace native { + +using forward_fn = void (*)( + const Tensor& /* X */, + const Tensor& /* gamma */, + const Tensor& /* beta */, + int64_t /* N */, + int64_t /* C */, + int64_t /* HxW */, + int64_t /* group */, + double /* eps */, + Tensor& /* Y */, + Tensor& /* mean */, + Tensor& /* rstd */); + +using backward_fn = void (*)( + const Tensor& /* dY */, + const Tensor& /* X */, + const Tensor& /* mean */, + const Tensor& /* rstd */, + const Tensor& /* gamma */, + int64_t /* N */, + int64_t /* C */, + int64_t /* HxW */, + int64_t /* group */, + Tensor& /* dX */, + Tensor& /* dgamma */, + Tensor& /* dbeta */); + +DECLARE_DISPATCH(forward_fn, GroupNormKernel) +DECLARE_DISPATCH(backward_fn, GroupNormBackwardKernel) + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_bgemm.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_bgemm.h new file mode 100644 index 0000000000000000000000000000000000000000..fb1458043f676129234170c9d51c8ce987c98d71 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_bgemm.h @@ -0,0 +1,16 @@ +#pragma once + +#include +#include + +namespace at::native { + +template +inline void bgemm_internal_ck(CUDABLAS_BGEMM_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas_bgemm_internal_ck: not implemented"); +} + +template <> +void bgemm_internal_ck(CUDABLAS_BGEMM_ARGTYPES(at::BFloat16)); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_gemm.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_gemm.h new file mode 100644 index 0000000000000000000000000000000000000000..176cbabd5e01c40189b2d6115136d27a7e5865b6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_gemm.h @@ -0,0 +1,24 @@ +#pragma once + +#include +#include +namespace at::native { + + +template +inline void gemm_internal_ck(CUDABLAS_GEMM_ARGTYPES(Dtype)) { + static_assert(false&&sizeof(Dtype),"at::cuda::blas_gemm_internal_ck: not implemented"); +} + +template <> +void gemm_internal_ck(CUDABLAS_GEMM_ARGTYPES(double)); +template <> +void gemm_internal_ck(CUDABLAS_GEMM_ARGTYPES(float)); +template <> +void gemm_internal_ck(CUDABLAS_GEMM_ARGTYPES(at::Half)); +template <> +void gemm_internal_ck(CUDABLAS_GEMM_ARGTYPES(at::BFloat16)); + + + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_gemm_template.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_gemm_template.h new file mode 100644 index 0000000000000000000000000000000000000000..41308f30dcd3eb188c4c0debb88cb1f0fe8cd267 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_gemm_template.h @@ -0,0 +1,239 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ +#undef __HIP_NO_HALF_CONVERSIONS__ +#include +#include +#include + +#include +#include +#include +#include + +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include + +#include + +// Define commonly used types. +template +using S = ck::Sequence; + +using Row = ck::tensor_layout::gemm::RowMajor; +using Col = ck::tensor_layout::gemm::ColumnMajor; +using PassThrough = ck::tensor_operation::element_wise::PassThrough; + +namespace at::native { + +// Elementwise Operators +struct AlphaBetaAdd +{ + AlphaBetaAdd(float alpha, float beta) : alpha_(alpha), beta_(beta){}; + + template + __host__ __device__ constexpr void operator()(C& c, const AB& ab) const; + + template<> + __host__ __device__ constexpr void operator() + (float& c, const float& ab) const + { + c = alpha_ * ab; + }; + + template<> + __host__ __device__ constexpr void operator() + (ck::bhalf_t& c, const ck::bhalf_t& ab) const + { + c = alpha_ * ab; + }; + + template<> + __host__ __device__ constexpr void operator() + (ck::half_t& c, const ck::half_t& ab) const + { + c = alpha_ * ab; + }; + + float alpha_; + // TODO: Leaving for now, will use later + float beta_; +}; + +template < + typename Dtype, + int BLOCK_SIZE, + int MBLOCK, + int NBLOCK, + int KBLOCK, + int AK1, + int BK1, + int MPER_XDL, + int NPER_XDL, + int MPER_WAVE, + int NPER_WAVE, + typename ABLOCK_CLUSTER_LENS, + typename ABLOCK_CLUSTER_ORDER, + typename ABLOCK_SRC_ORDER, + int ABLOCK_VECTOR_DIM, + int ABLOCK_SCALAR_VEC, + int ABLOCK_SCALAR_VEC_AK1, + bool ABLOCK_LDS_EXTRAM, + typename BBLOCK_CLUSTER_LENS, + typename BBLOCK_CLUSTER_ORDER, + typename BBLOCK_SRC_ORDER, + int BBLOCK_VECTOR_DIM, + int BBLOCK_SCALAR_VEC, + int BBLOCK_SCALAR_VEC_AK1, + bool BBLOCK_LDS_EXTRAN, + int CMPER_WAVE, + int CNPER_WAVE, + typename BLOCK_CLUSTER_LENS, + typename CDE_SCALAR_VEC, + bool PADDING = false, + bool TRANSA = false, + bool TRANSB = false> +void gemm_impl(CUDABLAS_GEMM_ARGTYPES(Dtype)) { + // Get input information. + int M = m; + int N = n; + int K = k; + + int StrideA = lda; + int StrideB = ldb; + int StrideC = ldc; + + int KBatch = 1; + + float falpha = alpha; + float fbeta = beta; + + using ADataType = typename CkMathType::dtype; + using BDataType = typename CkMathType::dtype; + using CDataType = typename CkMathType::dtype; + using DDataType = typename CkMathType::dtype; + + using AccDataType = float; + using CShuffleDataType = typename CkMathType::dtype; + + using ALayout = typename CkTensorLayout::a_layout; + using BLayout = typename CkTensorLayout::b_layout; + + using DLayout = Row; + using CLayout = Row; + + using AElementOp = PassThrough; + using BElementOp = PassThrough; + using CElementOp = AlphaBetaAdd; + + + static constexpr auto GemmDefault = + ck::tensor_operation::device::GemmSpecialization::Default; + static constexpr auto GemmMNKPadding = + ck::tensor_operation::device::GemmSpecialization::MNKPadding; + static constexpr auto GemmSpec = PADDING ? GemmMNKPadding : GemmDefault; + + + using DeviceGemmInstance = + ck::tensor_operation::device::DeviceGemmMultiD_Xdl_CShuffle_V3, + CLayout, + ADataType, + BDataType, + ck::Tuple<>, + CDataType, + AccDataType, + CShuffleDataType, + AElementOp, + BElementOp, + CElementOp, + GemmSpec, + BLOCK_SIZE, + MBLOCK, + NBLOCK, + KBLOCK, + AK1, + BK1, + MPER_XDL, + NPER_XDL, + MPER_WAVE, + NPER_WAVE, + ABLOCK_CLUSTER_LENS, + ABLOCK_CLUSTER_ORDER, + ABLOCK_SRC_ORDER, + ABLOCK_VECTOR_DIM, + ABLOCK_SCALAR_VEC, + ABLOCK_SCALAR_VEC_AK1, + ABLOCK_LDS_EXTRAM, + BBLOCK_CLUSTER_LENS, + BBLOCK_CLUSTER_ORDER, + BBLOCK_SRC_ORDER, + BBLOCK_VECTOR_DIM, + BBLOCK_SCALAR_VEC, + BBLOCK_SCALAR_VEC_AK1, + BBLOCK_LDS_EXTRAN, + CMPER_WAVE, + CNPER_WAVE, + BLOCK_CLUSTER_LENS, + CDE_SCALAR_VEC>; + + + auto gemm = DeviceGemmInstance{}; + auto invoker = gemm.MakeInvoker(); + + auto a_element_op = AElementOp{}; + auto b_element_op = BElementOp{}; + auto c_element_op = CElementOp{alpha, beta}; + + + using DDataArrayType = std::array; + DDataArrayType DDataArray; + + // We swap A and B inputs here as a temporary workaround + auto argument = gemm.MakeArgument( + reinterpret_cast(b), + reinterpret_cast(a), + DDataArray, + reinterpret_cast(c), + N, + M, + K, + StrideB, + StrideA, + std::array{}, + StrideC, + KBatch, + a_element_op, + b_element_op, + c_element_op); + + + if(!gemm.IsSupportedArgument(argument)) + { + throw std::runtime_error( + "wrong! device_gemm with the specified compilation parameters does " + "not support this GEMM problem"); + } + + + auto stream = at::cuda::getCurrentHIPStream().stream(); + invoker.Run(argument, StreamConfig{stream, false}); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_types.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_types.h new file mode 100644 index 0000000000000000000000000000000000000000..5840924a1bf86bd6fc2468bce84741d7a21b351e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/hip/ck_types.h @@ -0,0 +1,75 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +// work around CK assuming only a single FP8 interpretation at a time +#if(defined(__gfx940__) || defined(__gfx941__) || defined(__gfx942__)) && __HIP_DEVICE_COMPILE__ +#define CK_USE_FNUZ_FP8 1 +#undef CK_USE_OCP_FP8 +#elif __HIP_DEVICE_COMPILE__ +#undef CK_USE_FNUZ_FP8 +#define CK_USE_OCP_FP8 1 +#endif + +#include +#include +#include +#include + +using Row = ck::tensor_layout::gemm::RowMajor; +using Col = ck::tensor_layout::gemm::ColumnMajor; + +namespace at::native { + +template +struct CkMathType { + using dtype = T; +}; + +template <> +struct CkMathType { + using dtype = ck::bhalf_t; +}; + +template <> +struct CkMathType { + using dtype = ck::half_t; +}; + +template +struct CkTensorLayout { + // default goes to row-wise for now + using a_layout = Row; + using b_layout = Row; +}; + +// True denotes transpose is necessary. Default is Col, so return Row +template <> +struct CkTensorLayout { + using a_layout = Col; + using b_layout = Col; +}; + +template <> +struct CkTensorLayout { + using a_layout = Row; + using b_layout = Col; +}; + +template <> +struct CkTensorLayout { + using a_layout = Col; + using b_layout = Row; +}; + +template <> +struct CkTensorLayout { + using a_layout = Row; + using b_layout = Row; +}; + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/im2col.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/im2col.h new file mode 100644 index 0000000000000000000000000000000000000000..879de4bb5554e452ee549a7a485ecd342a3f43db --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/im2col.h @@ -0,0 +1,149 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + +#include + +namespace at::native { + +template +static void im2col( + const T* data_im, + const int64_t channels, + const int64_t height, + const int64_t width, + const int64_t output_height, + const int64_t output_width, + const int64_t kernel_h, + const int64_t kernel_w, + const int64_t pad_h, + const int64_t pad_w, + const int64_t stride_h, + const int64_t stride_w, + const int64_t dilation_h, + const int64_t dilation_w, + T* data_col, + bool is_channels_last = false) { + const int64_t height_col = output_height; + const int64_t width_col = output_width; + const int64_t channels_col = channels * kernel_h * kernel_w; + + if (is_channels_last) { + at::parallel_for(0, height_col * width_col, 0, [&](int64_t begin, int64_t end) { + int64_t h_col{0}, w_col{0}; + data_index_init(begin, h_col, height_col, w_col, width_col); + + for (const auto i_col : c10::irange(begin, end)) { + for (const auto h_offset : c10::irange(kernel_h)) { + int64_t h_im = h_col * stride_h - pad_h + h_offset * dilation_h; + for (const auto w_offset : c10::irange(kernel_w)) { + int64_t w_im = w_col * stride_w - pad_w + w_offset * dilation_w; + + const T* slice_im = data_im + (h_im * width + w_im) * channels; + T* slice_col = data_col + (i_col * kernel_h * kernel_w + h_offset * kernel_w + w_offset) * channels; + + if (h_im >= 0 && w_im >= 0 && h_im < height && w_im < width) { + std::copy_n(slice_im, channels, slice_col); + } else { + std::fill_n(slice_col, channels, T(0)); + } + } + } + + // move the next index + data_index_step(h_col, height_col, w_col, width_col); + } + }); + } else { + at::parallel_for(0, channels_col, 0, [&](int64_t begin, int64_t end) { + int64_t c_im{0}, h_offset{0}, w_offset{0}; + data_index_init(begin, c_im, channels, h_offset, kernel_h, w_offset, kernel_w); + + for (const auto c_col : c10::irange(begin, end)) { + for (const auto h_col : c10::irange(height_col)) { + int64_t h_im = h_col * stride_h - pad_h + h_offset * dilation_h; + for (const auto w_col : c10::irange(width_col)) { + int64_t w_im = w_col * stride_w - pad_w + w_offset * dilation_w; + data_col[(c_col * height_col + h_col) * width_col + w_col] = + (h_im >= 0 && w_im >= 0 && h_im < height && w_im < width) + ? c10::load(&(data_im[(c_im * height + h_im) * width + w_im])) + : static_cast(0); + } + } + + // move to the next index + data_index_step(c_im, channels, h_offset, kernel_h, w_offset, kernel_w); + } + }); + } +} + +template +static void col2im( + const T* data_col, + const int64_t channels, + const int64_t height, + const int64_t width, + const int64_t output_height, + const int64_t output_width, + const int64_t kernel_h, + const int64_t kernel_w, + const int64_t pad_h, + const int64_t pad_w, + const int64_t stride_h, + const int64_t stride_w, + const int64_t dilation_h, + const int64_t dilation_w, + T* data_im, + bool is_channels_last = false) { + std::fill_n(data_im, height * width * channels, T(0)); + + const int64_t height_col = output_height; + const int64_t width_col = output_width; + const int64_t channels_col = channels * kernel_h * kernel_w; + + if (is_channels_last) { + for (const auto h_col : c10::irange(height_col)) { + for (const auto w_col : c10::irange(width_col)) { + for (const auto h_offset : c10::irange(kernel_h)) { + int64_t h_im = h_col * stride_h - pad_h + h_offset * dilation_h; + for (const auto w_offset : c10::irange(kernel_w)) { + int64_t w_im = w_col * stride_w - pad_w + w_offset * dilation_w; + + T* slice_im = data_im + (h_im * width + w_im) * channels; + const T* slice_col = data_col + ((h_col * width_col + w_col) * kernel_h * kernel_w + + h_offset * kernel_w + w_offset) * channels; + + if (h_im >= 0 && h_im < height && w_im >= 0 && w_im < width) { + std::transform(slice_col, slice_col + channels, slice_im, slice_im, std::plus()); + } + } + } + } + } + } else { + for (const auto c_col : c10::irange(channels_col)) { + int64_t w_offset = c_col % kernel_w; + int64_t h_offset = (c_col / kernel_w) % kernel_h; + int64_t c_im = c_col / kernel_h / kernel_w; + + for (const auto h_col : c10::irange(height_col)) { + int64_t h_im = h_col * stride_h - pad_h + h_offset * dilation_h; + for (const auto w_col : c10::irange(width_col)) { + int64_t w_im = w_col * stride_w - pad_w + w_offset * dilation_w; + + if (h_im >= 0 && h_im < height && w_im >= 0 && w_im < width) + data_im[(c_im * height + h_im) * width + w_im] += + data_col[(c_col * height_col + h_col) * width_col + w_col]; + } + } + } + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/im2col_shape_check.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/im2col_shape_check.h new file mode 100644 index 0000000000000000000000000000000000000000..6c830c5c929cb18f18086a0a71a878e1221a0186 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/im2col_shape_check.h @@ -0,0 +1,232 @@ +#pragma once +#include +#include +#include + +namespace at::native { + +inline void col2im_shape_check( + const Tensor& input, + const Tensor& grad_output, + int64_t output_height, + int64_t output_width, + int64_t kernel_height, + int64_t kernel_width, + int64_t dilation_height, + int64_t dilation_width, + int64_t pad_height, + int64_t pad_width, + int64_t stride_height, + int64_t stride_width) { + TORCH_CHECK( + kernel_width > 0 && kernel_height > 0, + "kernel size should be greater than zero, but got kernel_height: ", + kernel_height, + " kernel_width: ", + kernel_width); + TORCH_CHECK( + stride_width > 0 && stride_height > 0, + "stride should be greater than zero, but got stride_height: ", + stride_height, + " stride_width: ", + stride_width); + TORCH_CHECK( + dilation_width > 0 && dilation_height > 0, + "dilation should be greater than zero, but got dilation_height: ", + dilation_height, + " dilation_width: ", + dilation_width); + TORCH_CHECK( + pad_width >= 0 && pad_height >= 0, + "padding should be non-negative, but got pad_height: ", + pad_height, + " pad_width: ", + pad_width); + + + int64_t ndim = input.ndimension(); + // allow dim=0 only the batch dimension. + TORCH_CHECK( + (ndim == 2 && input.size(0) != 0 && input.size(1) != 0) || + (ndim == 3 && input.size(1) != 0 && input.size(2) != 0), + "Expected 2D or 3D (batch mode) tensor for input with possibly 0 batch size and non-zero dimensions for input, but got: ", + input.sizes()); + + int64_t batch_dim = (ndim == 3) ? 0 : -1; + int64_t n_input_plane = input.size(batch_dim + 1); + + if (n_input_plane % (kernel_width * kernel_height) != 0) { + TORCH_CHECK(false, + "Expected size of input's dimension 1 to be divisible by the " + "product of kernel_size, but got input.size(1)=", + n_input_plane, + " and kernel_size=(", + kernel_height, + ", ", + kernel_width, + ")."); + } + + int64_t input_length = input.size(batch_dim + 2); + int64_t n_blocks_height = + div_rtn( + output_height + 2 * pad_height - + dilation_height * (kernel_height - 1) - 1, + stride_height) + + 1; + int64_t n_blocks_width = div_rtn( + output_width + 2 * pad_width - + dilation_width * (kernel_width - 1) - 1, + stride_width) + + 1; + + if (input_length != (n_blocks_height * n_blocks_width)) { + TORCH_CHECK(false, + "Given output_size=(", + output_height, + ", ", + output_width, + "), kernel_size=(", + kernel_height, + ", ", + kernel_width, + "), dilation=(", + dilation_height, + ", ", + dilation_width, + "), padding=(", + pad_height, + ", ", + pad_width, + "), stride=(", + stride_height, + ", ", + stride_width, + "), expected size of input's dimension 2 to match the calculated number of ", + "sliding blocks ", + n_blocks_height, + " * ", + n_blocks_width, + " = ", + (n_blocks_height * n_blocks_width), + ", but got input.size(2)=", + input_length, + "."); + } + + TORCH_CHECK( + n_blocks_height >= 1 && n_blocks_width >= 1, + "Given output_size=(", output_height, ", ", output_width, "), ", + "kernel_size=(", kernel_height, ", ", kernel_width, "), ", + "dilation=(", dilation_height, ", ", dilation_width, "), ", + "padding=(", pad_height, ", ", pad_width, "), ", + "stride=(", stride_height, ", ", stride_width, "), ", + "calculated shape of the array of sliding blocks as ", + "(", n_blocks_height, ", ", n_blocks_width, "), ", + "which is too small (non-positive)"); + + if (output_width < 1 || output_height < 1) { + TORCH_CHECK(false, + "Expected output spatial size to be positive, but got: output_size=(", + output_height, + ", ", + output_width, + ")."); + } +} + +inline void im2col_shape_check( + const Tensor& input, + const Tensor& grad_output, + int64_t kernel_height, + int64_t kernel_width, + int64_t dilation_height, + int64_t dilation_width, + int64_t pad_height, + int64_t pad_width, + int64_t stride_height, + int64_t stride_width) { + TORCH_CHECK( + kernel_width > 0 && kernel_height > 0, + "kernel size should be greater than zero, but got kernel_height: ", + kernel_height, + " kernel_width: ", + kernel_width); + + TORCH_CHECK( + dilation_width > 0 && dilation_height > 0, + "dilation should be greater than zero, but got dilation_height: ", + dilation_height, + " dilation_width: ", + dilation_width); + + TORCH_CHECK( + pad_width >= 0 && pad_height >= 0, + "padding should be non-negative, but got pad_height: ", + pad_height, + " pad_width: ", + pad_width); + + TORCH_CHECK( + stride_width > 0 && stride_height > 0, + "stride should be greater than zero, but got stride_height: ", + stride_height, + " stride_width: ", + stride_width); + + int64_t ndim = input.ndimension(); + + // allow dim=0 only the batch dimension. + bool valid_dims = input.size(1) != 0 && input.size(2) != 0; + TORCH_CHECK( + (ndim == 3 && input.size(0) && valid_dims) || + (ndim == 4 && valid_dims && input.size(3) != 0), + "Expected 3D or 4D (batch mode) tensor with possibly 0 batch size and other non-zero dimensions for input, but got: ", + input.sizes()); + + int64_t dim_batch = 0; + + if (ndim == 3) { + dim_batch = -1; + } + + int64_t input_height = input.size(dim_batch + 2); + int64_t input_width = input.size(dim_batch + 3); + int64_t output_height = div_rtn( + input_height + 2 * pad_height - + (dilation_height * (kernel_height - 1) + 1), + stride_height) + + 1; + int64_t output_width = div_rtn( + input_width + 2 * pad_width - + (dilation_width * (kernel_width - 1) + 1), + stride_width) + + 1; + + if (output_height < 1 || output_width < 1) { + TORCH_CHECK(false, + "Given input with spatial size (", + input_height, + ", ", + input_height, + "), kernel_size=(", + kernel_height, + ", ", + kernel_width, + "), dilation=(", + dilation_height, + ", ", + dilation_width, + "), padding=(", + pad_height, + ", ", + pad_width, + "), calculated shape of the array of sliding blocks as (", + output_height, + ", ", + output_width, + "), but its components must be at least one."); + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/kleidiai/kai_kernels.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/kleidiai/kai_kernels.h new file mode 100644 index 0000000000000000000000000000000000000000..9b522d7f7705ac122d38855f3cc12f270c637093 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/kleidiai/kai_kernels.h @@ -0,0 +1,42 @@ +#pragma once +#include +#include +#if AT_KLEIDIAI_ENABLED() + +namespace at::native::kleidiai { + +/** + * @brief Rearranges the quantized weight to support kleidiai inference + * @param bl Groupsize for quantization should be multiple of 32 + */ +void kai_pack_int4_rhs( + const Tensor& weight_packed, + const Tensor& weight, + const Tensor& scales, + const std::optional& bias, + const int64_t n, + const int64_t k, + const int64_t bl); + +/** + * @brief Outputs the buffer size for the packed weights + * @param bl Groupsize for quantization. 32 for groupwise , 0 for channelwise + */ +size_t kai_pack_rhs_int4_size( + const int64_t n, + const int64_t k, + const int64_t bl); + +/** + * @brief Run 2 operations ( Input quantize and pack -> 4 bit Matmul ) + */ +void kai_quant_pack_lhs_int4_mm( + const Tensor& output, + const Tensor& input, + const Tensor& weight, + const int64_t m, + const int64_t n, + const int64_t k, + const int64_t bl); +} // namespace at::native::kleidiai +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/kleidiai/kai_pack.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/kleidiai/kai_pack.h new file mode 100644 index 0000000000000000000000000000000000000000..4ff3371ab5e2ac68a0f6a982f9d2f4f235449adb --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/kleidiai/kai_pack.h @@ -0,0 +1,106 @@ +#pragma once +#include +#include +#include +#include +#if AT_KLEIDIAI_ENABLED() + +namespace at::native::kleidiai { + +template +void kai_pack_rhs_groupwise_int4( + T& kernel, + const Tensor& weight_packed, + const Tensor& weight, + const Tensor& scales, + const std::optional& bias, + const int64_t n, + const int64_t k, + const int64_t bl, + const int64_t rhs_stride, + const int64_t scale_stride) { + const auto& ukernel = kernel.ukernel; + const size_t nr = ukernel.get_nr(); + const size_t kr = ukernel.get_kr(); + const size_t sr = ukernel.get_sr(); + auto weight_packed_data = + reinterpret_cast(weight_packed.data_ptr()); + const auto weight_data = weight.data_ptr(); + auto scales_data = scales.const_data_ptr(); + + if (weight_data == nullptr) { + AT_ERROR("kai_pack_rhs_channelwise_int4: Weight data pointer is null"); + } + + if (scales_data == nullptr) { + AT_ERROR("kai_pack_rhs_channelwise_int4: Scales data pointer is null"); + } + + float* bias_ptr = bias.has_value() ? bias.value().data_ptr() : NULL; + auto& params = kernel.rhs_pack_params; + + kernel.kai_run_rhs_pack( + /*num_groups=*/1, + n, + k, + nr, + kr, + sr, + bl, + (const uint8_t*)(weight_data), + rhs_stride, + bias_ptr, + scales_data, + scale_stride, + weight_packed_data, + 0, + ¶ms); +} + +template +void kai_pack_rhs_channelwise_int4( + T& kernel, + const Tensor& weight_packed, + const Tensor& weight, + const Tensor& scales, + const std::optional& bias, + const int64_t n, + const int64_t k) { + const auto& ukernel = kernel.ukernel; + const size_t nr = ukernel.get_nr(); + const size_t kr = ukernel.get_kr(); + const size_t sr = ukernel.get_sr(); + auto weight_packed_data = + reinterpret_cast(weight_packed.data_ptr()); + const auto weight_data = weight.data_ptr(); + const auto scales_data = scales.data_ptr(); + + if (weight_data == nullptr) { + AT_ERROR("kai_pack_rhs_channelwise_int4: Weight data pointer is null"); + } + + if (scales_data == nullptr) { + AT_ERROR("kai_pack_rhs_channelwise_int4: Scales data pointer is null"); + } + + float* bias_ptr = bias.has_value() ? bias.value().data_ptr() : NULL; + auto& params = kernel.rhs_pack_params; + + kernel.kai_run_rhs_pack( + /*num_groups=*/1, + n, + k, + nr, + kr, + sr, + (const uint8_t*)(weight_data), + (const float*)(bias_ptr), + (const float*)(scales_data), + weight_packed_data, + 0, + ¶ms); +} + +} // namespace at::native::kleidiai + +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/kleidiai/kai_ukernel_interface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/kleidiai/kai_ukernel_interface.h new file mode 100644 index 0000000000000000000000000000000000000000..c0835729f88b58859336924b6a0f3608516ef0d6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/kleidiai/kai_ukernel_interface.h @@ -0,0 +1,144 @@ +#pragma once +#include +#include +#if AT_KLEIDIAI_ENABLED() + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at::native::kleidiai { + +enum class kai_kernel_id { + matmul_clamp_f32_qai8dxp1x8_qsi4c32p8x8_1x8x32_neon_dotprod = + 0, // Groupwise 4 bit GEMV + matmul_clamp_f32_qai8dxp4x8_qsi4c32p4x8_4x8x32_neon_i8mm = + 1, // Groupwise 4 bit GEMM + matmul_clamp_f32_qai8dxp1x8_qsi4cxp8x8_1x8x32_neon_dotprod = + 2, // Channelwise 4 bit GEMV + matmul_clamp_f32_qai8dxp4x8_qsi4cxp8x8_8x8x32_neon_i8mm = + 3 // Channelwise 4 bit GEMM +}; + +// Channelwise Kernel mapping +struct kai_matmul_ukernel_f32_qa8dxp_qs4cxp { + struct kai_matmul_clamp_f32_qai8dxp_qsi4cxp_ukernel ukernel; + struct kai_rhs_pack_nxk_qsi4cxp_qs4cxs1s0_params rhs_pack_params; + size_t (*kai_get_lhs_packed_size)( + size_t m, + size_t k, + size_t mr, + size_t kr, + size_t sr); + size_t (*kai_get_rhs_packed_size)( + size_t n, + size_t k, + size_t nr, + size_t kr, + size_t sr); + void (*kai_run_lhs_quant_pack)( + size_t m, + size_t k, + size_t mr, + size_t kr, + size_t sr, + size_t m_idx_start, + const float* lhs, + size_t lhs_stride, + void* lhs_packed); + void (*kai_run_rhs_pack)( + size_t num_groups, + size_t n, + size_t k, + size_t nr, + size_t kr, + size_t sr, + const uint8_t* rhs, + const float* bias, + const float* scale, + void* rhs_packed, + size_t extra_bytes, + const struct kai_rhs_pack_nxk_qsi4cxp_qs4cxs1s0_params* params); + + kai_matmul_ukernel_f32_qa8dxp_qs4cxp( + const kai_matmul_clamp_f32_qai8dxp_qsi4cxp_ukernel& kernel) + : ukernel(kernel), + kai_get_lhs_packed_size( + &kai_get_lhs_packed_size_lhs_quant_pack_qai8dxp_f32), + kai_get_rhs_packed_size( + &kai_get_rhs_packed_size_rhs_pack_nxk_qsi4cxp_qs4cxs1s0), + kai_run_lhs_quant_pack(&kai_run_lhs_quant_pack_qai8dxp_f32), + kai_run_rhs_pack(&kai_run_rhs_pack_nxk_qsi4cxp_qs4cxs1s0) {} +}; + +struct kai_matmul_ukernel_f32_qa8dxp_qs4cxp +kai_select_channelwise_matmul_ukernel(const kai_kernel_id id); + +// Groupwise Kernel mapping +struct kai_matmul_ukernel_f32_qa8dxp_qs4c32p { + struct kai_matmul_clamp_f32_qai8dxp_qsi4c32p_ukernel ukernel; + struct kai_rhs_pack_nxk_qsi4c32p_qsu4c32s1s0_params rhs_pack_params; + size_t (*kai_get_lhs_packed_size)( + size_t m, + size_t k, + size_t mr, + size_t kr, + size_t sr); + size_t (*kai_get_rhs_packed_size)( + size_t n, + size_t k, + size_t nr, + size_t kr, + size_t sr, + size_t bl, + enum kai_datatype scale_dt); + void (*kai_run_lhs_quant_pack)( + size_t m, + size_t k, + size_t mr, + size_t kr, + size_t sr, + size_t m_idx_start, + const float* lhs, + size_t lhs_stride, + void* lhs_packed); + void (*kai_run_rhs_pack)( + size_t num_groups, + size_t n, + size_t k, + size_t nr, + size_t kr, + size_t sr, + size_t bl, + const uint8_t* rhs, + size_t rhs_stride, + const float* bias, + const void* scale, + size_t scale_stride, + void* rhs_packed, + size_t extra_bytes, + const struct kai_rhs_pack_nxk_qsi4c32p_qsu4c32s1s0_params* params); + + kai_matmul_ukernel_f32_qa8dxp_qs4c32p( + const kai_matmul_clamp_f32_qai8dxp_qsi4c32p_ukernel& kernel) + : ukernel(kernel), + kai_get_lhs_packed_size( + &kai_get_lhs_packed_size_lhs_quant_pack_qai8dxp_f32), + kai_get_rhs_packed_size( + &kai_get_rhs_packed_size_rhs_pack_nxk_qsi4c32p_qsu4c32s1s0), + kai_run_lhs_quant_pack(&kai_run_lhs_quant_pack_qai8dxp_f32), + kai_run_rhs_pack(&kai_run_rhs_pack_nxk_qsi4c32p_qsu4c32s1s0) {} +}; + +struct kai_matmul_ukernel_f32_qa8dxp_qs4c32p kai_select_groupwise_matmul_ukernel( + const kai_kernel_id id); + +} // namespace at::native::kleidiai +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/layer_norm.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/layer_norm.h new file mode 100644 index 0000000000000000000000000000000000000000..0181f35fd6ed46e51e4e1d668b8a6f66ab2bb022 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/layer_norm.h @@ -0,0 +1,141 @@ +#pragma once + +#include +#include +#include + +namespace at::native { + +namespace { + +C10_ALWAYS_INLINE void _check_rms_norm_inputs_symint( + const Tensor& input, + c10::SymIntArrayRef normalized_shape, + const Tensor& weight /* optional */) { + + const int normalized_ndim = normalized_shape.size(); + TORCH_CHECK( + normalized_ndim >= 1, + "Expected normalized_shape to be at least 1-dimensional, i.e., ", + "containing at least one element, but got normalized_shape = ", + normalized_shape); + TORCH_CHECK( + !weight.defined() || weight.sym_sizes().equals(normalized_shape), + "Expected weight to be of same shape as normalized_shape, but got ", + "weight of shape ", + weight.sym_sizes(), + " and normalized_shape = ", + normalized_shape); + + const auto input_ndim = input.dim(); + const auto input_shape = input.sym_sizes(); + if (input_ndim < normalized_ndim || + !input_shape.slice(input_ndim - normalized_ndim) + .equals(normalized_shape)) { + std::stringstream ss; + ss << "Given normalized_shape=" << normalized_shape + << ", expected input with shape [*"; + for (auto size : normalized_shape) { + ss << ", " << size; + } + ss << "], but got input of size" << input_shape; + TORCH_CHECK(false, ss.str()); + } +} + +C10_ALWAYS_INLINE std::pair _check_layer_norm_inputs( + const Tensor& input, + IntArrayRef normalized_shape, + const Tensor& weight /* optional */, + const Tensor& bias /* optional */) { + + const int normalized_ndim = normalized_shape.size(); + TORCH_CHECK( + normalized_ndim >= 1, + "Expected normalized_shape to be at least 1-dimensional, i.e., ", + "containing at least one element, but got normalized_shape = ", + normalized_shape); + TORCH_CHECK( + !weight.defined() || weight.sizes().equals(normalized_shape), + "Expected weight to be of same shape as normalized_shape, but got ", + "weight of shape ", + weight.sizes(), + " and normalized_shape = ", + normalized_shape); + TORCH_CHECK( + !bias.defined() || bias.sizes().equals(normalized_shape), + "Expected bias to be of same shape as normalized_shape, but got ", + "bias of shape ", + bias.sizes(), + " and normalized_shape = ", + normalized_shape); + + const auto input_shape = input.sizes(); + const auto input_ndim = input.dim(); + + if (input_ndim < normalized_ndim || + !input_shape.slice(input_ndim - normalized_ndim) + .equals(normalized_shape)) { + std::stringstream ss; + ss << "Given normalized_shape=" << normalized_shape + << ", expected input with shape [*"; + for (auto size : normalized_shape) { + ss << ", " << size; + } + ss << "], but got input of size" << input_shape; + TORCH_CHECK(false, ss.str()); + } + + const int axis = input_ndim - normalized_ndim; + const int64_t M = + c10::multiply_integers(input_shape.cbegin(), input_shape.cbegin() + axis); + const int64_t N = + c10::multiply_integers(input_shape.cbegin() + axis, input_shape.cend()); + + return std::make_pair(M, N); +} + +} // namespace + +void layer_norm_cpu_out( + at::Tensor& out, + const at::Tensor& input, + const Tensor& gamma, + const Tensor& beta, + double eps, + int64_t M, + int64_t N); + +Tensor rms_norm_symint( + const Tensor& input, + c10::SymIntArrayRef normalized_shape, + const std::optional& weight_opt /* optional */, + std::optional eps); + +using forward_fn = void (*)( + const Tensor& /* X */, + const Tensor& /* gamma */, + const Tensor& /* beta */, + int64_t /* M */, + int64_t /* N */, + double /* eps */, + Tensor* /* Y */, + Tensor* /* mean */, + Tensor* /* rstd */); + +using backward_fn = void (*)( + const Tensor& /* dY */, + const Tensor& /* X */, + const Tensor& /* mean */, + const Tensor& /* rstd */, + const Tensor& /* gamma */, + int64_t /* M */, + int64_t /* N */, + Tensor* /* dX */, + Tensor* /* dgamma */, + Tensor* /* dbeta */); + +DECLARE_DISPATCH(forward_fn, LayerNormKernel) +DECLARE_DISPATCH(backward_fn, LayerNormBackwardKernel) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/Attr.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/Attr.h new file mode 100644 index 0000000000000000000000000000000000000000..13ae166d1616f696795e078db1f77cd1c26f2999 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/Attr.h @@ -0,0 +1,464 @@ +#pragma once + +#include +#include +#include +#include +#include + +namespace at::native::onednn { +/* oneDNN quantization usage: + https://oneapi-src.github.io/oneDNN/dev_guide_attributes_quantization.html# + + src_fp32 = scale_src * (src_int8 - zero_point) + wei_fp32 = scale_wei * (wei_int8 - zero_point) + dst_fp32 = scale_dst * (dst_int8 - zero_point) + fp32 Convolution: dst_fp32 = src_fp32 * wei_fp32 + Int8 Convolution: dst_fp32 = (src_int8 * wei_int8) * (scale_src * scale_wei) + Int8 Convolution: dst_int8 = 1 / scale_dst * dst_fp32; + + Considering zero-point (asymmetric): + dst_fp32 = (src_int8 - src_zp) * src_sc * wei_int8 * wei_sc + dst_sc * (dst_int8 - dst_zp) = (src_int8 - src_zp) * wei_int8 * src_sc * + wei_sc + dst_int8 = (src_int8 - src_zp) * wei_int8 * src_sc * wei_sc / dst_sc + + dst_zp + + considering bias: + fp32 Convolution: dst_fp32 = src_fp32 * wei_fp32 + bias + Int8 Convolution: dst_fp32 = (src_int8 * wei_int8) * (scale_src * scale_wei) + + bias Int8 Convolution: dst_fp32 = (src_int8 * wei_int8 + bias/(scale_src * + scale_wei)) * (scale_src * scale_wei) Int8 Convolution: dst_int8 = 1 / + scale_dst * dst_fp32; +*/ + +/* + oneDNN postops usage: + Currently, oneDNN supports 5 kinds of post ops. More details can be refered +to oneDNN doc. + https://oneapi-src.github.io/oneDNN/dev_guide_attributes_post_ops.html#doxid-dev-guide-attributes-post-ops-1dev-guide-attributes-post-ops-eltwise + +0. without post ops + dst = Conv(src, wei) + bias; + dst_int8 = 1/q_scale * dst; q_scale is the op output quantization scale + fp32 API: Attr attr; + int8 API: Attr attr(q_scale); + +1. append eltwise post op + dst = elt_scale * Eltwise{conv_scale * [Conv(src, wei) + bias], alpha, beta} + dst_int8 = 1/q_scale * dst; + fp32 API: + Attr attr; + attr.append_post_eltwise(1.f, conv_scale, 0.f, kind_with_linear) + attr.append_post_eltwise(elt_scale, alpha, beta, eltwise_algorithm) + int8 API: + Attr attr(q_scale); + attr.append_post_eltwise(1.f, conv_scale, 0.f, kind_with_linear) + attr.append_post_eltwise(elt_scale, alpha, beta, eltwise_algorithm) + +2. append sum post op + dst = conv_scale * Conv(src, wei) + sum_scale * (dst - zp) + dst_int8 = 1/q_scale * dst; + fp32 API: + Attr attr; + attr.append_post_eltwise(1.f, conv_scale, 0.f, kind_with_linear) + attr.append_post_sum(sum_scale) + int8 API: + Attr attr(q_scale); + attr.append_post_eltwise(1.f, conv_scale, 0.f, kind_with_linear) + attr.append_post_sum(sum_scale) + +3. append binary post op + dst = Binary[Conv(src, wei)] + +*/ +using kind_t = dnnl::primitive::kind; +struct PostOpParam { + // eltwise post op constructor + PostOpParam( + float scale, + float alpha, + float beta, + dnnl::algorithm algo, + kind_t kind) + : scale_(scale), alpha_(alpha), beta_(beta), algo_(algo), kind_(kind) {} + // sum post op constructor + PostOpParam(float scale, kind_t kind) : scale_(scale), kind_(kind) {} + // sum post op with zp + PostOpParam(float scale, int64_t zero_point, kind_t kind) + : scale_(scale), zero_point_(zero_point), kind_(kind) {} + // binary post op constructor + PostOpParam( + at::Tensor& binary, + dnnl::memory::desc& binary_md, + dnnl::memory::desc& expected_md, + dnnl::algorithm algo, + kind_t kind) + : binary_(binary), + meta_(binary_md), + expected_meta_(expected_md), + algo_(algo), + kind_(kind) {} + // prelu post op constructor + PostOpParam(int mask, kind_t kind) : mask_(mask), kind_(kind) {} + + // post sum or binary with scale post op constructor + PostOpParam( + at::Tensor& binary, + float scale, + dnnl::algorithm algo, + kind_t kind) + : scale_(scale), binary_(binary), algo_(algo), kind_(kind) {} + + // for int8 sum/eltwise + float scale_ = 1.0; + int64_t zero_point_ = 0; + // for eltwise + float alpha_ = 0.0; + float beta_ = 0.0; + // for binary + at::Tensor binary_ = at::Tensor(); + at::Tensor expected_binary_ = at::Tensor(); + void* binary_ptr_ = nullptr; + dnnl::memory::desc meta_ = dnnl::memory::desc(); + dnnl::memory::desc expected_meta_ = dnnl::memory::desc(); + // for prelu + int mask_ = 0; + // common + dnnl::algorithm algo_ = dnnl::algorithm::eltwise_relu; + kind_t kind_ = kind_t::eltwise; +}; + +class Attr { + public: + Attr() : q_scale_(1.f), q_zero_point_(0) {} + Attr(float q_scale, int64_t zp = 0) : q_scale_(q_scale), q_zero_point_(zp) {} + + /***** eltwise *****/ + dnnl::algorithm kind_with_relu = dnnl::algorithm::eltwise_relu; + dnnl::algorithm kind_with_sigmoid = dnnl::algorithm::eltwise_logistic; + dnnl::algorithm kind_with_gelu_tanh = dnnl::algorithm::eltwise_gelu_tanh; + dnnl::algorithm kind_with_gelu_erf = dnnl::algorithm::eltwise_gelu_erf; + dnnl::algorithm kind_with_mish = dnnl::algorithm::eltwise_mish; + dnnl::algorithm kind_with_linear = dnnl::algorithm::eltwise_linear; + dnnl::algorithm kind_with_swish = dnnl::algorithm::eltwise_swish; + dnnl::algorithm kind_with_sqrt = dnnl::algorithm::eltwise_sqrt; + dnnl::algorithm kind_with_tanh = dnnl::algorithm::eltwise_tanh; + dnnl::algorithm kind_with_square = dnnl::algorithm::eltwise_square; + dnnl::algorithm kind_with_abs = dnnl::algorithm::eltwise_abs; + dnnl::algorithm kind_with_exp = dnnl::algorithm::eltwise_exp; + dnnl::algorithm kind_with_log = dnnl::algorithm::eltwise_log; + dnnl::algorithm kind_with_round = dnnl::algorithm::eltwise_round; + dnnl::algorithm kind_with_hardswish = dnnl::algorithm::eltwise_hardswish; + dnnl::algorithm kind_with_soft_relu = dnnl::algorithm::eltwise_soft_relu; + dnnl::algorithm kind_with_elu = dnnl::algorithm::eltwise_elu; + dnnl::algorithm kind_with_pow = dnnl::algorithm::eltwise_pow; + dnnl::algorithm kind_with_clip = dnnl::algorithm::eltwise_clip; + // note: hardsigmoid seems oneDNN still not support + dnnl::algorithm kind_with_hardsigmoid = dnnl::algorithm::eltwise_hardsigmoid; + + /***** binary *****/ + dnnl::algorithm kind_with_binary_mul = dnnl::algorithm::binary_mul; + dnnl::algorithm kind_with_binary_add = dnnl::algorithm::binary_add; + dnnl::algorithm kind_with_binary_sub = dnnl::algorithm::binary_sub; + dnnl::algorithm kind_with_binary_div = dnnl::algorithm::binary_div; + dnnl::algorithm kind_with_binary_eq = dnnl::algorithm::binary_eq; + dnnl::algorithm kind_with_binary_ne = dnnl::algorithm::binary_ne; + dnnl::algorithm kind_with_binary_ge = dnnl::algorithm::binary_ge; + dnnl::algorithm kind_with_binary_gt = dnnl::algorithm::binary_gt; + dnnl::algorithm kind_with_binary_le = dnnl::algorithm::binary_le; + dnnl::algorithm kind_with_binary_lt = dnnl::algorithm::binary_lt; + dnnl::algorithm kind_with_binary_max = dnnl::algorithm::binary_max; + dnnl::algorithm kind_with_binary_min = dnnl::algorithm::binary_min; + + // append sum post op + Attr& append_post_sum( + float sum_scale, + float sum_q_scale = 1.f, + int64_t zp = 0) { + ops_params_.push_back( + PostOpParam(/*scale_sum*/ sum_scale * sum_q_scale, zp, kind_t::sum)); + return *this; + } + + // append eltwise post op + Attr& append_post_eltwise( + float scale, + float alpha, + float beta, + dnnl::algorithm algo) { + ops_params_.push_back( + PostOpParam(scale, alpha, beta, algo, kind_t::eltwise)); + return *this; + } + + // append binary post op + template + Attr& append_post_binary(dnnl::algorithm algo, const at::Tensor& binary) { + auto binary_ = binary.is_quantized() ? at::dequantize(binary) : binary; + bool binary_is_channels_last = + (binary_.suggest_memory_format() == at::MemoryFormat::ChannelsLast || + binary_.suggest_memory_format() == at::MemoryFormat::ChannelsLast3d); + + if constexpr (!is_matmul) { + binary_ = binary_is_channels_last ? binary_ : binary_.contiguous(); + } + dnnl::memory::desc md = get_onednn_md(binary_); + auto expected_md = dnnl::memory::desc( + md.get_dims(), md.get_data_type(), dnnl::memory::format_tag::any); + if constexpr (is_matmul) { + ops_params_.push_back(PostOpParam(binary_, md, md, algo, kind_t::binary)); + } else { + ops_params_.push_back( + PostOpParam(binary_, md, expected_md, algo, kind_t::binary)); + } + + return *this; + } + + Attr& append_scale_binary( + dnnl::algorithm algo, + at::Tensor binary, + float scale, + float sum_q_scale = 1.f, + int64_t zp = 0) { + ops_params_.push_back(PostOpParam( + binary, /*scale_sum*/ scale * sum_q_scale, algo, kind_t::binary)); + return *this; + } + + // append bias with binary_add method (only used for QConv now) + Attr& append_bias(const at::Tensor& binary, const int ndimension) { + // In PyTorch, bias are in shape of [OC], + // we expand its shape according to Conv dimension + // Conv1d [OC, 1, 1], Conv2d [1, OC, 1, ,1], Conv3d [1, OC, 1, 1, 1] + at::Tensor binary_ = binary.contiguous(); + dnnl::memory::desc binary_md; + switch (ndimension) { + case 1: + binary_md = dnnl::memory::desc( + {binary.size(0), 1, 1}, + dnnl::memory::data_type::f32, + dnnl::memory::format_tag::abc); + break; + case 2: + binary_md = dnnl::memory::desc( + {1, binary.size(0), 1, 1}, + dnnl::memory::data_type::f32, + dnnl::memory::format_tag::abcd); + break; + case 3: + binary_md = dnnl::memory::desc( + {1, binary.size(0), 1, 1, 1}, + dnnl::memory::data_type::f32, + dnnl::memory::format_tag::abcde); + break; + default: + TORCH_INTERNAL_ASSERT( + 0, "XPU only supports append_bias for Conv1d, Conv2d and Conv3d."); + } + // In this case, expected_md = binary_md + ops_params_.push_back(PostOpParam( + binary_, binary_md, binary_md, kind_with_binary_add, kind_t::binary)); + return *this; + } + + // append prelu post op + Attr& append_post_prelu(int mask) { + ops_params_.push_back(PostOpParam(mask, kind_t::prelu)); + return *this; + } + + dnnl::post_ops extract_post_ops(const at::Tensor& dst) { + // this function is used to extract post ops params from the ops_params_ + // and put them into onednn post ops + for (size_t i = 0; i < ops_params_.size(); ++i) { + kind_t kind = ops_params_[i].kind_; + switch (kind) { + case kind_t::eltwise: { + dnnl::algorithm algo = ops_params_[i].algo_; + float alpha = ops_params_[i].alpha_; + float beta = ops_params_[i].beta_; + dnnl_post_ops_.append_eltwise(algo, alpha, beta); + break; + } + case kind_t::sum: { + float scale = ops_params_[i].scale_; + int64_t zero_point = ops_params_[i].zero_point_; + // TODO [Asymmetric]: + // Post-sum zp for gpu is not supported currently + dnnl_post_ops_.append_sum(scale, zero_point); + break; + } + case kind_t::binary: { + dnnl::algorithm algo = ops_params_[i].algo_; + auto expected_md = ops_params_[i].expected_meta_; + // In this case user may create src1 memory descriptor with + // format_tag::any or set a specific tag. However, in later case if + // tags mismatch with dst, it would result in suboptimal performance. + // So here we use format_tag::any to make sure the fast can be + // selected. + // Thus we use expected_md (with format_any) here to create pd instead + // of original md + dnnl_post_ops_.append_binary(algo, expected_md); + break; + } + default: + break; + } + } + + return dnnl_post_ops_; + } + + bool with_sum() { + for (size_t i = 0; i < ops_params_.size(); ++i) { + if (ops_params_[i].kind_ == kind_t::sum) { + return true; + } + } + return false; + } + + bool with_binary() { + for (size_t i = 0; i < ops_params_.size(); ++i) { + if (ops_params_[i].kind_ == kind_t::binary) { + return true; + } + } + return false; + } + + void construct_post_binary( + dnnl::primitive_desc& pd, + std::unordered_map& args) { + // This function is used to construct binary memory desc in binary post ops. + // According to oneDNN doc, the binary tensor can be in shape of + // [1, 1, 1, 1], tensor broadcast + // [1, C, 1, 1], channel broadcast + // [dst.shape], no broadcast and eltwise-wise binary operations on dst + + auto engine = GpuEngineManager::Instance().get_engine( + {c10::kXPU, c10::xpu::current_device()}); + for (size_t i = 0; i < ops_params_.size(); ++i) { + kind_t kind = ops_params_[i].kind_; + if (kind == kind_t::binary) { + dnnl::memory binary_m; + auto binary = ops_params_[i].binary_; + auto md = ops_params_[i].meta_; + // qeury expected_md to achieve peak performance + auto expected_md = pd.query_md( + dnnl::query::exec_arg_md, + DNNL_ARG_ATTR_MULTIPLE_POST_OP(i) | DNNL_ARG_SRC_1); + + binary_m = at::native::onednn::make_onednn_memory( + md, engine, binary.data_ptr()); + + args.insert( + {DNNL_ARG_ATTR_MULTIPLE_POST_OP(i) | DNNL_ARG_SRC_1, binary_m}); + } + } + } + + float q_scale_ = 1.0; // the scale used to quantize the fused result from fp32 + // to int8, only works for int8 case + int64_t q_zero_point_ = 0; + std::vector ops_params_; // series of post ops + dnnl::post_ops dnnl_post_ops_; +}; + +static inline void construct_attr_for_unary( + const std::string_view& unary_post_op, + const torch::List>& unary_post_op_args, + const std::string_view& unary_post_op_algorithm, + at::native::onednn::Attr& attr) { + if (unary_post_op == "relu") { + attr = attr.append_post_eltwise( + /* eltwise_scale */ 1.f, + /* alpha */ 0.f, + /* beta */ 0.f, + attr.kind_with_relu); + } else if (unary_post_op == "leaky_relu") { + auto alpha = unary_post_op_args[0].value().to(); + attr = attr.append_post_eltwise(1.0, alpha, 0.f, attr.kind_with_relu); + } else if (unary_post_op == "tanh") { + attr = attr.append_post_eltwise(1.0f, 0.0f, 0.0f, attr.kind_with_tanh); + } else if (unary_post_op == "gelu") { + auto post_algorithm = unary_post_op_algorithm == "none" + ? attr.kind_with_gelu_erf + : attr.kind_with_gelu_tanh; + attr = attr.append_post_eltwise(1.0f, 0.0f, 0.0f, post_algorithm); + } else if (unary_post_op == "hardtanh") { + auto alpha = unary_post_op_args[0].value().to(); + auto beta = unary_post_op_args[1].value().to(); + attr = attr.append_post_eltwise(1.0, alpha, beta, attr.kind_with_clip); + } else if (unary_post_op == "hardswish") { + attr = attr.append_post_eltwise( + 1.0f, 1.f / 6.f, 1.f / 2.f, attr.kind_with_hardswish); + } else if (unary_post_op == "swish") { + attr = attr.append_post_eltwise(1.0f, 1.0f, 0.0f, attr.kind_with_swish); + } else { + TORCH_CHECK( + unary_post_op == "none", + "onednn qlinear: unspported unary post op", + unary_post_op); + } +} + +static inline void construct_attr_by_post_op( + const std::string_view& binary_post_op, + double binary_alpha, + double input1_scale, + int64_t input1_zero_point, + std::optional accum, + const std::string_view& unary_post_op, + const torch::List>& unary_post_op_args, + const std::string_view& unary_post_op_algorithm, + at::native::onednn::Attr& attr) { + bool is_none_post_op = + (binary_post_op == "none" && unary_post_op == "none"); // not post-ops + bool is_unary_post_op_only = + (binary_post_op == "none" && unary_post_op != "none"); // ex., conv + relu + bool is_valid_binary_combination = + (binary_post_op == "add" || binary_post_op == "sum") && + (unary_post_op == "none" || unary_post_op == "relu"); + TORCH_INTERNAL_ASSERT( + is_unary_post_op_only || is_none_post_op || is_valid_binary_combination, + "Please provide valid combination of unary post operators and binary post operators"); + + if (binary_post_op == "none") { + construct_attr_for_unary( + unary_post_op, unary_post_op_args, unary_post_op_algorithm, attr); + } else if (binary_post_op == "sum") { + if (unary_post_op == "none") { + if (input1_zero_point != 0) + attr = attr.append_post_eltwise( + /*scale*/ 1.f, + /*alpha*/ 1.f, + -input1_zero_point * input1_scale, + attr.kind_with_linear); + attr = attr.append_post_sum(1, input1_scale, /*input1_zero_point*/ 0); + } else if (unary_post_op == "relu") { + if (input1_zero_point != 0) + attr = attr.append_post_eltwise( + /*scale*/ 1.f, + /*alpha*/ 1.f, + -input1_zero_point * input1_scale, + attr.kind_with_linear); + attr = attr.append_post_sum(1, input1_scale, /*input1_zero_point*/ 0); + attr = attr.append_post_eltwise( + /* scale */ 1.f, + /* alpha */ 0.f, + /* beta */ 0.f, + attr.kind_with_relu); + } + } else if (binary_post_op == "add") { + TORCH_CHECK(accum.has_value()); + attr = attr.append_post_binary(attr.kind_with_binary_add, accum.value()); + if (unary_post_op == "relu") { + attr = attr.append_post_eltwise(1.f, 0.f, 0.f, attr.kind_with_relu); + } + } +} + +} // namespace at::native::onednn diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/Utils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/Utils.h new file mode 100644 index 0000000000000000000000000000000000000000..ac8645d3e4a50a382f49d4dff76966cbcd232e8e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/Utils.h @@ -0,0 +1,134 @@ +#pragma once +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include + +#include + +#define ONEDNN_SUPPORT_DETERMINISTIC \ + (DNNL_VERSION_MAJOR >= 3 && DNNL_VERSION_MINOR >= 4) + +namespace at::native::onednn { + +dnnl::memory::format_tag get_dnnl_default_format( + int ndims, + bool is_channels_last = false, + bool allow_undef = false); + +dnnl::memory::data_type get_onednn_dtype( + const at::Tensor& tensor, + bool allow_undef = false); + +dnnl::memory::data_type get_onednn_dtype_include_double( + const at::Tensor& tensor, + bool allow_undef = false); + +bool is_supported_onednn_dtype(const at::Tensor& tensor); + +dnnl::memory::dims get_onednn_dims(const at::Tensor& tensor); + +dnnl::memory::dims get_onednn_strides(const at::Tensor& tensor); +dnnl::memory::desc get_onednn_md(const at::Tensor& tensor); + +bool onednn_strides_check(const at::Tensor& src); +bool is_broadcast(const at::Tensor& t); +void undo_broadcast_on_batch(at::Tensor& m1, at::Tensor& m2); +void undo_broadcast(at::Tensor& tensor); + +bool is_onednn_matmul_strides(const at::Tensor& tensor); + +bool is_broadcast_from_other_to_self( + const at::Tensor& self, + const at::Tensor& other); + +at::MemoryFormat get_cl_tag_by_ndim(const int64_t ndim); + +void apply_tf32_if_allowed(dnnl::primitive_attr& primitive_attr); + +bool binary_valid( + const at::Tensor& self, + const at::Tensor& other, + bool is_fusion = false); + +bool use_channels_last_for_conv( + const at::Tensor& src, + const at::Tensor& weight); + +dnnl::memory::format_tag conv_src_fmt( + const int64_t ndim, + const bool is_channels_last = false); + +dnnl::memory::dims compatible_weight_dims( + const int64_t ndim, + const int64_t groups, + const int64_t oc, + const int64_t ic, + const IntArrayRef wsizes); + +dnnl::memory::format_tag conv_weight_fmt( + const int64_t ndim, + const bool grouped = false, + const bool is_channels_last = false); + +template +dnnl::memory::dims compatible_dilation(Vec&& dilation) { + dnnl::memory::dims ret = dilation.vec(); + for (auto it = ret.begin(); it != ret.end(); it++) { + *it -= 1; + } + return ret; +} + +template +dnnl::memory dnnl_memory_from_host_scalar( + T host_value, + Tensor& holder, + dnnl::engine& engine) { + auto options = at::TensorOptions() + .dtype(c10::CppTypeToScalarType::value) + .device(kXPU); + holder = at::empty({1}, options).fill_(host_value); + dnnl::memory::desc md = get_onednn_md(holder); + dnnl::memory mem = make_onednn_memory(md, engine, holder.data_ptr()); + return mem; +} + +struct PartitionCache { + std::unordered_map, dnnl::graph::partition> partition_map_{}; + + // The first 8 bits are reserved + // bit 0: is int8 + // bit 1: is uint8 + // bit 2: fp16(0) / bf16(1) + // bit 3: is fp32 + // bit 4: is sdp pattern + // bit 5-7: N/A + // The rest of the bits depend upon the arguments provided + // However, down the line, we might have different bitsets for different + // patterns + dnnl::graph::partition& insert_partition_cache( + std::bitset<32>& patternID, + dnnl::graph::partition& p) { + partition_map_[patternID] = std::move(p); + return partition_map_[patternID]; + } + std::optional> find_partition( + std::bitset<32>& patternID) { + auto iter = partition_map_.find(patternID); + if (iter != partition_map_.end()) { + return iter->second; + } + return std::nullopt; + } +}; + +} // namespace at::native::onednn diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/oneDNN.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/oneDNN.h new file mode 100644 index 0000000000000000000000000000000000000000..a4f993eebcd642389b44c1afd2f82362cf0aad27 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/oneDNN.h @@ -0,0 +1,173 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::native::onednn { + +TORCH_API sycl::event matmul( + at::Tensor& result, + const at::Tensor& mat1, + const at::Tensor& mat2, + const at::Tensor& b_raw, + bool m2_trans, + Attr attr, + const std::vector& deps = {}); + +TORCH_API sycl::event convolution( + at::Tensor& dst, + const at::Tensor& src, + const at::Tensor& weight, + const at::Tensor& bia, + IntArrayRef padding_front_top_left, + IntArrayRef padding_back_bottom_right, + IntArrayRef stride, + IntArrayRef dilation, + int64_t groups, + Attr& attr, + const std::vector& deps = {}); + +TORCH_API sycl::event convolution_backward_weights( + at::Tensor& diff_weight, + at::Tensor& diff_bia, + const at::Tensor& diff_dst, + const at::Tensor& src, + IntArrayRef diff_weight_aten_size, + IntArrayRef padding_front_top_left, + IntArrayRef padding_back_bottom_right, + IntArrayRef stride, + IntArrayRef dilation, + int64_t groups, + const std::vector& deps = {}); + +TORCH_API sycl::event convolution_backward_data( + at::Tensor& diff_src, + const at::Tensor& diff_dst, + const at::Tensor& weight, + IntArrayRef padding_front_top_left, + IntArrayRef padding_back_bottom_right, + IntArrayRef stride, + IntArrayRef dilation, + int64_t groups, + bool bias_defined, + const std::vector& deps = {}); + +TORCH_API sycl::event deconvolution( + at::Tensor& dst, + const at::Tensor& src, + const at::Tensor& weight, + const at::Tensor& bia, + IntArrayRef stride, + IntArrayRef padding, + IntArrayRef dst_padding, + IntArrayRef dilation, + int64_t groups, + Attr& attr, + const std::vector& deps = {}); + +TORCH_API sycl::event deconvolution_backward_data( + at::Tensor& diff_src, + const at::Tensor& diff_dst, + const at::Tensor& weight, + IntArrayRef stride, + IntArrayRef padding, + IntArrayRef dilation, + int64_t groups, + bool bias_defined, + const std::vector& deps = {}); + +TORCH_API sycl::event deconvolution_backward_weights( + at::Tensor& diff_weight, + at::Tensor& diff_bia, + const at::Tensor& diff_dst, + const at::Tensor& src, + IntArrayRef stride, + IntArrayRef padding, + IntArrayRef dilation, + int64_t groups, + const std::vector& deps = {}); + +dnnl::memory::dims conv_dst_size( + int64_t ndim, + IntArrayRef src_tz, + IntArrayRef wgh_tz, + IntArrayRef padding_front_top_left, + IntArrayRef padding_back_bottom_right, + IntArrayRef stride, + IntArrayRef dilation); + +dnnl::memory::dims deconv_dst_size( + IntArrayRef src_size, + IntArrayRef wgh_size, + IntArrayRef padding, + IntArrayRef stride, + IntArrayRef dilation, + IntArrayRef dst_padding, + int64_t groups); + +at::Tensor quantized_convolution( + at::Tensor act, + double act_scale, + int64_t act_zero_point, + at::Tensor weight, + at::Tensor weight_scales, + at::Tensor weight_zero_points, + std::optional bias, + torch::List stride, + torch::List padding, + torch::List dilation, + bool transposed, + int64_t groups, + at::Tensor output, + double inv_output_scale, + int64_t output_zero_point, + std::optional accum, + double accum_scale, + int64_t accum_zero_point, + std::optional output_dtype, + std::optional binary_attr, + std::optional binary_alpha, + std::optional unary_attr, + torch::List> unary_scalars, + std::optional unary_algorithm); + +void quantized_matmul( + at::Tensor mat1, // act + double input_scale, + int64_t input_zero_point, + at::Tensor mat2, // weight + at::Tensor& weight_scales, + at::Tensor& weight_zero_points, + at::Tensor& b_raw, + at::Tensor result, // output + double output_scale, + int64_t output_zero_point, + std::optional output_dtype, + std::optional other, // extra input for binary-post-op + double other_scale, + int64_t other_zero_point, + const c10::string_view& binary_post_op, + double binary_alpha, + const c10::string_view& unary_post_op, + torch::List>& unary_post_op_args, + c10::string_view unary_post_op_algorithm, + bool m2_trnas); + +void gpu_float_sdpa( + int batch_size, + int seq_len_q, + int seq_len_k, + int num_head, + int num_head_kv, + int head_dim, + int head_dim_v, + const Tensor& query, + const Tensor& key, + const Tensor& value, + std::optional attn_mask, + bool is_causal, + float softmax_scale, + const Tensor& output); +} // namespace at::native::onednn diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/oneDNNContext.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/oneDNNContext.h new file mode 100644 index 0000000000000000000000000000000000000000..b1a85fb5b3bdb0ef0c5740a980126811e0024679 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mkldnn/xpu/detail/oneDNNContext.h @@ -0,0 +1,87 @@ +#pragma once + +#include + +#include +#include +#include +#include + +#include +#include +#include + +namespace at::native::onednn { + +TORCH_XPU_API dnnl::memory make_onednn_memory( + dnnl::memory::desc md, + dnnl::engine& engine, + void* ptr); + +// Keep non-static and non-inline +bool set_onednn_verbose(int level); + +// GpuEngineManager singleton +struct TORCH_XPU_API GpuEngineManager { + static GpuEngineManager& Instance(); // Singleton + + dnnl::engine& get_engine(const Device& device) { + TORCH_INTERNAL_ASSERT(device.type() == kXPU); + TORCH_INTERNAL_ASSERT(device.index() < c10::xpu::device_count()); + return *engine_pool[device.index()]; + } + + GpuEngineManager(GpuEngineManager const&) = delete; + GpuEngineManager& operator=(GpuEngineManager const&) = delete; + GpuEngineManager(GpuEngineManager&&) = default; + GpuEngineManager& operator=(GpuEngineManager&&) = default; + + protected: + GpuEngineManager(); + ~GpuEngineManager() = default; + + private: + std::vector> engine_pool; +}; + +// GpuStreamManager singleton +struct TORCH_XPU_API GpuStreamManager { + static GpuStreamManager& Instance(); // Singleton + + dnnl::stream get_stream() { + auto stream = c10::xpu::getCurrentXPUStream(); + auto priority = stream.priority(); + auto device_index = stream.device_index(); + if (stream_pool[device_index][priority].find(stream) == + stream_pool[device_index][priority].end()) { + stream_pool[device_index][priority][stream] = + std::make_shared(dnnl::sycl_interop::make_stream( + GpuEngineManager::Instance().get_engine( + {c10::kXPU, device_index}), + stream.queue())); + } + return *stream_pool[device_index][priority][stream]; + } + + GpuStreamManager(GpuStreamManager const&) = delete; + GpuStreamManager& operator=(GpuStreamManager const&) = delete; + GpuStreamManager(GpuStreamManager&&) = default; + GpuStreamManager& operator=(GpuStreamManager&&) = default; + + protected: + GpuStreamManager() { + c10::DeviceIndex device_count = c10::xpu::device_count(); + TORCH_INTERNAL_ASSERT(device_count > 0); + stream_pool.resize(device_count); + } + ~GpuStreamManager() = default; + + private: + using stream_hash_map = + ska::flat_hash_map>; + std::vector< + std::array> + stream_pool; +}; + +} // namespace at::native::onednn diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/Copy.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/Copy.h new file mode 100644 index 0000000000000000000000000000000000000000..cd65d8ae00e655d05f15ef1f744d771fe0d4eadc --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/Copy.h @@ -0,0 +1,14 @@ +// Copyright © 2022 Apple Inc. + +#pragma once +#include + +namespace at::native::mps { + +at::Tensor& mps_copy_( + at::Tensor& dst, + const at::Tensor& src, + bool non_blocking); +void copy_blit_mps(void* dst, const void* src, size_t size); + +} // namespace at::native::mps diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MPSGraphSequoiaOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MPSGraphSequoiaOps.h new file mode 100644 index 0000000000000000000000000000000000000000..94ea7b8734b3e699fc45077ba3d844b8277ab8a0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MPSGraphSequoiaOps.h @@ -0,0 +1,41 @@ +#pragma once + +#include + +#if !defined(__MAC_15_0) && (!defined(MAC_OS_X_VERSION_15_0) || (MAC_OS_X_VERSION_MIN_REQUIRED < MAC_OS_X_VERSION_15_0)) + +@interface MPSNDArrayIdentity : MPSNDArrayUnaryKernel +- (MPSNDArray* __nullable)reshapeWithCommandBuffer:(__nullable id)cmdBuf + sourceArray:(MPSNDArray* __nonnull)sourceArray + shape:(MPSShape* __nonnull)shape + destinationArray:(MPSNDArray* __nullable)destinationArray; +@end + +@interface MPSNDArrayDescriptor () +@property(readwrite, nonatomic) BOOL preferPackedRows; +@end + +@interface MPSNDArray () +- (nonnull instancetype)initWithBuffer:(id _Nonnull)buffer + offset:(NSUInteger)offset + descriptor:(MPSNDArrayDescriptor* _Nonnull)descriptor; +- (MPSNDArray* __nullable)arrayViewWithShape:(MPSShape* _Nullable)shape strides:(MPSShape* _Nonnull)strides; +@end + +typedef NS_ENUM(NSInteger, MTLMathMode) { + MTLMathModeSafe = 0, + MTLMathModeRelaxed = 1, + MTLMathModeFast = 2, +}; + +typedef NS_ENUM(NSInteger, MTLMathFloatingPointFunctions) { + MTLMathFloatingPointFunctionsFast = 0, + MTLMathFloatingPointFunctionsPrecise = 1, +}; + +@interface MTLCompileOptions () +@property(readwrite, nonatomic) MTLMathMode mathMode; +@property(readwrite, nonatomic) MTLMathFloatingPointFunctions mathFloatingPointFunctions; +@end + +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MPSGraphSonomaOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MPSGraphSonomaOps.h new file mode 100644 index 0000000000000000000000000000000000000000..6290245083a443ee2cd8109c81d270ec9674f9f7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MPSGraphSonomaOps.h @@ -0,0 +1,48 @@ +#pragma once + +#include + +#if !defined(__MAC_14_0) && (!defined(MAC_OS_X_VERSION_14_0) || (MAC_OS_X_VERSION_MIN_REQUIRED < MAC_OS_X_VERSION_14_0)) + +typedef NS_ENUM(NSUInteger, MPSGraphFFTScalingMode) { + MPSGraphFFTScalingModeNone = 0L, + MPSGraphFFTScalingModeSize = 1L, + MPSGraphFFTScalingModeUnitary = 2L, +}; + +@interface FakeMPSGraphFFTDescriptor : NSObject +@property(readwrite, nonatomic) BOOL inverse; +@property(readwrite, nonatomic) MPSGraphFFTScalingMode scalingMode; +@property(readwrite, nonatomic) BOOL roundToOddHermitean; ++ (nullable instancetype)descriptor; +@end + +@compatibility_alias MPSGraphFFTDescriptor FakeMPSGraphFFTDescriptor; + +@interface MPSGraph (SonomaOps) +- (MPSGraphTensor* _Nonnull)conjugateWithTensor:(MPSGraphTensor* _Nonnull)tensor name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)realPartOfTensor:(MPSGraphTensor* _Nonnull)tensor name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)fastFourierTransformWithTensor:(MPSGraphTensor* _Nonnull)tensor + axes:(NSArray* _Nonnull)axes + descriptor:(MPSGraphFFTDescriptor* _Nonnull)descriptor + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)realToHermiteanFFTWithTensor:(MPSGraphTensor* _Nonnull)tensor + axes:(NSArray* _Nonnull)axes + descriptor:(MPSGraphFFTDescriptor* _Nonnull)descriptor + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)HermiteanToRealFFTWithTensor:(MPSGraphTensor* _Nonnull)tensor + axes:(NSArray* _Nonnull)axes + descriptor:(MPSGraphFFTDescriptor* _Nonnull)descriptor + name:(NSString* _Nullable)name; +@end + +// define BFloat16 enums for MacOS13 +#define MPSDataTypeBFloat16 ((MPSDataType)(MPSDataTypeAlternateEncodingBit | MPSDataTypeFloat16)) + +// define Metal version +#define MTLLanguageVersion3_1 ((MTLLanguageVersion)((3 << 16) + 1)) +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MPSGraphVenturaOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MPSGraphVenturaOps.h new file mode 100644 index 0000000000000000000000000000000000000000..5497c83f7b9a684cd70716cf605d66c2461ce9bf --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MPSGraphVenturaOps.h @@ -0,0 +1,196 @@ +#pragma once +#include + +// TODO: Remove me when moved to MacOS 13 +#if !defined(__MAC_13_2) && (!defined(MAC_OS_X_VERSION_13_2) || (MAC_OS_X_VERSION_MIN_REQUIRED < MAC_OS_X_VERSION_13_2)) + +@interface FakeMPSGraphConvolution3DOpDescriptor : NSObject + +@property(readwrite, nonatomic) NSUInteger strideInX; +@property(readwrite, nonatomic) NSUInteger strideInY; +@property(readwrite, nonatomic) NSUInteger strideInZ; +@property(readwrite, nonatomic) NSUInteger dilationRateInX; +@property(readwrite, nonatomic) NSUInteger dilationRateInY; +@property(readwrite, nonatomic) NSUInteger dilationRateInZ; + +@property(readwrite, nonatomic) NSUInteger paddingLeft; +@property(readwrite, nonatomic) NSUInteger paddingRight; +@property(readwrite, nonatomic) NSUInteger paddingTop; +@property(readwrite, nonatomic) NSUInteger paddingBottom; +@property(readwrite, nonatomic) NSUInteger paddingFront; +@property(readwrite, nonatomic) NSUInteger paddingBack; + +@property(readwrite, nonatomic) MPSGraphPaddingStyle paddingStyle; +@property(readwrite, nonatomic) MPSGraphTensorNamedDataLayout dataLayout; +@property(readwrite, nonatomic) MPSGraphTensorNamedDataLayout weightsLayout; + +@property(readwrite, nonatomic) NSUInteger groups; + +@end + +@compatibility_alias MPSGraphConvolution3DOpDescriptor FakeMPSGraphConvolution3DOpDescriptor; + +#endif + +@interface MPSGraph (VenturaOps) + +#if !defined(__MAC_13_0) && (!defined(MAC_OS_X_VERSION_13_0) || (MAC_OS_X_VERSION_MIN_REQUIRED < MAC_OS_X_VERSION_13_0)) + +typedef NS_ENUM(NSUInteger, MPSGraphResizeNearestRoundingMode) { + MPSGraphResizeNearestRoundingModeRoundPreferCeil = 0L, + MPSGraphResizeNearestRoundingModeRoundPreferFloor = 1L, + MPSGraphResizeNearestRoundingModeCeil = 2L, + MPSGraphResizeNearestRoundingModeFloor = 3L, + MPSGraphResizeNearestRoundingModeRoundToEven = 4L, + MPSGraphResizeNearestRoundingModeRoundToOdd = 5L, +}; + +// Define complex enums for MacOS 12 +#define MPSDataTypeComplexBit 0x01000000 +#define MPSDataTypeComplexFloat32 ((MPSDataType)(MPSDataTypeFloatBit | MPSDataTypeComplexBit | 64)) +#define MPSDataTypeComplexFloat16 ((MPSDataType)(MPSDataTypeFloatBit | MPSDataTypeComplexBit | 32)) +#endif + +- (MPSGraphTensor* _Nonnull)convolution3DWithSourceTensor:(MPSGraphTensor* _Nonnull)source + weightsTensor:(MPSGraphTensor* _Nonnull)weights + descriptor:(MPSGraphConvolution3DOpDescriptor* _Nonnull)descriptor + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull) + convolution3DDataGradientWithIncomingGradientTensor:(MPSGraphTensor* _Nonnull)incomingGradient + weightsTensor:(MPSGraphTensor* _Nonnull)weights + outputShape:(MPSShape* _Nonnull)outputShape + forwardConvolutionDescriptor: + (MPSGraphConvolution3DOpDescriptor* _Nonnull)forwardConvolutionDescriptor + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull) + convolution3DWeightsGradientWithIncomingGradientTensor:(MPSGraphTensor* _Nonnull)incomingGradient + sourceTensor:(MPSGraphTensor* _Nonnull)source + outputShape:(MPSShape* _Nonnull)outputShape + forwardConvolutionDescriptor: + (MPSGraphConvolution3DOpDescriptor* _Nonnull)forwardConvolutionDescriptor + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)cumulativeSumWithTensor:(MPSGraphTensor* _Nonnull)tensor + axis:(NSInteger)axis + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)sortWithTensor:(MPSGraphTensor* _Nonnull)tensor + axis:(NSInteger)axis + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)sortWithTensor:(MPSGraphTensor* _Nonnull)tensor + axis:(NSInteger)axis + descending:(BOOL)descending + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)sortWithTensor:(MPSGraphTensor* _Nonnull)tensor + axisTensor:(MPSGraphTensor* _Nonnull)axisTensor + descending:(BOOL)descending + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)sortWithTensor:(MPSGraphTensor* _Nonnull)tensor + axisTensor:(MPSGraphTensor* _Nonnull)axisTensor + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)argSortWithTensor:(MPSGraphTensor* _Nonnull)tensor + axis:(NSInteger)axis + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)argSortWithTensor:(MPSGraphTensor* _Nonnull)tensor + axis:(NSInteger)axis + descending:(BOOL)descending + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)argSortWithTensor:(MPSGraphTensor* _Nonnull)tensor + axisTensor:(MPSGraphTensor* _Nonnull)axisTensor + descending:(BOOL)descending + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)argSortWithTensor:(MPSGraphTensor* _Nonnull)tensor + axisTensor:(MPSGraphTensor* _Nonnull)axisTensor + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)inverseOfTensor:(MPSGraphTensor* _Nonnull)inputTensor name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)resizeNearestWithTensor:(MPSGraphTensor* _Nonnull)imagesTensor + sizeTensor:(MPSGraphTensor* _Nonnull)size + nearestRoundingMode:(MPSGraphResizeNearestRoundingMode)nearestRoundingMode + centerResult:(BOOL)centerResult + alignCorners:(BOOL)alignCorners + layout:(MPSGraphTensorNamedDataLayout)layout + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)resizeNearestWithTensor:(MPSGraphTensor* _Nonnull)imagesTensor + sizeTensor:(MPSGraphTensor* _Nonnull)size + scaleOffsetTensor:(MPSGraphTensor* _Nonnull)scaleOffset + nearestRoundingMode:(MPSGraphResizeNearestRoundingMode)nearestRoundingMode + layout:(MPSGraphTensorNamedDataLayout)layout + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)resizeBilinearWithTensor:(MPSGraphTensor* _Nonnull)imagesTensor + sizeTensor:(MPSGraphTensor* _Nonnull)size + centerResult:(BOOL)centerResult + alignCorners:(BOOL)alignCorners + layout:(MPSGraphTensorNamedDataLayout)layout + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)resizeBilinearWithTensor:(MPSGraphTensor* _Nonnull)imagesTensor + sizeTensor:(MPSGraphTensor* _Nonnull)size + scaleOffsetTensor:(MPSGraphTensor* _Nonnull)scaleOffset + layout:(MPSGraphTensorNamedDataLayout)layout + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)resizeNearestWithGradientTensor:(MPSGraphTensor* _Nonnull)gradient + input:(MPSGraphTensor* _Nonnull)input + nearestRoundingMode:(MPSGraphResizeNearestRoundingMode)nearestRoundingMode + centerResult:(BOOL)centerResult + alignCorners:(BOOL)alignCorners + layout:(MPSGraphTensorNamedDataLayout)layout + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)resizeNearestWithGradientTensor:(MPSGraphTensor* _Nonnull)gradient + input:(MPSGraphTensor* _Nonnull)input + scaleOffsetTensor:(MPSGraphTensor* _Nonnull)scaleOffset + nearestRoundingMode:(MPSGraphResizeNearestRoundingMode)nearestRoundingMode + layout:(MPSGraphTensorNamedDataLayout)layout + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)resizeBilinearWithGradientTensor:(MPSGraphTensor* _Nonnull)gradient + input:(MPSGraphTensor* _Nonnull)input + centerResult:(BOOL)centerResult + alignCorners:(BOOL)alignCorners + layout:(MPSGraphTensorNamedDataLayout)layout + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)resizeBilinearWithGradientTensor:(MPSGraphTensor* _Nonnull)gradient + input:(MPSGraphTensor* _Nonnull)input + scaleOffsetTensor:(MPSGraphTensor* _Nonnull)scaleOffset + layout:(MPSGraphTensorNamedDataLayout)layout + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)sampleGridWithSourceTensor:(MPSGraphTensor* _Nonnull)source + coordinateTensor:(MPSGraphTensor* _Nonnull)coordinates + layout:(MPSGraphTensorNamedDataLayout)layout + normalizeCoordinates:(BOOL)normalizeCoordinates + relativeCoordinates:(BOOL)relativeCoordinates + alignCorners:(BOOL)alignCorners + paddingMode:(MPSGraphPaddingMode)paddingMode + samplingMode:(MPSGraphResizeMode)samplingMode + constantValue:(double)constantValue + name:(NSString* _Nullable)name; + +- (MPSGraphTensor* _Nonnull)sampleGridWithSourceTensor:(MPSGraphTensor* _Nonnull)source + coordinateTensor:(MPSGraphTensor* _Nonnull)coordinates + layout:(MPSGraphTensorNamedDataLayout)layout + normalizeCoordinates:(BOOL)normalizeCoordinates + relativeCoordinates:(BOOL)relativeCoordinates + alignCorners:(BOOL)alignCorners + paddingMode:(MPSGraphPaddingMode)paddingMode + nearestRoundingMode:(MPSGraphResizeNearestRoundingMode)nearestRoundingMode + constantValue:(double)constantValue + name:(NSString* _Nullable)name; +- (MPSGraphTensor* _Nonnull)truncateWithTensor:(MPSGraphTensor* _Nonnull)tensor name:(NSString* _Nullable)name; + +@end diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MetalShaderLibrary.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MetalShaderLibrary.h new file mode 100644 index 0000000000000000000000000000000000000000..0d29b31e57ab6031515a126cb7d23959dd690f54 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/MetalShaderLibrary.h @@ -0,0 +1,167 @@ +#pragma once +#ifdef __OBJC__ +#include +typedef id MTLLibrary_t; +typedef id MTLFunction_t; +typedef id MTLComputePipelineState_t; +typedef id MTLComputeCommandEncoder_t; +#else +typedef void MTLCompileOptions; +typedef void* MTLLibrary_t; +typedef void* MTLFunction_t; +typedef void* MTLComputePipelineState_t; +typedef void* MTLComputeCommandEncoder_t; +#endif + +#include +#include +#include +#include +#include +#include +#include + +// Forward declaration of TensorBase and TensorIteratorBase +namespace at { +class TensorBase; +struct TensorIteratorBase; +} // namespace at + +namespace at::native::mps { + +namespace detail { +template +class has_size_type { + template + static constexpr std::true_type check(typename U::size_type*); + template + static constexpr std::false_type check(...); + + public: + static constexpr bool value = decltype(check(nullptr))::value; +}; + +template +constexpr bool has_size_type_v = has_size_type::value; + +} // namespace detail + +class MetalKernelFunction { + public: + MetalKernelFunction(MTLComputePipelineState_t cps_); + ~MetalKernelFunction(); + MetalKernelFunction(MetalKernelFunction&) = delete; + // Shader properties + uint64_t getMaxThreadsPerThreadgroup() const; + uint64_t getThreadExecutionWidth() const; + uint64_t getStaticThreadGroupMemoryLength() const; + void runCommandBlock(std::function f); + // Methods below should be called from runCommandBlock functionT + void startEncoding(); + void setArg(unsigned idx, const at::TensorBase& t); + void setArg(unsigned idx, const void* ptr, uint64_t size); + template < + typename T, + typename = std::enable_if_t< + std::is_integral_v || std::is_same_v || + (std::is_class_v && std::is_trivially_copyable_v && + !detail::has_size_type_v)>> + inline void setArg(unsigned idx, const T val) { + setArg(idx, &val, sizeof(T)); + } + + template < + typename Container, + typename = std::enable_if_t>> + inline void setArg(unsigned idx, const Container& values) { + setArg( + idx, + values.data(), + values.size() * sizeof(typename Container::value_type)); + } + void dispatch( + uint64_t length, + std::optional groupSize = std::nullopt); + void dispatch( + c10::ArrayRef length, + c10::OptionalArrayRef groupSize = std::nullopt); + + private: + MTLComputePipelineState_t cps; + MTLComputeCommandEncoder_t encoder = nullptr; +}; + +class MetalShaderLibrary { + public: + MetalShaderLibrary(std::string src) + : shaderSource(std::move(src)), nparams(0), compile_options(nullptr) {} + MetalShaderLibrary(std::string src, unsigned nparams_) + : shaderSource(std::move(src)), + nparams(nparams_), + compile_options(nullptr) {} + MetalShaderLibrary( + std::string src, + unsigned nparams_, + MTLCompileOptions* compile_options_) + : shaderSource(std::move(src)), + nparams(nparams_), + compile_options(compile_options_) {} + MetalShaderLibrary(const MetalShaderLibrary&) = delete; + virtual ~MetalShaderLibrary(); + std::vector getFunctionNames(); + std::shared_ptr getKernelFunction( + const std::string& name); + inline MTLComputePipelineState_t getPipelineStateForFunc( + const std::string& fname) { + return getLibraryPipelineState(getLibrary(), fname).first; + } + MTLComputePipelineState_t getPipelineStateForFunc( + const std::string& fname, + const std::initializer_list& params) { + return getLibraryPipelineState(getLibrary(params), fname).first; + } + inline MTLFunction_t getMTLFunction(const std::string& fname) { + return getLibraryPipelineState(getLibrary(), fname).second; + } + MTLFunction_t getMTLFunction( + const std::string& fname, + const std::initializer_list& params) { + return getLibraryPipelineState(getLibrary(params), fname).second; + } + static MetalShaderLibrary& getBundledLibrary(); + void exec_unary_kernel( + TensorIteratorBase& iter, + const std::string& name, + std::optional extra = std::nullopt); + + protected: + virtual MTLLibrary_t getLibrary(); + virtual MTLLibrary_t getLibrary( + const std::initializer_list& params); + MTLLibrary_t library = nullptr; + + private: + std::pair getLibraryPipelineState( + MTLLibrary_t lib, + const std::string& fname); + MTLLibrary_t compileLibrary(const std::string& src); + std::string shaderSource; + unsigned nparams; + MTLCompileOptions* compile_options; + std::unordered_map libMap; + std::unordered_map< + std::string, + std::pair> + cplMap; +}; + +class DynamicMetalShaderLibrary : public MetalShaderLibrary { + public: + DynamicMetalShaderLibrary(const std::string& src) : MetalShaderLibrary(src) { + // Compile right away + getLibrary(); + } + ~DynamicMetalShaderLibrary() override; +}; + +} // namespace at::native::mps diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/OperationUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/OperationUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..4f8c3df538d3437774fa43e463fc2939311cfc3e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/OperationUtils.h @@ -0,0 +1,512 @@ +// Copyright © 2022 Apple Inc. + +#pragma once + +#include +#define TORCH_ASSERT_ONLY_METHOD_OPERATORS +#include +#include +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#include +#else +#include +#include +#include +#include +#endif + +#include + +@interface MPSGraph (PyTorchFixups) +- (MPSGraphTensor*)minimumWithNaNPropagationAndIntFallbackWithPrimaryTensor:(MPSGraphTensor*)primaryTensor + secondaryTensor:(MPSGraphTensor*)secondaryTensor + name:(NSString*)name; + +- (MPSGraphTensor*)maximumWithNaNPropagationAndIntFallbackWithPrimaryTensor:(MPSGraphTensor*)primaryTensor + secondaryTensor:(MPSGraphTensor*)secondaryTensor + name:(NSString*)name; +@end + +// Fwd declarations +namespace at { +struct TensorIteratorBase; +} +using namespace at::mps; + +namespace at::native::mps { + +void dispatch_sync_with_rethrow(dispatch_queue_t queue, void (^block)()); + +struct MPSScalar { + id getMTLBuffer() const { + return __builtin_bit_cast(id, buffer.get()); + } + + size_t size = 0; + ScalarType type = ScalarType::Undefined; + c10::DataPtr buffer; // stores MTLBuffer (frees buffer if MPSScalar instance goes out of scope) + union { + float f; // MPS doesn't support 'double' + at::Half h; + int64_t i; + bool b; + c10::complex cf; + c10::complex ch; + at::BFloat16 bf16; + } value{}; +}; + +void runMPSGraph(MPSStream* mpsStream, MPSGraph* mpsGraph, NSDictionary* feeds, NSDictionary* results); + +MPSDataType getMPSDataType(ScalarType scalar_type); +static inline MPSDataType getMPSDataType(const TensorBase& t) { + return getMPSDataType(t.scalar_type()); +} +MPSDataType getMPSScalarType(ScalarType scalar_type); +static inline MPSDataType getMPSScalarType(const TensorBase& t) { + return getMPSScalarType(t.scalar_type()); +} +MPSScalar getMPSScalar(const Scalar& scalar, ScalarType type); +std::string getMPSTypeString(ScalarType scalar_type, bool short_name = false); +static inline std::string getMPSTypeString(const TensorBase& t, bool short_name = false) { + return getMPSTypeString(t.scalar_type(), short_name); +} +std::string scalarToMetalTypeString(const c10::ScalarType& scalar_type); +static inline std::string scalarToMetalTypeString(const TensorBase& t) { + return scalarToMetalTypeString(t.scalar_type()); +} +NSArray* getTensorAxes(const TensorBase& t); +NSArray* getTensorAxes(const IntArrayRef& sizes, at::OptionalIntArrayRef dim); +std::string getMPSShapeString(MPSShape* shape); +std::string getTensorsStringKey(const TensorList& tensors, bool short_dtype = true, bool exclude_shape = false); +std::string getArrayRefString(const IntArrayRef s); +// use has_storage() on the returned tensor to determine if src actually is a view +Tensor gatherViewTensor(const Tensor& src, Tensor& dst); +Tensor& scatterViewTensor(const Tensor& src, Tensor& output); +MPSGraphTensor* castToIHFTypes(MPSGraph* mpsGraph, + MPSGraphTensor* inputTensor, + const TensorBase& input, + bool includesInt64 = false); +MPSGraphTensor* castFromIHFTypes(MPSGraph* mpsGraph, + MPSGraphTensor* inputTensor, + const TensorBase& input, + bool includesInt64 = false); + +MPSNDArray* getMPSNDArray(const TensorBase& t, const IntArrayRef& sizes = {}, const IntArrayRef& strides = {}); +MPSNDArray* getMPSNDArray(const TensorBase& t, MPSShape* sizes = nil, MPSShape* strides = nil); +// The MPSShape could vary based on memory format +Tensor getTensorView(const Tensor& t, MPSShape* shape); +MPSShape* getMPSShape(const TensorBase& t, c10::MemoryFormat memory_format = MemoryFormat::Contiguous); +MPSShape* getMPSShape(IntArrayRef sizes, c10::MemoryFormat memory_format = MemoryFormat::Contiguous); + +static inline id getMTLBufferStorage(const TensorBase& tensor) { + return __builtin_bit_cast(id, tensor.storage().data()); +} + +class Placeholder { + public: + Placeholder() : _placeholder(nullptr), _value(nullptr), _tensor(Tensor()) {} + Placeholder(MPSGraphTensor* mpsGraphTensor) : _placeholder(mpsGraphTensor), _value(nullptr), _tensor(Tensor()) {} + Placeholder(MPSGraphTensor* mpsGraphTensor, MPSNDArray* mpsNDArray); + Placeholder(MPSGraphTensor* mpsGraphTensor, + const Tensor& self, + MPSShape* mpsShape = nullptr, + bool gatherTensorData = true, + MPSDataType dataType = MPSDataTypeInvalid, + bool useMPSStridedAPI = true); + MPSGraphTensor* getMPSGraphTensor() { + return _placeholder; + } + MPSGraphTensorData* getMPSGraphTensorData() { + return _value; + } + bool isIntermediate() { + return _value == nullptr; + } + + private: + MPSGraphTensor* _placeholder; + MPSGraphTensorData* _value; + Tensor _tensor; +}; + +void resize_tensor(Tensor* output); +Tensor wrapped_scalar_tensor_mps(const Scalar& scalar, const Device device); +MPSGraphTensor* convertNHWCtoNCHW(MPSGraph* mpsGraph, MPSGraphTensor* tensor); +MPSGraphTensor* castMPSTensor(MPSGraph* mpsGraph, MPSGraphTensor* tensor, ScalarType toType); +MPSGraphTensor* castMPSTensor(MPSGraph* mpsGraph, MPSGraphTensor* tensor, MPSDataType toType); +MPSGraphTensorData* getMPSGraphTensorData(MPSGraph* mpsGraph, MPSStream* mpsStream, const TensorBase& tensor); +MPSGraphTensorData* getMPSGraphTensorFromScalar(MPSStream* mpsStream, MPSScalar& scalar); + +MPSGraph* make_mps_graph(); +void printTensorNDArray(const TensorBase& t); +MPSNDArray* ndArrayFromTensor(const TensorBase& tensor, MPSShape* shape, MPSDataType mpsType); + +MPSGraphTensor* mpsGraphUnrankedPlaceHolder(MPSGraph* mpsGraph, MPSDataType dataType); +MPSGraphTensor* mpsGraphRankedPlaceHolder(MPSGraph* mpsGraph, MPSDataType dataType, MPSShape* mpsShape); +MPSGraphTensor* mpsGraphRankedPlaceHolder(MPSGraph* mpsGraph, const TensorBase& tensor); +MPSGraphTensor* mpsGraphScalarPlaceHolder(MPSGraph* mpsGraph, MPSDataType dataType); +MPSGraphTensor* mpsGraphScalarPlaceHolder(MPSGraph* mpsGraph, const Scalar& scalar); + +string get_mem_format_string(c10::MemoryFormat memory_format); + +using MPSCacheKey = uint64_t; + +// derive this class to cache a graph and its inputs/outputs +// can be used to store any NSObject +struct MPSCachedGraph { + MPSCachedGraph(NSObject* object) : _object([object retain]) {} + virtual ~MPSCachedGraph() { + [_object release]; + _object = nullptr; + } + + template + inline T* as() { + return static_cast(this); + } + + MPSGraph* graph() const { + return (MPSGraph*)_object; + } + NSObject* object() const { + return _object; + } + + private: + NSObject* _object = nullptr; +}; + +struct MPSUnaryCachedGraph : public MPSCachedGraph { + MPSUnaryCachedGraph(MPSGraph* graph) : MPSCachedGraph(graph) {} + MPSGraphTensor* inputTensor_ = nil; + MPSGraphTensor* outputTensor_ = nil; +}; + +struct MPSUnaryGradCachedGraph : public MPSCachedGraph { + MPSUnaryGradCachedGraph(MPSGraph* graph) : MPSCachedGraph(graph) {} + MPSGraphTensor* gradOutputTensor_ = nil; + MPSGraphTensor* inputTensor_ = nil; + MPSGraphTensor* outputTensor_ = nil; // some backward input is actually the forward's output + MPSGraphTensor* gradInputTensor_ = nil; +}; + +struct MPSBinaryCachedGraph : public MPSCachedGraph { + MPSBinaryCachedGraph(MPSGraph* graph) : MPSCachedGraph(graph) {} + MPSGraphTensor* inputTensor_ = nil; + MPSGraphTensor* otherTensor_ = nil; + MPSGraphTensor* outputTensor_ = nil; +}; + +struct MPSBinaryGradCachedGraph : public MPSCachedGraph { + MPSBinaryGradCachedGraph(MPSGraph* graph) : MPSCachedGraph(graph) {} + MPSGraphTensor* gradOutputTensor_ = nil; + MPSGraphTensor* inputTensor_ = nil; + MPSGraphTensor* otherTensor_ = nil; + MPSGraphTensor* gradInputTensor_ = nil; +}; + +// TODO: Improve the overall design of MPSGraphCache. +// https://github.com/pytorch/pytorch/issues/77176 +// Cache holding various keys mapped to graphs +struct MPSGraphCache { + typedef MPSCachedGraph* (^CreateCachedGraphBlock)(); + + struct CacheEntry { + CacheEntry(const std::string& key, MPSCachedGraph* cachedGraph) : cachedGraph_(cachedGraph), key_(key) {} + MPSCachedGraph* cachedGraph_ = nullptr; + std::string key_; + }; + + public: + static MPSGraphCache* getInstance() { + if (_instance_cache == nullptr) { + _instance_cache = new MPSGraphCache(); + } + return _instance_cache; + } + + ~MPSGraphCache() { + dispatch_release(serialQueue_); + + for (const auto& i : cache_) { + delete i.second.cachedGraph_; + } + } + + // Disallow the copy constructor and operator= functions + MPSGraphCache(const MPSGraphCache&) = delete; + void operator=(const MPSGraphCache&) = delete; + + MPSCachedGraph* CreateCachedGraph(const std::string& key, CreateCachedGraphBlock createCacheBlock) { + __block MPSCachedGraph* cachedGraph = nil; + + MPSCacheKey hash = std::hash{}(key); + + dispatch_sync_with_rethrow(serialQueue_, ^() { + // verify the cached entry doesn't already exist + if (cache_.count(hash) != 0) { + auto& entry = cache_.at(hash); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(key == entry.key_, "Key collision in the MPS cached graph!\n"); + cachedGraph = entry.cachedGraph_; + } else { + cachedGraph = createCacheBlock(); + CacheEntry entry(key, cachedGraph); + cache_.emplace(hash, entry); + profileCachedGraph(entry); + } + }); + return cachedGraph; + } + + template + inline T* CreateCachedGraphAs(const std::string& key, CreateCachedGraphBlock createCacheBlock) { + return static_cast(CreateCachedGraph(key, createCacheBlock)); + } + + MPSCachedGraph* LookUp(const std::string& key) const { + __block MPSCachedGraph* cachedGraph = nullptr; + + MPSCacheKey hash = std::hash{}(key); + + dispatch_sync(serialQueue_, ^() { + if (cache_.count(hash) != 0) { + auto& entry = cache_.at(hash); + TORCH_INTERNAL_ASSERT_DEBUG_ONLY(key == entry.key_, "Key collision in the MPS cached graph!\n"); + cachedGraph = entry.cachedGraph_; + profileCachedGraph(entry); + } + }); + return cachedGraph; + } + + template + inline T* LookUpAs(const std::string& key) const { + return static_cast(LookUp(key)); + } + + private: + MPSGraphCache() { + serialQueue_ = dispatch_queue_create("cache queue", DISPATCH_QUEUE_SERIAL); + } + // this is defined in OperationUtils.mm to not include + // MPSProfiler.h in header OperationUtils.h + void profileCachedGraph(const CacheEntry& cacheEntry) const; + + static MPSGraphCache* _instance_cache; + std::unordered_map cache_; + dispatch_queue_t serialQueue_ = nullptr; +}; + +// Common template for creating graph with a specified cache if missing +template +inline T* LookUpOrCreateCachedGraph(const std::string& key, std::function instantiate) { + auto cache_ = MPSGraphCache::getInstance(); + if (auto rc = cache_->LookUpAs(key)) { + return rc; + } + return cache_->CreateCachedGraphAs(key, ^mps::MPSCachedGraph*() { + T* newCachedGraph = nil; + @autoreleasepool { + // Initialize graph + auto mpsGraph = mps::make_mps_graph(); + newCachedGraph = new T(mpsGraph); + instantiate(mpsGraph, newCachedGraph); + } + return newCachedGraph; + }); +} + +// Common math operations +MPSGraphTensor* log1p(MPSGraph* mpsGraph, MPSGraphTensor* inputTensor); + +#define MPS_CHECK_INT64_OP_SUPPORTED(input_tensor, mac_os_13_3_plus, op_name) \ + if (!mac_os_13_3_plus && input_tensor.scalar_type() == kLong) { \ + TORCH_WARN_ONCE( \ + "MPS: no support for int64 for ", \ + op_name, \ + ", downcasting to a smaller data type (int32/float32). Native support for int64 has been added in macOS 13.3."); \ + } + +/** + * Returns distance from lowest to highest element offset in given tensor. + */ +size_t compute_storage_numel_distance(const TensorBase& t); + +/** + * Checks whether tensor is mapped to a contiguous area in the storage. + */ +inline bool is_dense_in_storage(const TensorBase& t) { + return compute_storage_numel_distance(t) == static_cast(t.numel()); +} + +template , encoder_t> || + std::is_same_v, encoder_t>>> +static inline void mtl_setBuffer(encoder_t encoder, const TensorBase& t, unsigned idx) { + if (C10_UNLIKELY(t.device().type() == kCPU)) { + if constexpr (std::is_same_v, encoder_t>) { + TORCH_CHECK(t.dim() == 0, "Passed CPU tensor to MPS op"); + [encoder setBytes:t.storage().data() length:t.element_size() atIndex:idx]; + } else { + TORCH_CHECK(false, "Passed CPU tensor to MPS op"); + } + return; + } + [encoder setBuffer:getMTLBufferStorage(t) offset:t.storage_offset() * t.element_size() atIndex:idx]; +} + +// Implementation of setBytes for containers vs trivially copiable types must be separate +// Containers like `std::array` could have been uploaded directly, but `c10::ArrayRef`, +// while trivially copiable, includes padding which if copied as Metal shader parameters +// might overwrite other values +template < + typename T, + typename = std::enable_if_t || std::is_same_v || + (std::is_class_v && std::is_trivially_copyable_v && !detail::has_size_type_v)>> +static inline void mtl_setBytes(id encoder, const T val, unsigned idx) { + [encoder setBytes:&val length:sizeof(T) atIndex:idx]; +} + +template >> +static inline void mtl_setBytes(id encoder, const Container& values, unsigned idx) { + [encoder setBytes:values.data() length:sizeof(typename Container::value_type) * values.size() atIndex:idx]; +} + +static inline void mtl_setBytes(id encoder, const MPSScalar& s, unsigned idx) { + [encoder setBytes:&s.value length:s.size atIndex:idx]; +} + +namespace detail { +template +inline void mtl_setArg(id encoder, const T& val, unsigned idx) { + mtl_setBytes(encoder, val, idx); +} + +inline void mtl_setArg(id encoder, id val, unsigned idx) { + [encoder setBuffer:val offset:0 atIndex:idx]; +} + +template <> +inline void mtl_setArg(id encoder, const Tensor& val, unsigned idx) { + mtl_setBuffer(encoder, val, idx); +} + +template <> +inline void mtl_setArg(id encoder, const std::optional& val, unsigned idx) { + if (val.has_value()) { + mtl_setBuffer(encoder, val.value(), idx); + } +} + +template <> +inline void mtl_setArg(id encoder, const TensorBase& val, unsigned idx) { + mtl_setBuffer(encoder, val, idx); +} +// MPS does not support doubles, so cast it down to float before passing as an argument +template <> +inline void mtl_setArg(id encoder, const double& val, unsigned idx) { + float val_f = static_cast(val); + mtl_setBytes(encoder, val_f, idx); +} +} // namespace detail + +template +static inline void mtl_setArgs(id encoder, const T& val) { + detail::mtl_setArg(encoder, val, idx); +} + +template +static inline void mtl_setArgs(id encoder, const T& val, Args&&... args) { + detail::mtl_setArg(encoder, val, idx); + mtl_setArgs(encoder, std::forward(args)...); +} + +static inline void mtl_dispatch1DJob(id encoder, + id cplState, + NSUInteger length) { + static_assert(sizeof(NSUInteger) == sizeof(uint64_t)); + const auto maxThreadsPerGroup = [cplState maxTotalThreadsPerThreadgroup]; + auto size = MTLSizeMake(length, 1, 1); + auto threadGroupSize = MTLSizeMake(std::min(maxThreadsPerGroup, length), 1, 1); + [encoder dispatchThreads:size threadsPerThreadgroup:threadGroupSize]; +} + +id generateKernelDataOffsets(id commandEncoder, + const TensorIteratorBase& iter, + bool use_64bit_index = false); + +inline NSDictionary* dictionaryFromPlaceholders(Placeholder& p1) { + return @{p1.getMPSGraphTensor() : p1.getMPSGraphTensorData()}; +} + +inline NSDictionary* dictionaryFromPlaceholders(Placeholder& p1, Placeholder& p2) { + return @{ + p1.getMPSGraphTensor() : p1.getMPSGraphTensorData(), + p2.getMPSGraphTensor() : p2.getMPSGraphTensorData(), + }; +} + +inline NSDictionary* dictionaryFromPlaceholders(Placeholder& p1, Placeholder& p2, Placeholder& p3) { + return @{ + p1.getMPSGraphTensor() : p1.getMPSGraphTensorData(), + p2.getMPSGraphTensor() : p2.getMPSGraphTensorData(), + p3.getMPSGraphTensor() : p3.getMPSGraphTensorData(), + }; +} + +inline NSDictionary* dictionaryFromPlaceholders(Placeholder& p1, Placeholder& p2, Placeholder& p3, Placeholder& p4) { + return @{ + p1.getMPSGraphTensor() : p1.getMPSGraphTensorData(), + p2.getMPSGraphTensor() : p2.getMPSGraphTensorData(), + p3.getMPSGraphTensor() : p3.getMPSGraphTensorData(), + p4.getMPSGraphTensor() : p4.getMPSGraphTensorData(), + }; +} + +inline void runMPSGraph(MPSStream* stream, MPSGraph* graph, NSDictionary* feeds, Placeholder& result) { + runMPSGraph(stream, graph, feeds, dictionaryFromPlaceholders(result)); +} + +inline bool supportsComplex() { + return is_macos_13_or_newer(MacOSVersion::MACOS_VER_14_0_PLUS); +} + +// MPS yet to support double types, but starting from MacOS 14, supports bfloat16 +inline bool supportedFloatingType(ScalarType dtype) { + return dtype == kFloat || dtype == kHalf || dtype == kBFloat16; +} + +inline bool supportedFloatingType(const TensorBase& t) { + return supportedFloatingType(t.scalar_type()); +} + +inline bool supportedFloatingOrComplexType(ScalarType dtype) { + if (dtype == kComplexFloat || dtype == kComplexHalf) { + return supportsComplex(); + } + return supportedFloatingType(dtype); +} +inline bool supportedFloatingOrComplexType(const TensorBase& t) { + return supportedFloatingOrComplexType(t.scalar_type()); +} + +inline void checkSupportsBFloat16() { + TORCH_CHECK_TYPE(is_macos_13_or_newer(MacOSVersion::MACOS_VER_14_0_PLUS), + "MPS bfloat16 type is supported on MacOS 14.0 or newer."); +} + +inline bool needsGather(const TensorBase& t) { + static const bool is_macOS_15_0_or_newer = is_macos_13_or_newer(MacOSVersion::MACOS_VER_15_0_PLUS); + return !is_macOS_15_0_or_newer && (!t.is_contiguous() || t.storage_offset()); +} + +} // namespace at::native::mps diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/TensorFactory.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/TensorFactory.h new file mode 100644 index 0000000000000000000000000000000000000000..22a49c1106f278cc6eb54fed59547f00551c8246 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/mps/TensorFactory.h @@ -0,0 +1,14 @@ +// Copyright © 2022 Apple Inc. + +#define AT_DISPATCH_MPS_TYPES(TYPE, NAME, ...) \ + AT_DISPATCH_SWITCH( \ + TYPE, \ + NAME, \ + AT_DISPATCH_CASE(at::ScalarType::Float, __VA_ARGS__) AT_DISPATCH_CASE( \ + at::ScalarType::Half, \ + __VA_ARGS__) AT_DISPATCH_CASE(at::ScalarType::BFloat16, __VA_ARGS__) \ + AT_DISPATCH_CASE(at::ScalarType::Long, __VA_ARGS__) \ + AT_DISPATCH_CASE(at::ScalarType::Int, __VA_ARGS__) \ + AT_DISPATCH_CASE(at::ScalarType::Short, __VA_ARGS__) \ + AT_DISPATCH_CASE(at::ScalarType::Char, __VA_ARGS__) \ + AT_DISPATCH_CASE(at::ScalarType::Byte, __VA_ARGS__)) diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorBinaryOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorBinaryOps.h new file mode 100644 index 0000000000000000000000000000000000000000..c391efd7173e5d7e227f3a6c89492af0eddbac1a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorBinaryOps.h @@ -0,0 +1,18 @@ +#pragma once + +#include +#include + +namespace at::native { + +enum class NESTED_DENSE_OP : uint8_t { ADD, MUL }; + +using nested_dense_elementwise_fn = void (*)( + Tensor& result, + const Tensor& self, + const Tensor& other, + const NESTED_DENSE_OP& op); + +DECLARE_DISPATCH(nested_dense_elementwise_fn, nested_dense_elementwise_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorMath.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorMath.h new file mode 100644 index 0000000000000000000000000000000000000000..d0a189a78013a099054fc8df9957f085bc8afd96 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorMath.h @@ -0,0 +1,79 @@ +#pragma once + +#include +#include +#include + +namespace at::native { + +TORCH_API Tensor NestedTensor_to_padded_tensor_generic( + const Tensor& t, + double padding, + OptionalIntArrayRef output_size); + +template +Tensor map_nt(const Tensor& nt, Func f) { + auto* nt_impl = get_nested_tensor_impl(nt); + const auto& sizes = nt_impl->get_nested_sizes(); + return at::detail::make_tensor(f(nt_impl->get_buffer()), sizes); +} +template +Tensor map_nt_binary(const Tensor& nt_1, const Tensor& nt_2, Func f){ + auto* nt_impl_1 = get_nested_tensor_impl(nt_1); + auto* nt_impl_2 = get_nested_tensor_impl(nt_2); + const auto& sizes = nt_impl_1->get_nested_sizes(); + return at::detail::make_tensor(f(nt_impl_1->get_buffer(), nt_impl_2->get_buffer()), sizes); +} + +C10_ALWAYS_INLINE std::pair _check_nested_layer_norm_inputs( + const NestedTensorImpl& input, + IntArrayRef normalized_shape, + const Tensor& weight /* optional */, + const Tensor& bias /* optional */) { + + const size_t normalized_ndim = normalized_shape.size(); + TORCH_CHECK( + normalized_ndim >= 1, + "Expected normalized_shape to be at least 1-dimensional, i.e., ", + "containing at least one element, but got normalized_shape = ", + normalized_shape); + TORCH_CHECK( + !weight.defined() || weight.sizes().equals(normalized_shape), + "Expected weight to be of same shape as normalized_shape, but got ", + "weight of shape ", + weight.sizes(), + " and normalized_shape = ", + normalized_shape); + TORCH_CHECK( + !bias.defined() || bias.sizes().equals(normalized_shape), + "Expected bias to be of same shape as normalized_shape, but got ", + "bias of shape ", + bias.sizes(), + " and normalized_shape = ", + normalized_shape); + + // Check that the normalized_shape has the exact same sizes as the last dimensions from the NestedTensor input + // Also, compute M and N considering the idiosyncracies of NestedTensors + int64_t N = 1; + for (const auto i: c10::irange(normalized_ndim)) { + TORCH_CHECK( + input.opt_size(-normalized_ndim + i).has_value(), + "normalized_shape extends into irregular dimensions for the nested tensor" + ); + TORCH_CHECK( + normalized_shape[i] == input.opt_size(-normalized_ndim + i), + "The shape at dimension ", + i, + "of normalized_shape doesn't match the input" + ); + N *= normalized_shape[i]; + } + + const int64_t M = input.numel() / N; + + return std::make_pair(M, N); +} + +Tensor reshape_nested(const Tensor& self, IntArrayRef proposed_shape); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorTransformerFunctions.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorTransformerFunctions.h new file mode 100644 index 0000000000000000000000000000000000000000..47119fdd4a1ab10cd7ef3e73491afdb03b5b3838 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorTransformerFunctions.h @@ -0,0 +1,103 @@ +/** + * Transformer-specific NestedTensor utility functions. + * + * Not co-located with NestedTensor core code yet because they only + * support specific cases needed in transformers. + */ +#pragma once + +#include + +#include +#include + +namespace c10 { +class Scalar; +} // namespace c10 + +namespace at { +class Tensor; +namespace native { +struct NestedTensorImpl; + +// Requires that self is a contiguous NestedTensor, other is not a +// NestedTensor, self.dim() == 3, and other.dim() == 2. Also, self +// must have a consistent last dimension across its included Tensors +// and that dimension must match other.size(0). +Tensor NestedTensor_matmul(const Tensor& self, const Tensor& other); + +// Requires that mat1 is a contiguous NestedTensor, self & mat2 are +// not NestedTensors, mat1.dim() == 3, mat2.dim() == 2, and that mat1 +// has a consistent last dimension across its included Tensors that +// matches mat2.size(0). +Tensor NestedTensor_times_Tensor_plus_Tensor_addmm( + const Tensor& self, + const Tensor& mat1, + const Tensor& mat2, + const c10::Scalar& beta, + const c10::Scalar& alpha, + std::optional use_gelu = std::nullopt); + +Tensor NestedTensor_add_NestedTensor_in_place( + const Tensor& self, + const Tensor& other); + +TORCH_API Tensor NestedTensor_batch_offsets_from_size_tensor( + const Tensor& sizes, + int64_t extra_elements); + +Tensor NestedTensor_from_padded_tensor_cpu( + const Tensor& padded, + const NestedTensorImpl& nt); + +TORCH_API Tensor NestedTensor_to_mask(const Tensor& nt, std::optional mask_dim, std::optional mask_dim_length); + +template +void remove_padding_kernelLauncher( + const T* input, + T* output, + const int* offsets, + const int* input_sizes, + const int* output_sizes, + int64_t output_dim, + const int64_t batch_size); + +template +void remove_padding_transform0213_kernelLauncher( + const T* input, + T* output, + const int* offsets, + const int* input_sizes, + const int* output_sizes, + int64_t output_dim, + const int64_t batch_size); + +template +void add_padding_kernelLauncher( + T* input, + T* output, + T padding_value, + const int* offsets, + const int* input_sizes, + int input_dim, + const std::vector& output_sizes, + const int batch_size, + const int output_batch_size); + +TORCH_API Tensor flash_attention_helper( + const Tensor& query, + const Tensor& key, + const Tensor& value, + double dropout_p, + bool need_attn_weights, + bool is_causal); + +TORCH_API std::tuple mem_efficient_helper_nested_unpacked( + const Tensor& query, + const Tensor& key, + const Tensor& value, + double dropout_p, + bool need_attn_weights, + bool is_causal); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorTransformerUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorTransformerUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..a9082a7dfa47c9f388f74af7fc137e27a40f639a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorTransformerUtils.h @@ -0,0 +1,40 @@ +#pragma once +#include + +namespace at::native::preprocessing { + +/** + * This function will take nested query, key, and value + * and will preprocess it in order to run with either + * the flash-attention or efficient-attention kernels. + * @return A tuple containing all the necessary data for running the fused + * kernels + */ +std::tuple +sdpa_nested_preprocessing( + const Tensor& query, + const Tensor& key, + const Tensor& value); + +/** + * This function will take nested query, key, and value, grad_out, and out + * and will preprocess it in order to run with either + * the flash-attention or efficient-attention kernels backwards. + * We use both functions to avoid having to do the same preprocessing + * for cumulative_sequence_length_q and cumulative_sequence_length_kv + * @return A tuple containing all the necessary data for running the fused + * kernels + */ +std::tuple +sdpa_nested_preprocessing_backward( + const at::Tensor& grad_out_, + const at::Tensor& query, + const at::Tensor& key, + const at::Tensor& value, + const at::Tensor& out, + const Tensor& cumulative_sequence_length_q, + const Tensor& cumulative_sequence_length_kv, + const int64_t max_seqlen_batch_q, + const int64_t max_seqlen_batch_kv); + +} // namespace at::native::preprocessing diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..6a66a7f43e820af24aa392626b304a6059b9900d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/nested/NestedTensorUtils.h @@ -0,0 +1,449 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS + +#include +#include +#else +#include +#include +#include +#include +#include +#include +#endif + +#include +#include +#include + +namespace at::native { +struct NestedTensorImpl; + +// The following functions are used to construct nested tensors from buffers and +// metadata. + +inline at::Tensor wrap_buffer(const at::Tensor& buffer, const at::Tensor& nested_sizes) { + TORCH_CHECK( + buffer.dim() == 1, + "Expected given buffer to be 1dim, but got ", + buffer.dim(), + " instead."); + TORCH_CHECK( + buffer.is_contiguous(), "Expected given buffer to be contiguous."); + return at::detail::make_tensor( + buffer, nested_sizes); +} + +// TODO: Figure out if we need a non-moving wrap_buffer() +inline at::Tensor wrap_buffer( + const at::Tensor& buffer, + at::Tensor nested_sizes, + at::Tensor nested_strides, + at::Tensor storage_offsets) { + TORCH_INTERNAL_ASSERT_DEBUG_ONLY( + buffer.is_contiguous(), "Given buffer must be contiguous."); + return at::detail::make_tensor( + buffer, + std::move(nested_sizes), + std::move(nested_strides), + std::move(storage_offsets)); +} + +inline at::Tensor get_buffer(const at::Tensor& tensor) { + return get_nested_tensor_impl(tensor)->get_buffer(); +} + +/** + * Create a new nested tensor that is a view of a base nested tensor + * + * create_view_tensor calls a specialized constructor that copies the + * keys from base onto the new view tensor being created. + * The storage is shared between the base and the returned view tensor + * + * All callers of this helper must: + * - Only return a view of the input + * - Must be explicit and define a derivative + * + * @param base Base tensor to construct view from. + * @param nested_sizes View tensors' sizes. + * @param nested_strides View tensors' strides. + * @param storage_offsets View tensors' offsets. + * @return A newly constructed view tensor + */ +inline at::Tensor create_nested_view_tensor( + const at::Tensor& base, + at::Tensor nested_sizes, + at::Tensor nested_strides, + at::Tensor storage_offsets) { + TORCH_INTERNAL_ASSERT( + base.is_nested(), + "This function can only be used to create nested tensor views"); + TORCH_INTERNAL_ASSERT( + c10::impl::tls_local_dispatch_key_set().excluded_.has( + c10::DispatchKey::AutogradFunctionality), + "Creating a non differentiable nested tensor view in a CompositeImplicit function is not allowed."); + return at::detail::make_tensor( + c10::TensorImpl::VIEW, + base, + std::move(nested_sizes), + std::move(nested_strides), + std::move(storage_offsets)); +} +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ + +// Helper functions for getting information about a nested tensor's shape. + +int64_t get_consistent_last_dim_of_nested_tensor(const NestedTensorImpl& nt); + +// The sizes of the underlying tensors +inline std::vector NestedTensor_get_sizes( + const NestedTensorImpl* self_ptr) { + int64_t ntensors = self_ptr->size(0); + std::vector sizes(ntensors); + if (ntensors == 0) { + return sizes; + } + const Tensor& sizemat = self_ptr->get_nested_sizes(); + int64_t orig_dim = sizemat.size(1); + // nesting scalars has empty sizes + if (orig_dim == 0) { + return sizes; + } + const int64_t* sizemat_ptr = sizemat.const_data_ptr(); + + for (const auto i : c10::irange(ntensors)) { + sizes[i] = IntArrayRef(sizemat_ptr, sizemat_ptr + orig_dim); + sizemat_ptr += orig_dim; + } + return sizes; +} + +TORCH_API std::vector NestedTensor_get_max_size( + const NestedTensorImpl& nt); + +std::vector NestedTensor_get_max_size_from_size_tensor( + const Tensor& sizes); + +inline std::vector NestedTensor_get_sizes(const at::Tensor& self) { + const NestedTensorImpl* self_ptr = get_nested_tensor_impl(self); + return NestedTensor_get_sizes(self_ptr); +} +// The strides of the underlying tensors +inline std::vector NestedTensor_get_strides( + const NestedTensorImpl* self_ptr) { + int64_t ntensors = self_ptr->size(0); + std::vector strides(ntensors); + if (ntensors == 0) { + return strides; + } + const Tensor& stridemat = self_ptr->get_nested_strides(); + int64_t orig_dim = stridemat.size(1); + // nesting scalars has empty strides + if (orig_dim == 0) { + return strides; + } + const int64_t* stridemat_ptr = stridemat.const_data_ptr(); + for (const auto i : c10::irange(ntensors)) { + strides[i] = IntArrayRef(stridemat_ptr, stridemat_ptr + orig_dim); + stridemat_ptr += orig_dim; + } + return strides; +} + +inline std::vector NestedTensor_get_strides( + const at::Tensor& self) { + const NestedTensorImpl* self_ptr = get_nested_tensor_impl(self); + return NestedTensor_get_strides(self_ptr); +} + +inline void check_numel_equals_buffer_size(const at::Tensor& self) { + auto self_impl = get_nested_tensor_impl(self); + TORCH_CHECK( + self.numel() == static_cast(self_impl->get_buffer_size()), + "Number of elements in nested tensor must match number of elements in buffer."); +} + +inline void check_numel_equals_buffer_size(const NestedTensorImpl* self_ptr) { + TORCH_CHECK( + self_ptr->numel() == static_cast(self_ptr->get_buffer_size()), + "Number of elements in nested tensor must match number of elements in buffer."); +} + +// Helper function to get size / stride / offset for a nested/normal tensor. +inline IntArrayRef get_size_for_index(const Tensor& tensor, int64_t i) { + if (tensor.is_nested()) { + std::vector tensor_sizes = + NestedTensor_get_sizes(get_nested_tensor_impl(tensor)); + return tensor_sizes[i]; + } else { + return tensor.sizes().slice(1); + } +} + +inline IntArrayRef get_stride_for_index(const Tensor& tensor, int64_t i) { + if (tensor.is_nested()) { + std::vector tensor_strides = + NestedTensor_get_strides(get_nested_tensor_impl(tensor)); + return tensor_strides[i]; + } else { + return tensor.strides().slice(1); + } +} + +inline int64_t get_offset_for_index(const Tensor& tensor, int64_t i) { + if (tensor.is_nested()) { + int64_t* offsets_ptr = get_nested_tensor_impl(tensor) + ->get_storage_offsets() + .data_ptr(); + return offsets_ptr[i]; + + } else { + int64_t offset = tensor.storage_offset(); + return offset + tensor.strides()[0] * i; + } +} +// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +// Data structures and functions for generically applying a function on a nested +// tensor. +namespace impl { + +template +struct NestedNode { + NestedNode() = delete; + explicit NestedNode(std::vector children) + : _is_leaf(false), _children(std::move(children)) {} + explicit NestedNode(TensorList children) + : _is_leaf(false), _children(children.vec()) {} + explicit NestedNode(T payload) + : _is_leaf(true), _payload(std::move(payload)) {} + NestedNode(const NestedNode&) = delete; + NestedNode& operator=(const NestedNode&) = delete; + NestedNode(NestedNode&&) noexcept = default; + NestedNode& operator=(NestedNode&&) noexcept = default; + ~NestedNode() = default; + inline bool is_leaf() const { + return _is_leaf; + } + inline size_t degree() const { + return _children.size(); + } + inline const std::vector unbind() const { + return _children; + } + inline T children(size_t i) const { + return _children[i]; + } + inline const T& payload() const { + return _payload; + } + inline T& payload() { + return _payload; + } + + private: + bool _is_leaf; + std::vector _children; + T _payload{}; +}; + +using TensorNode = NestedNode; + +template +class _map; + +template +class _map> { + public: + static A function_one(const F& fn, const Args&... nested_node) { + return fn(nested_node...); + } + static NestedNode function( + const F& fn, + const NestedNode&... nested_node) { + size_t degree = 0; + bool all_leaf = true; + c10::guts::tuple_map( + std::forward_as_tuple(nested_node...), [&all_leaf, °ree](auto n) { + all_leaf = all_leaf && (n.is_leaf()); + if (degree > 1 && n.degree() > 1) { + TORCH_CHECK( + degree == n.degree(), "NestedNodes must match in degree."); + } + if (n.degree() > degree) { + degree = n.degree(); + } + return nullptr; + }); + // All NestedNodes just wrap regular objects. + if (all_leaf) { + return NestedNode(std::forward(fn)(nested_node.payload()...)); + } + // Some NestedNodes wrap regular Tensors, some NestedTensors and some other + // types. + std::vector result; + for (size_t i = 0; i < degree; i++) { + auto children = c10::guts::tuple_map( + std::forward_as_tuple(nested_node...), [&i](auto a) { + static_assert( + c10::guts::is_instantiation_of::value, + "Internal error."); + // Broadcast regular arguments across NestedTensor constituents. + // This could be a Tensor, integer or anything else really. + if (a.is_leaf()) { + return a.payload(); + } + // Broadcast NestedTensors with one constituent. + if (a.degree() == 1 && !a.is_leaf()) { + return a.children(0); + } + TORCH_CHECK(a.degree() > 0, "Internal assert."); + return a.children(i); + }); + std::apply( + [&result, &fn](Args... filtered) { + result.emplace_back(function_one(fn, filtered...)); + }, + std::move(children)); + } + return NestedNode(std::move(result)); + } +}; + +// TODO: Add static assert to verify lambda arguments match nested_node types +template +static inline NestedNode< + typename c10::guts::infer_function_traits::type::return_type> +map(F&& fn, const NestedNode&... nested_node) { + return _map< + F, + typename c10::guts::infer_function_traits::type::return_type, + typename c10::guts::infer_function_traits::type::parameter_types>:: + function(std::forward(fn), nested_node...); +} + +inline TensorNode get_nested_tensor_structure(at::Tensor tensor) { + if (get_nested_tensor_impl_or_null(tensor) == nullptr) { + return TensorNode(std::move(tensor)); + } + return TensorNode(tensor.unbind()); +} + +inline Tensor wrap_tensor_node( + TensorNode tensor_node, + std::optional dtype, + std::optional layout, + std::optional device, + std::optional pin_memory) { + TORCH_CHECK( + !tensor_node.is_leaf(), "Expected TensorNode to wrap a list of Tensors."); + TensorOptions options_ = + TensorOptions().dtype(dtype).layout(layout).device(device).pinned_memory( + pin_memory); + if (tensor_node.degree() == 0) { + return wrap_buffer(ones({0}, dtype, layout, device), ones({})); + } + + // Fast path: if all tensors are on CPU, have contiguous memory, and the same + // dtype, copying can be done much faster. + bool all_tensors_cpu = true; + bool all_tensors_contiguous = true; + bool all_tensors_same_dtype = true; + auto first_dtype = tensor_node.children(0).dtype(); + std::vector start_offsets(tensor_node.degree()); + start_offsets[0] = 0; + long total_size = 0; + for (const auto i : c10::irange(tensor_node.degree())) { + all_tensors_cpu = all_tensors_cpu && tensor_node.children(i).is_cpu(); + all_tensors_contiguous = + all_tensors_contiguous && tensor_node.children(i).is_contiguous(); + all_tensors_same_dtype = all_tensors_same_dtype && + (first_dtype == tensor_node.children(i).dtype()); + if (!(all_tensors_cpu && all_tensors_contiguous && + all_tensors_same_dtype)) { + break; + } + if (i > 0) { + start_offsets[i] = + start_offsets[i - 1] + tensor_node.children(i - 1).numel(); + } + total_size += tensor_node.children(i).numel(); + } + + TensorOptions options; + Tensor nt_buffer, nt_sizes; + if (all_tensors_cpu && all_tensors_contiguous && all_tensors_same_dtype) { + nt_buffer = at::empty({total_size}, tensor_node.children(0).options()); + nt_sizes = at::empty( + {static_cast(tensor_node.degree()), + static_cast(tensor_node.children(0).sizes().size())}, + TensorOptions().dtype(kLong)); + AT_DISPATCH_ALL_TYPES_AND_COMPLEX_AND3( + at::ScalarType::Half, + at::ScalarType::Bool, + at::ScalarType::BFloat16, + c10::typeMetaToScalarType(first_dtype), + "create_nt_buffer", + [&]() { + at::parallel_for( + 0, tensor_node.degree(), 1, [&](int64_t begin, int64_t end) { + for (int64_t i = begin; i < end; ++i) { + // Only try copying memory if there is more than 0 elements + // for a certain tensor + if (tensor_node.children(i).numel() > 0) { + memcpy( + nt_buffer.mutable_data_ptr() + start_offsets[i], + tensor_node.children(i).const_data_ptr(), + tensor_node.children(i).numel() * sizeof(scalar_t)); + } + } + }); + }); + long sizes_offset = 0; + for (size_t i = 0; i < tensor_node.degree(); ++i) { + auto tensor_sizes = tensor_node.children(i).sizes(); + for (int64_t tensor_size : tensor_sizes) { + nt_sizes.mutable_data_ptr()[sizes_offset++] = tensor_size; + } + } + options = nt_buffer.options().merge_in(options_); + } else { // Slow path + std::vector flat_tensors; + std::vector sizes; + for (const auto i : c10::irange(tensor_node.degree())) { + flat_tensors.push_back(tensor_node.children(i).reshape(-1).contiguous()); + sizes.push_back( + tensor(c10::IntArrayRef(tensor_node.children(i).sizes()))); + } + options = flat_tensors[0].options().merge_in(options_); + nt_buffer = at::cat(flat_tensors); + nt_sizes = at::native::stack(sizes); + } + + return wrap_buffer(nt_buffer.to(options), nt_sizes); +} + +} // namespace impl + +// This function is meant to ease rapid operator coverage for +// NestedTensor kernels. It is not meant to be efficient. Use it judiciously. +template +inline at::Tensor map_nested_tensor(F&& fn, A... a) { + return wrap_tensor_node( + impl::map(std::forward(fn), impl::get_nested_tensor_structure(a)...), + std::nullopt, + std::nullopt, + std::nullopt, + std::nullopt); +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/AffineQuantizer.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/AffineQuantizer.h new file mode 100644 index 0000000000000000000000000000000000000000..93af7669e117025784d5bf9f8f30e1e5a8a9458a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/AffineQuantizer.h @@ -0,0 +1,128 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::native { + +TORCH_API Tensor& quantize_tensor_per_tensor_affine( + const Tensor& rtensor, + Tensor& qtensor, + double scale, + int64_t zero_point); +TORCH_API Tensor& quantize_tensor_per_channel_affine( + const Tensor& rtensor, + Tensor& qtensor, + const Tensor& scales, + Tensor zero_points, + int64_t axis); + +TORCH_API Tensor& quantize_tensor_per_channel_float_qparams( + const Tensor& rtensor, + Tensor& qtensor, + const Tensor& scales, + const Tensor& zero_points, + int64_t axis); + +TORCH_API Tensor& dequantize_tensor_per_tensor_affine( + const Tensor& qtensor, + Tensor& rtensor, + double scale, + int64_t zero_point); +TORCH_API Tensor& dequantize_tensor_per_channel_affine( + const Tensor& qtensor, + Tensor& rtensor, + const Tensor& scales, + Tensor zero_points, + int64_t axis); +TORCH_API Tensor& dequantize_tensor_per_channel_float_qparams( + const Tensor& qtensor, + Tensor& rtensor, + const Tensor& scales, + const Tensor& zero_points, + int64_t axis); + +using quantize_tensor_per_tensor_affine_fn = + void (*)(const Tensor& rtensor, Tensor& qtensor, double scale, int64_t zero_point); + +using quantize_tensor_per_channel_affine_fn = void (*)( + const Tensor& rtensor, + Tensor& qtensor, + const Tensor& scales, + const Tensor& zero_points, + int64_t axis); + +using quantize_tensor_per_channel_float_qparams_fn = void (*)( + const Tensor& rtensor, + Tensor& qtensor, + const Tensor& scales, + const Tensor& zero_points, + int64_t axis); + +using dequantize_tensor_per_tensor_affine_fn = + void (*)(const Tensor& qtensor, Tensor& rtensor, double scale, int64_t zero_point); + +using dequantize_tensor_per_channel_affine_fn = void (*)( + const Tensor& qtensor, + Tensor& rtensor, + const Tensor& scales, + const Tensor& zero_points, + int64_t axis); + +using dequantize_tensor_per_channel_float_qparams_fn = void (*)( + const Tensor& qtensor, + Tensor& rtensor, + const Tensor& scales, + const Tensor& zero_points, + int64_t axis); + +using quantize_tensor_per_tensor_affine_sub_byte_fn = + void (*)(const Tensor& rtensor, Tensor& qtensor, float scale, float zero_point); + +using dequantize_tensor_per_tensor_affine_sub_byte_fn = + void (*)(const Tensor& qtensor, Tensor& rtensor, float scale, float zero_point); + +DECLARE_DISPATCH( + quantize_tensor_per_tensor_affine_fn, + quantize_tensor_per_tensor_affine_stub) +DECLARE_DISPATCH( + quantize_tensor_per_channel_affine_fn, + quantize_tensor_per_channel_affine_stub) +DECLARE_DISPATCH( + quantize_tensor_per_channel_float_qparams_fn, + quantize_tensor_per_channel_float_qparams_stub) + +DECLARE_DISPATCH( + dequantize_tensor_per_tensor_affine_fn, + dequantize_tensor_per_tensor_affine_stub) +DECLARE_DISPATCH( + dequantize_tensor_per_channel_affine_fn, + dequantize_tensor_per_channel_affine_stub) +DECLARE_DISPATCH( + dequantize_tensor_per_channel_float_qparams_fn, + dequantize_tensor_per_channel_float_qparams_stub) + +DECLARE_DISPATCH( + quantize_tensor_per_tensor_affine_sub_byte_fn, + quantize_tensor_per_tensor_affine_sub_byte_stub) + +DECLARE_DISPATCH( + dequantize_tensor_per_tensor_affine_sub_byte_fn, + dequantize_tensor_per_tensor_affine_sub_byte_stub) + +template +TORCH_API Tensor quantize_tensor( + Tensor rtensor, + Tensor qtensor, + double scale, + int64_t zero_point); +template +TORCH_API Tensor dequantize_tensor( + Tensor qtensor, + Tensor rtensor, + double scale, + int64_t zero_point); + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/AffineQuantizerBase.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/AffineQuantizerBase.h new file mode 100644 index 0000000000000000000000000000000000000000..a0cfafdb99054a4f68370934c78005367799c10d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/AffineQuantizerBase.h @@ -0,0 +1,45 @@ +#pragma once +#include +#include + +namespace at::native { + +// Quantize a float value into a uint value given scale and zero_point +template +TORCH_API T quantize_val(double scale, int64_t zero_point, float value); +// TODO combine this with quantize_val once the numerics for ARM are aligned +// with it +template +T quantize_val_arm( + const float scale, + const int32_t zero_point, + const float value); +template +void quantize_vec( + double scale, + int64_t zero_point, + const float* src, + T* dst, + size_t count = 8); +template +TORCH_API float dequantize_val(double scale, int64_t zero_point, T value); +template +TORCH_API float dequantize_vec( + double scale, + int64_t zero_point, + const T* src, + float* dst, + size_t count = 8); +template +TORCH_API DST_T requantize_val(double, int64_t, double, int64_t, SRC_T src); + +// Given a multiplier and a zero_point, requantize int32_t computed values back +// to quantized values. See comment above +// make_per_tensor_affine_quantizer function for the usage of int64_t +template +TORCH_API DST_T +requantize_from_int(double multiplier, int64_t zero_point, int64_t src); + +int quantize_val_float_qparams(float scale, float zero_point, float value, int qmin, int qmax); + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/ConvUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/ConvUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..6f8ff918c1d2f3e421922650161aaa41eda9545f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/ConvUtils.h @@ -0,0 +1,62 @@ +#pragma once +#include +#include + +namespace at::native::quantized { +namespace { +// MakeConvOutputShape used from both CPU and CUDA libraries +// and exporting symbol from torch_cpu would probably take more storage +// than duplicating implementation which likely be inlined away +template +at::SmallVector MakeConvOutputShape( + int N, // mini-batch + int M, // output channels + const std::array& input_image_shape, + const std::vector& kernel, + const torch::List& stride, + const torch::List& padding, + const torch::List& dilation); + +#if defined(USE_CUDA) || defined(USE_PYTORCH_QNNPACK) +template <> +at::SmallVector MakeConvOutputShape<2>( + int N, // mini-batch + int M, // output channels + const std::array& input_image_shape, + const std::vector& kernel, + const at::List& stride, + const at::List& padding, + const at::List& dilation) { + const int H = input_image_shape[0]; + const int W = input_image_shape[1]; + const int64_t Y_H = + (H + 2 * padding[0] - dilation[0] * (kernel[0] - 1) - 1) / stride[0] + 1; + const int64_t Y_W = + (W + 2 * padding[1] - dilation[1] * (kernel[1] - 1) - 1) / stride[1] + 1; + return {N, M, Y_H, Y_W}; +} + +template <> +at::SmallVector MakeConvOutputShape<3>( + int N, // mini-batch + int M, // output channels + const std::array& input_image_shape, + const std::vector& kernel, + const at::List& stride, + const at::List& padding, + const torch::List& dilation) { + const int D = input_image_shape[0]; + const int H = input_image_shape[1]; + const int W = input_image_shape[2]; + const int64_t Y_D = + (D + 2 * padding[0] - dilation[0] * (kernel[0] - 1) - 1) / stride[0] + 1; + const int64_t Y_H = + (H + 2 * padding[1] - dilation[1] * (kernel[1] - 1) - 1) / stride[1] + 1; + const int64_t Y_W = + (W + 2 * padding[2] - dilation[2] * (kernel[2] - 1) - 1) / stride[2] + 1; + return {N, M, Y_D, Y_H, Y_W}; +} + +#endif +} // anonymous namespace +} // namespace at::native::quantized diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/Copy.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/Copy.h new file mode 100644 index 0000000000000000000000000000000000000000..141174233be75a678370d605ff51c65b1575fcfd --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/Copy.h @@ -0,0 +1,8 @@ +#pragma once + +#include + +namespace at::native { + +Tensor& quantized_copy_from_float_(Tensor& self, const Tensor& src); +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/FakeQuantAffine.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/FakeQuantAffine.h new file mode 100644 index 0000000000000000000000000000000000000000..e107fb4c62f098e2cff847c9d17cbdea05f72234 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/FakeQuantAffine.h @@ -0,0 +1,67 @@ +#pragma once + +#include +#include +#include + +namespace at { + +struct TensorIterator; + +namespace native { + +using fake_quant_tensor_cachemask_fn = void (*)( + Tensor& output, + Tensor& mask, + const Tensor& input, + float sc, + int64_t z_point, + int64_t quant_min, + int64_t quant_max); + +using fake_quant_tensor_cachemask_tensor_qparams_fn = void (*)( + Tensor& output, + Tensor& mask, + const Tensor& input, + const Tensor& sc, + const Tensor& z_point, + const Tensor& fake_quant_enabled, + int64_t quant_min, + int64_t quant_max); + +using fake_quant_learnable_grad_tensor_fn = void (*)( + TensorIterator& iter, + float scale, + float inv_scale, + int64_t zero_point, + int64_t quant_min, + int64_t quant_max, + float grad_factor); + +DECLARE_DISPATCH(fake_quant_tensor_cachemask_fn, fake_quant_tensor_cachemask_stub) +DECLARE_DISPATCH(fake_quant_tensor_cachemask_tensor_qparams_fn, fake_quant_tensor_cachemask_tensor_qparams_stub) +DECLARE_DISPATCH(fake_quant_learnable_grad_tensor_fn, fake_quant_grad_learnable_tensor_stub) + +using fake_quant_per_channel_fn = void (*)( + TensorIterator &iter, + int64_t quant_min, + int64_t quant_max); + +using fake_quant_per_channel_cachemask_fn = void (*)( + TensorIterator &iter, + TensorIterator &iter_mask, + int64_t quant_min, + int64_t quant_max); + +DECLARE_DISPATCH(fake_quant_per_channel_cachemask_fn, fake_quant_per_channel_cachemask_stub) + +using fake_quant_learnable_per_channel_fn = void (*)( + TensorIterator &iter, + int64_t quant_min, + int64_t quant_max, + float grad_factor); + +DECLARE_DISPATCH(fake_quant_learnable_per_channel_fn, fake_quant_grad_learnable_channel_stub) + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/IndexKernel.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/IndexKernel.h new file mode 100644 index 0000000000000000000000000000000000000000..7811a6db91653414a2ad8cd7b9bf99f20bd6c742 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/IndexKernel.h @@ -0,0 +1,13 @@ +#pragma once +#include +#include + +namespace at::native { +using masked_fill_kernel_quantized_fn = void(*)(TensorIterator& iter, const Scalar& value, double scale, int zero_point); +using index_put_kernel_quantized_fn = void(*)(TensorIterator& iter, IntArrayRef index_size, IntArrayRef index_stride, bool accumulate, double scale, int zero_point); + +DECLARE_DISPATCH(masked_fill_kernel_quantized_fn, masked_fill_kernel_quantized_stub) +DECLARE_DISPATCH(index_put_kernel_quantized_fn, index_put_kernel_quantized_stub) + + +} // at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/PackedParams.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/PackedParams.h new file mode 100644 index 0000000000000000000000000000000000000000..d73bc0adbc4ef953e0580585ab9261700374a45d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/PackedParams.h @@ -0,0 +1,147 @@ +#pragma once + +#include +#include + +struct LinearPackedParamsBase : public torch::jit::CustomClassHolder { + virtual at::Tensor apply( + at::Tensor input, + double output_scale, + int64_t output_zero_point) = 0; + virtual at::Tensor apply_relu( + at::Tensor input, + double output_scale, + int64_t output_zero_point) = 0; + + // out variant of LinearPackedParamsBase::apply + virtual at::Tensor& apply_out( + const at::Tensor& /*input*/, + double /*output_scale*/, + int64_t /*output_zero_point*/, + at::Tensor& output) { + throw std::runtime_error( + "apply_out is not implemented for this packed " + "parameter type"); + return output; + } + + virtual at::Tensor& apply_relu_out( + const at::Tensor& /*input*/, + double /*output_scale*/, + int64_t /*output_zero_point*/, + at::Tensor& output) { + throw std::runtime_error( + "apply_relu_out is not implemented for this packed " + "parameter type"); + return output; + } + + // Corresponding pattern (the ops with `*` are part of the pattern that + // represents the computation of quantized::linear_with_input_q_dq_qweight_dq_output_fp32): + // input -> q* -> dq* -> linear* -> + // qweight -> dq* / + // + // After fusion: + // input -> quantized::linear_with_input_q_dq_qweight_dq_output_fp32* -> + // qweight / + // + // Additional Note: the weight is packed as well + // Params: + // X: float32 Tensor, will be quantized to quint8 in the op + // W_prepack: packed qint8 quantized weight and bias + // Returns: + // Y: float32 Tensor + virtual at::Tensor apply_with_input_q_dq_qweight_dq_output_fp32( + at::Tensor input, + double input_scale, + int64_t input_zero_point) { + throw std::runtime_error( + "apply_with_input_q_dq_qweight_dq_output_fp32 is not implemented for this packed " + "parameter type"); + return {}; + } + + // Corresponding pattern (the ops with `*` are part of the pattern that + // represents the computation of quantized::linear_with_input_q_dq_qweight_dq_relu_output_fp32): + // input -> q* -> dq* -> linear* -> relu* -> + // qweight -> dq* / + // + // After fusion: + // input -> quantized::linear_with_input_q_dq_qweight_dq_relu_output_fp32* -> + // qweight / + // + // Additional Note: the weight is packed as well + // Params: + // input: float32 Tensor, will be quantized to quint8 in the op + // Returns: + // float32 Tensor + virtual at::Tensor apply_with_input_q_dq_qweight_dq_relu_output_fp32( + at::Tensor input, + double input_scale, + int64_t input_zero_point) { + throw std::runtime_error( + "apply_with_input_q_dq_qweight_dq_relu_output_fp32 is not implemented for this packed " + "parameter type"); + return {}; + } + + virtual at::Tensor apply_dynamic( + at::Tensor input, + bool reduce_range = false) = 0; + virtual at::Tensor apply_dynamic_relu( + at::Tensor input, + bool reduce_range = false) = 0; + + virtual at::Tensor& apply_dynamic_out( + const at::Tensor& /* input */, + at::Tensor& output, + bool /* reduce_range */) { + throw std::runtime_error( + "apply_dynamic_out is not implemented for this packed " + "parameter type"); + return output; + } + virtual at::Tensor& apply_dynamic_relu_out( + const at::Tensor& /* input */, + at::Tensor& output, + bool /* reduce_range */) { + throw std::runtime_error( + "apply_dynamic_relu_out is not implemented for this packed " + "parameter type"); + return output; + } + + virtual std::tuple> unpack() = 0; + + virtual std::optional bias() = 0; + + virtual void set_bias(std::optional /*bias*/) { + throw std::runtime_error( + "set_bias is not implemented for this packed " + "parameter type"); + } +}; + +template +struct ConvPackedParamsBase : public torch::jit::CustomClassHolder { + virtual at::Tensor apply( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point) = 0; + virtual at::Tensor apply_relu( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point) = 0; + virtual at::Tensor apply_dynamic( + const at::Tensor& input, + bool reduce_range) = 0; + + virtual std::tuple> unpack() = 0; + + virtual torch::List stride() const = 0; + virtual torch::List padding() const = 0; + virtual torch::List output_padding() const = 0; + virtual torch::List dilation() const = 0; + virtual int64_t groups() const = 0; + virtual bool transpose() const = 0; +}; diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/ACLUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/ACLUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..c84406749528eb5bb706afd498198a05ca0a19eb --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/ACLUtils.h @@ -0,0 +1,257 @@ +#pragma once + +#include +#if AT_MKLDNN_ACL_ENABLED() + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +// Utilities for Arm Compute Library (ACL) quantized operations +// Provides interfaces to leverage ACL's accelerated kernels for statically and +// dynamically quantized matmuls (i.e. qlinear and qlinear_dynamic) These are +// utalized through PackedLinearWeightsACL which extends +// PackedLinearWeightsOnednn Note that PackedLinearWeightsACL extends rather +// than replaces PackedLinearWeightsOnednn for AArch64 because ACL currently +// only supports per_tensor weight quantization. +namespace at::native::acl_utils { + +using QuantMatmulCacheKey = std::tuple< + int64_t, // M + bool, // FUSE_RELU + int64_t, // NUM_THREADS + double, // INPUT_SCALE + int64_t, // INPUT_OFFSET + double, // OUTPUT_SCALE + int64_t, // OUTPUT_OFFSET + bool // SIGNED_INPUT + >; + +enum class QuantMatmulCacheKeyIndex { + M, + FUSE_RELU, + NUM_THREADS, + INPUT_SCALE, + INPUT_OFFSET, + OUTPUT_SCALE, + OUTPUT_OFFSET, + SIGNED_INPUT +}; + +// Abstract interface to share common stuff between static/dynamic ACL matmuls. +struct QuantMatmul { + arm_compute::NEGEMMLowpMatrixMultiplyCore gemm; + // key for use in the cache + QuantMatmulCacheKey key; + + QuantMatmul( + int64_t weight_dim_0, + int64_t weight_dim_1, + double weight_scale, + int64_t weight_offset, + int8_t* weight_ptr, + std::optional bias_ptr, + const QuantMatmulCacheKey& cache_key); + + virtual ~QuantMatmul(); + virtual arm_compute::Status validate() = 0; + virtual void configure() = 0; + + protected: + arm_compute::Tensor wei_q_tensor_; + std::optional bia_tensor_; + arm_compute::GEMMInfo gemm_info_; + std::optional relu_info_; +}; + +struct DynamicQuantMatmul : public QuantMatmul { + arm_compute::Tensor src_q_tensor; + arm_compute::Tensor src_tensor; + arm_compute::Tensor dst_tensor; + arm_compute::NEQuantizationLayer quant; + // We need a ReLU layer here (unlike static quantization) because the ReLU + // cannot be "truly" fused with the GEMM through gemm_info in ACL dynamically + // quantized matmuls. + std::optional relu; + + DynamicQuantMatmul( + int64_t weight_dim_0, + int64_t weight_dim_1, + double weight_scale, + int64_t weight_offset, + int8_t* weight_ptr, + std::optional bias_ptr, + const QuantMatmulCacheKey& cache_key); + + ~DynamicQuantMatmul() override; + + arm_compute::Status validate() override; + void configure() override; + + private: + at::Tensor src_q_tensor_orig_; +}; + +struct StaticQuantMatmul : public QuantMatmul { + arm_compute::Tensor src_q_tensor; + arm_compute::Tensor dst_q_tensor; + + StaticQuantMatmul( + int64_t weight_dim_0, + int64_t weight_dim_1, + double weight_scale, + int64_t weight_offset, + int8_t* weight_ptr, + std::optional bias_ptr, + const QuantMatmulCacheKey& cache_key); + + ~StaticQuantMatmul() override; + + arm_compute::Status validate() override; + void configure() override; + + private: + std::optional bia_q_tensor_; + std::optional bia_q_tensor_orig_; +}; + +struct QuantAdd { + arm_compute::Tensor qa_tensor; + arm_compute::Tensor qb_tensor; + arm_compute::Tensor qdst_tensor; + arm_compute::NEArithmeticAddition q_add; + + QuantAdd( + arm_compute::DataType dtype, + const std::vector& input_dims, + double qa_scale, + int64_t qa_offset, + double qb_scale, + int64_t qb_offset, + double dst_scale, + int64_t dst_offset); + + arm_compute::Status validate(); + void configure(); + + private: + arm_compute::ConvertPolicy policy{arm_compute::ConvertPolicy::SATURATE}; +}; + +} // namespace at::native::acl_utils +struct PackedLinearWeightsACL : public PackedLinearWeightsOnednn { + using ACLQuantMatmul = at::native::acl_utils::QuantMatmul; + using ACLDynamicQuantMatmul = at::native::acl_utils::DynamicQuantMatmul; + using ACLStaticQuantMatmul = at::native::acl_utils::StaticQuantMatmul; + using ACLQuantMatmulCacheKey = at::native::acl_utils::QuantMatmulCacheKey; + using ACLQuantMatmulCacheKeyIndex = + at::native::acl_utils::QuantMatmulCacheKeyIndex; + + PackedLinearWeightsACL( + std::unique_ptr weight, + std::optional bias, + at::Tensor orig_weight, + std::optional orig_bias); + + at::Tensor apply_dynamic(at::Tensor input, bool reduce_range = false) + override; + at::Tensor apply_dynamic_relu(at::Tensor input, bool reduce_range = false) + override; + + at::Tensor apply( + at::Tensor input, + double output_scale, + int64_t output_zero_point) override; + at::Tensor apply_relu( + at::Tensor input, + double output_scale, + int64_t output_zero_point) override; + + template + std::shared_ptr get_acl_quant_matmul( + const ACLQuantMatmulCacheKey& key) { + return std::dynamic_pointer_cast( + fetch_or_create_acl_quant_matmul(key)); + } + + private: + int64_t k_; + int64_t n_; + int64_t weight_zero_point_; + double weight_scale_; + + // A 2 element (per layer) cache. Given it's not intended to store more than 2 + // elements, we do not need a fancy implementation. The idea behind it is to + // allow for a (configuration free) fast path for autoregressive + // transformer-like models which usually involve 2 input tensor shapes; one + // for the prefill phase and another for the autoregressive phase + std::array, 2> cache_; + + template + std::shared_ptr fetch_or_create_acl_quant_matmul( + const ACLQuantMatmulCacheKey& key) { + // We're only maintaining a 2 element LRU cache + // hit first + if (cache_[0] != nullptr && cache_[0]->key == key) { + return cache_[0]; + } + // hit second + if (cache_[1] != nullptr && cache_[1]->key == key) { + // Update LRU + std::swap(cache_[0], cache_[1]); + return cache_[0]; + } + // miss -> replace Least Recently Used - i.e. element at index 1 + cache_[1] = create_acl_quant_matmul(key); + std::swap(cache_[0], cache_[1]); + return cache_[0]; + } + + template + std::shared_ptr create_acl_quant_matmul( + const ACLQuantMatmulCacheKey& key) { + std::optional bias_ptr; + if (bias_.has_value()) { + bias_ptr = (float*)bias_.value().get_data_handle(); + } + auto acl_gemm = std::make_shared( + k_, + n_, + weight_scale_, + weight_zero_point_, + (int8_t*)weight_.get()->get_data_handle(), + bias_ptr, + key); + + // validate + auto status = acl_gemm->validate(); + if (status.error_code() != arm_compute::ErrorCode::OK) { + TORCH_WARN( + "Arm Compute Library's Quantized Matmul Validation Failed: " + + status.error_description()); + return nullptr; + } + + // configure + acl_gemm->configure(); + return acl_gemm; + } + + template + at::Tensor apply_dynamic_impl(at::Tensor input, bool reduce_range = false); + + template + at::Tensor apply_impl( + at::Tensor input, + double output_scale, + int64_t output_zero_point); +}; + +#endif // AT_MKLDNN_ACL_ENABLED() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/BinaryOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/BinaryOps.h new file mode 100644 index 0000000000000000000000000000000000000000..0643ae3b536d30a4840ccd72dc04857922b3c9b0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/BinaryOps.h @@ -0,0 +1,6 @@ +#include + +namespace at::native { +TORCH_API Tensor +quantized_add(Tensor qa, Tensor qb, double scale, int64_t zero_point); +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/EmbeddingPackedParams.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/EmbeddingPackedParams.h new file mode 100644 index 0000000000000000000000000000000000000000..e6f47d611a19f4bcf804b63f20fb06be9a2c1f44 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/EmbeddingPackedParams.h @@ -0,0 +1,29 @@ +#pragma once + +#include +#include + +struct EmbeddingPackedParamsBase : public torch::jit::CustomClassHolder { + virtual at::Tensor embeddingbag_byte( + const at::Tensor& indices, + const std::optional& offsets, + bool pruned_weights, + const std::optional& per_sample_weights_, + const std::optional& compressed_indices_mapping, + bool include_last_offset, + bool is_embedding_op) = 0; + + virtual at::Tensor embeddingbag_4bit( + const at::Tensor& indices, + const std::optional& offsets, + bool pruned_weights, + const std::optional& per_sample_weights_, + const std::optional& compressed_indices_mapping, + bool include_last_offset, + bool is_embedding_op) = 0; + + virtual at::Tensor unpack() = 0; + + virtual int64_t bit_rate() const = 0; + virtual int64_t version() const = 0; +}; diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/OnednnUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/OnednnUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..7722272dfcc270914072602a2a32937fd1c1af72 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/OnednnUtils.h @@ -0,0 +1,463 @@ +#pragma once + +#include +#if AT_MKLDNN_ENABLED() +#include +#include +#include +#if !defined(__powerpc__) +#include +#endif + +#include + +using PrimitiveCacheKey = std::tuple< + double, // input_scale + int64_t, // input_zero_point + std::vector, // input_shape + double, // output_scale + int64_t, // output_zero_point + int64_t, // OMP_number_of_threads + double, // accum_scale + int64_t>; // accum_zero_point + +enum CacheKeyIndex { + InputScale, + InputZeroPoint, + InputShape, + OutputScale, + OutputZeroPoint, + NumOfThreads, +}; + +// Base class of primitive cache +struct PrimitiveCache { + PrimitiveCacheKey key; + + bool hit(const PrimitiveCacheKey& key) { + return this->key == key; + } +}; + +using LinearParams = ideep::matmul_forward_params; +using Conv = dnnl::convolution_forward; +using ConvDesc = dnnl::convolution_forward::primitive_desc; +using ConvParams = ideep::convolution_forward_params; +using Deconv = dnnl::deconvolution_forward; +using DeconvDesc = dnnl::deconvolution_forward::primitive_desc; +using DeconvParams = ideep::deconv_forward_params; + +struct LinearPrimitiveCache : PrimitiveCache { + LinearPrimitiveCache() = default; + + LinearPrimitiveCache( + const PrimitiveCacheKey& key, + const LinearParams& param) { + this->key = key; + this->param = param; + } + + LinearParams param; + + // For dynamic qlinear, scale and zero point + // are set at execution time. So we only need to compare + // the rest part of key. + bool hit_dynamic(const PrimitiveCacheKey& new_key) { + auto const& cached_input_shape = std::get(this->key); + auto const& new_input_shape = std::get(new_key); + return ( + cached_input_shape == new_input_shape && + std::get(this->key) == std::get(new_key)); + } + + LinearParams& get_param() { + return param; + } +}; + +struct ConvPrimitiveCache : PrimitiveCache { + ConvPrimitiveCache() = default; + + ConvPrimitiveCache( + const PrimitiveCacheKey& key, + const ConvParams& params) { + this->key = key; + this->params = params; + } + + ConvParams params; + + ConvParams& get_params() { + return params; + } +}; + +struct DeconvPrimitiveCache : PrimitiveCache { + DeconvPrimitiveCache() = default; + + DeconvPrimitiveCache( + const PrimitiveCacheKey& key, + const DeconvParams& params) { + this->key = key; + this->params = params; + } + + DeconvParams params; + + DeconvParams& get_params() { + return params; + } +}; + +enum PostOps { + NoPostOp, + Relu, + LeakyRelu, + Tanh, + Gelu +}; + + +struct PackedLinearWeightsOnednn : public LinearPackedParamsBase { + PackedLinearWeightsOnednn( + std::unique_ptr weight, + std::optional bias, + at::Tensor orig_weight, + std::optional orig_bias) + : weight_(std::move(weight)), + bias_(std::move(bias)), + orig_weight_(std::move(orig_weight)), + orig_bias_(std::move(orig_bias)) { + cache_initialized_flag = std::make_unique(); + } + std::unique_ptr weight_; + std::optional bias_; + at::Tensor orig_weight_; + std::optional orig_bias_; + + at::Tensor apply( + at::Tensor input, + double output_scale, + int64_t output_zero_point) override; + at::Tensor apply_relu( + at::Tensor input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor apply_dynamic(at::Tensor input, bool reduce_range=false) override; + at::Tensor apply_dynamic_relu(at::Tensor input, bool reduce_range=false) override; + + at::Tensor apply_leaky_relu( + at::Tensor input, + double output_scale, + int64_t output_zero_point, + double negative_slope); + + at::Tensor apply_tanh( + at::Tensor input, + double output_scale, + int64_t output_zero_point); + + std::tuple> unpack() override; + + std::optional bias() override { + return orig_bias_; + } + + static c10::intrusive_ptr prepack( + at::Tensor weight, + std::optional bias); + + private: + LinearPrimitiveCache prim_cache; + std::unique_ptr cache_initialized_flag; + + template + at::Tensor apply_impl( + at::Tensor input, + double output_scale, + int64_t output_zero_point, + torch::List post_op_args = torch::List()); + + template + at::Tensor apply_dynamic_impl(at::Tensor input, bool reduce_range=false); + + LinearPrimitiveCache& get_cache() { + return prim_cache; + } +}; + +template +struct PackedConvWeightsOnednn : public ConvPackedParamsBase { + PackedConvWeightsOnednn( + std::unique_ptr weight, + std::optional bias, + at::Tensor orig_weight, + std::optional orig_bias, + torch::List stride, + torch::List padding, + torch::List output_padding, + torch::List dilation, + int64_t groups, + uint8_t transpose) + : weight_(std::move(weight)), + bias_(std::move(bias)), + orig_weight_(std::move(orig_weight)), + orig_bias_(std::move(orig_bias)), + stride_(std::move(stride)), + padding_(std::move(padding)), + output_padding_(std::move(output_padding)), + dilation_(std::move(dilation)), + groups_(groups), + transpose_(transpose) { + cache_initialized_flag = std::make_unique(); + } + + std::unique_ptr weight_; + std::optional bias_; + at::Tensor orig_weight_; + std::optional orig_bias_; + torch::List stride_; + torch::List padding_; + torch::List output_padding_; + torch::List dilation_; + int64_t groups_; + uint8_t transpose_; + + at::Tensor apply( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor apply_relu( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor apply_dynamic( + const at::Tensor& input, + bool reduce_range) override; + + at::Tensor apply_add( + const at::Tensor& input, + const at::Tensor& accum, + double output_scale, + int64_t output_zero_point); + + at::Tensor apply_add_relu( + const at::Tensor& input, + const at::Tensor& accum, + double output_scale, + int64_t output_zero_point); + + std::tuple> unpack() override; + + static c10::intrusive_ptr> prepack( + at::Tensor weight, + std::optional bias, + torch::List stride, + torch::List padding, + torch::List output_padding, + torch::List dilation, + int64_t groups, + bool transpose); + + torch::List stride() const override { + return stride_; + } + + torch::List padding() const override { + return padding_; + } + + torch::List output_padding() const override { + return output_padding_; + } + + torch::List dilation() const override { + return dilation_; + } + + int64_t groups() const override { + return groups_; + } + + bool transpose() const override { + return (bool)transpose_; + } + + private: + ConvPrimitiveCache conv_prim_cache; + DeconvPrimitiveCache deconv_prim_cache; + std::unique_ptr cache_initialized_flag; + + template + at::Tensor apply_impl( + const at::Tensor& input, + const std::optional& accum, + double output_scale, + int64_t output_zero_point); + + ConvPrimitiveCache& get_conv_cache() { + assert(!transpose()); + return conv_prim_cache; + } + + DeconvPrimitiveCache& get_deconv_cache() { + assert(transpose()); + return deconv_prim_cache; + } +}; + +namespace onednn_utils { + +inline ideep::attr_t create_attr_by_post_op( + const std::string_view& binary_post_op, + double binary_alpha, + double input1_scale, + int64_t input1_zero_point, + const ideep::tensor::desc& input1_desc, + const std::string_view& unary_post_op, + const torch::List>& unary_post_op_args, + const std::string_view& unary_post_op_algorithm) { + using ideep::tensor; + if (binary_post_op == "none") { + if (unary_post_op == "relu") { + return ideep::attr_t::fuse_relu(); + } else if (unary_post_op == "leaky_relu") { + TORCH_CHECK( + unary_post_op_args.size() == 1, + "onednn qlinear: expect one argument for post op leaky_relu but got ", unary_post_op_args.size(), " args"); + auto alpha = unary_post_op_args[0].value().to(); + return ideep::attr_t::fuse_relu_v2(alpha); + } else if (unary_post_op == "tanh") { + return ideep::attr_t::fuse_tanh(); + } else if (unary_post_op == "gelu") { + TORCH_CHECK( + unary_post_op_algorithm == "none" || unary_post_op_algorithm == "tanh", + "onednn qlinear: algorithm for post op gelu must be none or tanh but got ", unary_post_op_algorithm); + auto post_algorithm = unary_post_op_algorithm == "none" ? + dnnl::algorithm::eltwise_gelu_erf : + dnnl::algorithm::eltwise_gelu_tanh; + return ideep::attr_t::fuse_gelu_v2(0.f, 0.f, post_algorithm); + } else if (unary_post_op == "hardtanh") { + TORCH_CHECK( + unary_post_op_args.size() == 2 && + unary_post_op_args[0].has_value() && + unary_post_op_args[1].has_value(), + "hardtanh is expected to have two scalar input: min_val and max_val"); + auto lower_bound_value = + unary_post_op_args[0].value().to(); + auto upper_bound_value = + unary_post_op_args[1].value().to(); + return ideep::attr_t::fuse_clamp(lower_bound_value, upper_bound_value); + } else if (unary_post_op == "hardswish") { + return ideep::attr_t::fuse_hardswish(); + } else if (unary_post_op == "swish") { + return ideep::attr_t::fuse_swish(); + } else { + TORCH_CHECK( + unary_post_op == "none", + "onednn qlinear: unsupported unary post op ", unary_post_op); + } + } else if (binary_post_op == "sum") { + if (unary_post_op == "none") { + return ideep::attr_t::fuse_sum(input1_scale, input1_zero_point); + } else if (unary_post_op == "relu") { + return ideep::attr_t::residual_with_sum_zero_point(input1_scale, input1_zero_point); + } else { + TORCH_CHECK( + false, + "onednn qlinear: unsupported unary post op ", unary_post_op, " with binary post op sum"); + } + } else if (binary_post_op == "add") { + if (unary_post_op == "none") { + return ideep::attr_t::fuse_binary(ideep::algorithm::binary_add, input1_desc); + } else if (unary_post_op == "relu") { + ideep::post_ops po; + po.append_binary(ideep::algorithm::binary_add, input1_desc); + po.append_eltwise(ideep::algorithm::eltwise_relu, 0, 0); + return ideep::attr_t::attr_post_ops(po); + } else { + TORCH_CHECK( + false, + "onednn qlinear: unsupported unary post op ", unary_post_op, " with binary post op add"); + } + } else { + TORCH_CHECK( + false, + "onednn qlinear: unsupported binary post op ", binary_post_op); + } + return ideep::attr_t(); +} + +// ONEDNN requires symmetric quantization of weight +// Use this util function to check. +inline bool is_weight_symmetric_quant( + const at::Tensor& weight, + bool is_transposed_conv) { + bool is_symmetric = true; + const auto qtype = weight.qscheme(); + if (qtype == c10::kPerTensorAffine) { + is_symmetric &= (weight.q_zero_point() == 0); + } else if (qtype == c10::kPerChannelAffine) { + if (is_transposed_conv) { + // This case is currently not supported in PyTorch + // but we do not want to raise an error in this util function. + is_symmetric = false; + } else { + auto output_channels = weight.size(0); + for (int i = 0; i < output_channels; ++i) { + auto zp = weight.q_per_channel_zero_points()[i].item(); + is_symmetric &= (zp == 0); + } + } + } else { + // This case is currently not supported in PyTorch + // but we do not want to raise an error in this util function. + is_symmetric = false; + } + return is_symmetric; +} + +// When qengine is x86, use this util func to check if onednn kernel +// is preferred than fbgemm's to get better performance. +inline bool should_use_onednn_quant( + const at::Tensor& weight, + bool is_transposed_conv, + int groups, + torch::List output_padding) { + // Performance of onednn is only validated on Linux right now. + // Also, the heuristics for dispatching are based on perf data on Linux. + // So, for x86 qengine, we always use fbgemm kernels if OS is not Linux. + // TODO Support more OSs. +#if !defined(__linux__) + return false; +#else +#if defined(__powerpc__) + constexpr auto vnni_available = true; +#else + const auto vnni_available = cpuinfo_has_x86_avx512vnni(); +#endif + bool w_sym_quant = + is_weight_symmetric_quant(weight, is_transposed_conv); + bool opad_all_zero = + std::all_of(output_padding.begin(), output_padding.end(), [](int i) { return i==0; }); + return vnni_available && (groups <= 100) && w_sym_quant && opad_all_zero; +#endif +} + +} // onednn_utils + +at::Tensor _qconv_prepack_onednn( + at::Tensor weight, // from CPU backend instead of QuantizedCPU + at::Tensor weight_scales, // Weight zero points must be 0 for onednn + double input_scale, + int64_t input_zero_point, + torch::List stride, + torch::List padding, + torch::List dilation, + int64_t groups, + std::optional> input_shape=std::nullopt); + +#endif // #if AT_MKLDNN_ENABLED() diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/QnnpackUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/QnnpackUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..2fb60fd88b3c002acf43a90f2b8b4d241de3ae38 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/QnnpackUtils.h @@ -0,0 +1,523 @@ +#pragma once + +#ifdef USE_PYTORCH_QNNPACK +#include +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + +#include +inline int kPaddingChannels = 8; +struct QnnpackOperatorDeleter { + void operator()(pytorch_qnnp_operator_t op) { + pytorch_qnnp_delete_operator(op); + } +}; + +// PackedWeight struct for QNNPACK stores the original Weight and Bias as +// QNNPACK currently does not support an unpack function. +// For PyTorch Mobile, once the model is scripted and serialized we don't need +// to call unpack, so we can save some memory by checking for this case and free +// the original weights after packing. +// Input scale is set to null in pre-pack step. QNNPACK needs bias quantized +// with input scale which is available at runtime in pytorch. During runtime if +// input scale value changes then we requantize bias with the updated scale. For +// inference we expect the graph to be static so the input scale should not +// change across consecutive inference calls. +struct PackedLinearWeightsQnnp : public LinearPackedParamsBase { + PackedLinearWeightsQnnp( + std::unique_ptr w, + at::Tensor orig_weight, + at::Tensor bias, + std::optional input_scale, + at::Tensor w_scales, + std::vector&& w_zps) + : w(std::move(w)), + orig_weight(std::move(orig_weight)), + bias_(at::native::mobile::allocate_padded_contiguous_if_needed( + bias, bias.suggest_memory_format())), + per_channel_(this->orig_weight.qscheme() == at::kPerChannelAffine), + input_scale(std::move(input_scale)), + w_scales(std::move(w_scales)), + w_zero_points(std::move(w_zps)), + q_scheme(this->orig_weight.qscheme()) { + weight_sizes = this->orig_weight.sizes().vec(); + } + + std::unique_ptr w; + at::Tensor orig_weight; + at::Tensor bias_; + bool per_channel_; + std::optional input_scale; + at::Tensor w_scales; + std::vector w_zero_points; + std::vector requantization_scales; + std::vector weight_sizes; + c10::QScheme q_scheme; + + at::Tensor apply( + at::Tensor input, + double output_scale, + int64_t output_zero_point) override; + at::Tensor apply_relu( + at::Tensor input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor apply_dynamic(at::Tensor input, bool reduce_range=false) override; + at::Tensor apply_dynamic_relu(at::Tensor input, bool reduce_range=false) override; + + std::tuple> unpack() override; + + std::optional bias() override { + return bias_; + } + + static c10::intrusive_ptr prepack( + at::Tensor weight, + std::optional bias); + + bool per_channel() const { + return per_channel_; + } + + private: + std::mutex qnnp_mutex_; + +#ifdef USE_XNNPACK + xnnpack_operator xnnp_linear_op; + + template + at::Tensor apply_impl_xnnp( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point); +#endif // USE_XNNPACK + + template + at::Tensor apply_impl( + at::Tensor input, + double output_scale, + int64_t output_zero_point); + + template + at::Tensor apply_dynamic_impl(at::Tensor input, bool reduce_range); +}; + +template +struct PackedConvWeightsQnnp : public ConvPackedParamsBase { + PackedConvWeightsQnnp( + std::unique_ptr w, + at::Tensor orig_weight, + at::Tensor bias, + torch::List stride, + torch::List padding, + torch::List output_padding, + torch::List dilation, + int64_t groups, + bool transpose, + std::optional input_scale, + std::vector kernel, + at::Tensor w_scale, + std::vector&& w_zps, + bool is_per_channel) + : w(std::move(w)), + orig_weight(std::move(orig_weight)), + bias(std::move(bias)), + stride_(std::move(stride)), + padding_(std::move(padding)), + output_padding_(std::move(output_padding)), + dilation_(std::move(dilation)), + groups_(groups), + transpose_(transpose), + is_per_channel_(is_per_channel), + input_scale(input_scale), + kernel_(std::move(kernel)), + w_scales(std::move(w_scale)), + w_zero_points(std::move(w_zps)) { + const bool any_padding = std::any_of( + padding_.begin(), padding_.end(), [](const auto& e) { return e != 0; }); + const size_t kernel_size = + std::accumulate(kernel_.begin(), kernel_.end(), 1, std::multiplies<>()); + + const size_t group_input_channels = transpose + ? this->orig_weight.size(0) / groups + : this->orig_weight.size(1); + const size_t group_output_channels = transpose + ? this->orig_weight.size(1) + : this->orig_weight.size(0) / groups; + + const size_t kernel_depth = kSpatialDim == 3 ? kernel_[0] : 1; + const size_t kernel_height = kernel_[kSpatialDim - 2]; + const size_t kernel_width = kernel_[kSpatialDim - 1]; + + pytorch_qnnp_ukernel_type ukernel_type; + if (transpose_) { + ukernel_type = pytorch_qnnp_ukernel_type_conv; + } else { + ukernel_type = pytorch_qnnp_ukernel_type_none; + + const bool has_depthwise_dimensions = + (kSpatialDim == 2 && + ((kernel_height == 3 && kernel_width == 3) || + (kernel_height == 5 && kernel_width == 5))) || + (kSpatialDim == 3 && kernel_height == 3 && kernel_width == 3 && + kernel_depth == 3); + const bool has_depthwise_grouping = + group_input_channels == 1 && group_output_channels == 1 && groups > 1; + + if (has_depthwise_dimensions && has_depthwise_grouping) { + ukernel_type = pytorch_qnnp_ukernel_type_dwconv; + } else if ( + kernel_size == 1 && + std::all_of( + stride_.begin(), + stride_.end(), + [](const auto& e) { return e == 1; }) && + !any_padding) { + ukernel_type = group_input_channels >= SIZE_MAX + ? pytorch_qnnp_ukernel_type_xzp_gemm + : pytorch_qnnp_ukernel_type_gemm; + } else { + ukernel_type = pytorch_qnnp_ukernel_type_conv; + } + } + + if (is_per_channel && ukernel_type == pytorch_qnnp_ukernel_type_xzp_gemm) { + TORCH_INTERNAL_ASSERT( + false, "Per channel quantized weights are not supported for XZP kernels"); + } + + pytorch_qnnp_operator_t convolution{nullptr}; + // Initially all the params are set to zero. + convolution = static_cast( + calloc(1, sizeof(struct pytorch_qnnp_operator))); + if (convolution == nullptr) { + TORCH_INTERNAL_ASSERT( + false, "failed to allocate %zu bytes for pytorch_qnnp_operator structure", + sizeof(struct pytorch_qnnp_operator)); + } + + convolution_op = + std::unique_ptr( + convolution); + + // NOLINTNEXTLINE(clang-analyzer-core.NullDereference) + convolution->ukernel_type = ukernel_type; + convolution->groups = groups; + convolution->group_input_channels = group_input_channels; + convolution->group_output_channels = group_output_channels; + convolution->kernel_depth = kernel_depth; + convolution->kernel_height = kernel_height; + convolution->kernel_width = kernel_width; + convolution->stride_depth = kSpatialDim == 3 ? stride_[0] : 1; + convolution->stride_height = stride_[kSpatialDim - 2]; + convolution->stride_width = stride_[kSpatialDim - 1]; + convolution->dilation_depth = kSpatialDim == 3 ? dilation_[0] : 1; + convolution->dilation_height = dilation_[kSpatialDim - 2]; + convolution->dilation_width = dilation_[kSpatialDim - 1]; + convolution->input_padding_height = padding_[kSpatialDim - 2]; + convolution->input_padding_width = padding_[kSpatialDim - 1]; + convolution->input_padding_depth = kSpatialDim == 3 ? padding_[0] : 0; + convolution->per_channel = is_per_channel_; + convolution->transpose = transpose_; + + const uint32_t kr = pytorch_qnnp_params.q8conv.kr; + const size_t k_stride = (group_input_channels + (kr - 1)) & -kr; + + size_t zero_size = sizeof(uint8_t) * k_stride; + size_t zero_offset = 0; + + if (transpose_) { + convolution->adjustment_width = output_padding_[1]; + convolution->adjustment_height = output_padding_[0]; + if (group_input_channels < 8) { + zero_size += 8; + zero_offset = 8; + } + } else { + zero_buffer_size = 0; + if (any_padding) { + zero_size = 0; + zero_offset = 0; + if (ukernel_type == pytorch_qnnp_ukernel_type_dwconv) { + const uint32_t cr = pytorch_qnnp_params.q8dw9.cr; + const size_t group_stride = (groups + (cr - 1)) & -cr; + if (groups >= 8) { + zero_size = sizeof(uint8_t) * group_stride; + zero_offset = 0; + } else { + zero_size = sizeof(uint8_t) * group_stride + 8; + zero_offset = sizeof(uint8_t) * 8; + } + } else if ( + ukernel_type == pytorch_qnnp_ukernel_type_conv || + ukernel_type == pytorch_qnnp_ukernel_type_gemm) { + if (group_input_channels >= 8) { + zero_size = sizeof(uint8_t) * k_stride; + zero_offset = 0; + } else { + zero_size = sizeof(uint8_t) * k_stride + 8; + zero_offset = 8; + } + } + } + } + + // NOLINTNEXTLINE(clang-analyzer-optin.portability.UnixAPI) + void* zero_buffer = malloc(zero_size); + if (zero_buffer == nullptr) { + pytorch_qnnp_delete_operator(convolution); + TORCH_INTERNAL_ASSERT( + false, "failed to allocate %zu bytes for zero padding", + zero_size); + } + // Need to set to input zero point + // memset(zero_buffer, input_zero_point, zero_size); + zero_buffer_size = zero_size; + convolution->zero_buffer = zero_buffer; + convolution->zero_pointer = (void*)((uintptr_t)zero_buffer + zero_offset); + } + + std::unique_ptr convolution_op; + #ifdef USE_XNNPACK + xnnpack_operator xnnp_convolution_op; + #endif // USE_XNNPACK + std::unique_ptr w; + at::Tensor orig_weight; + at::Tensor bias; + torch::List stride_; + torch::List padding_; + torch::List output_padding_; + torch::List dilation_; + int64_t groups_; + bool transpose_; + bool is_per_channel_; + std::optional input_scale; + std::vector kernel_; + at::Tensor w_scales; + std::vector w_zero_points; + std::vector requantization_scales; + size_t zero_buffer_size; + + at::Tensor apply( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor apply_relu( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor apply_dynamic( + const at::Tensor& input, + bool reduce_range=false) override; + + std::tuple> unpack() override; + + static c10::intrusive_ptr> prepack( + at::Tensor weight, + std::optional bias, + torch::List stride, + torch::List padding, + torch::List output_padding, + torch::List dilation, + int64_t groups, + bool transpose); + + torch::List stride() const override { + return stride_; + } + + torch::List padding() const override { + return padding_; + } + + torch::List output_padding() const override { + return output_padding_; + } + + torch::List dilation() const override { + return dilation_; + } + + int64_t groups() const override { + return groups_; + } + + bool transpose() const override { + return transpose_; + } + + bool per_channel() const { + return is_per_channel_; + } + + private: + std::mutex qnnp_mutex_; + template + at::Tensor apply_impl( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point); + +#ifdef USE_XNNPACK + template + at::Tensor apply_impl_xnnp( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point); +#endif // USE_XNNPACK +}; + +enum class Activation : uint8_t { NONE = 0, RELU = 1 }; + +#if defined(__ANDROID__) && !defined(__NDK_MAJOR__) +template +inline float Round(const float x) { + return ::nearbyintf(x); +} +inline double Round(const double x) { + return ::nearbyint(x); +} +#else +template +inline T Round(const T x) { + return std::nearbyint(x); +} +#endif + +template +inline T QuantizeValue(float scale, int32_t zero_point, float value) { + const int32_t qmin = std::numeric_limits::min(); + const int32_t qmax = std::numeric_limits::max(); + auto r = zero_point + static_cast(Round(value / scale)); + r = std::max(r, qmin); + r = std::min(r, qmax); + return static_cast(r); +} + +template +inline std::pair activationLimits( + float scale, + int32_t zero_point, + Activation Ac) { + switch (Ac) { + case Activation::NONE: + return {std::numeric_limits::min(), + std::numeric_limits::max()}; + case Activation::RELU: + return {QuantizeValue(scale, zero_point, 0.0), + std::numeric_limits::max()}; + default: +#ifdef _MSC_VER + __assume(0); +#else + __builtin_unreachable(); +#endif + } +} + +namespace at::native::qnnp_avgpool_helper { +Tensor qnnpack_avg_pool2d( + Tensor input, + IntArrayRef kernel_size, + IntArrayRef stride, + IntArrayRef padding, + bool ceil_mode, + bool count_include_pad, + std::optional divisor_override); +} // namespace at::native::qnnp_avgpool_helper + +namespace { +[[maybe_unused]] std::vector generate_requantization_scales( + const at::Tensor& weight_scales, + const float input_scale, + const float output_scale, + std::vector& requant_scales) { + // Since weight scale is allocated with padding + // weight_scales.numel() gives us padded num elements. + const auto num_output_channels_padded = weight_scales.numel(); + float *const weight_scales_data = weight_scales.data_ptr(); + if (static_cast(requant_scales.size()) < num_output_channels_padded) { + requant_scales.resize(num_output_channels_padded); + } + for (const auto i : c10::irange(num_output_channels_padded)) { + const auto inverse_output_scale = 1.f /output_scale; + requant_scales[i] = (weight_scales_data[i] * input_scale) * inverse_output_scale; + TORCH_CHECK( + (requant_scales[i] > 0.0f && std::isnormal(requant_scales[i])), + "failed to create op with requantization scale: ", + requant_scales[i], + ": requantization scale must be finite and positive"); + } + return requant_scales; +} + +[[maybe_unused]] std::pair, at::Tensor> +make_zero_points_and_scales_tensor( + const at::Tensor& weight_contig, + bool transpose = false, + uint32_t groups = 1) { + const int out_ch_idx = transpose ? 1 : 0; + const auto num_output_channels = weight_contig.size(out_ch_idx) * (transpose ? groups : 1); + // Add 8 to account for bufferring needed by QNNPACK. + const auto num_output_channels_padded = num_output_channels + kPaddingChannels; + const auto qtype = weight_contig.qscheme(); + std::vector weight_zp(num_output_channels_padded, 0); + // Adjust weight zero point, similar to weight data. + if (qtype == at::kPerTensorAffine) { + for (const auto i : c10::irange(num_output_channels)) { + weight_zp[i] = (uint8_t)(weight_contig.q_zero_point() + 128); + } + } else if (qtype == at::kPerChannelAffine) { + TORCH_CHECK( + weight_contig.q_per_channel_zero_points().scalar_type() == at::kLong, + "Per channel zero points dtype must be long int."); + const int64_t* per_channel_zero_points = + weight_contig.q_per_channel_zero_points().data_ptr(); + for (const auto i : c10::irange(num_output_channels)) { + weight_zp[i] = (uint8_t)(per_channel_zero_points[i] + 128); + } + } else { + TORCH_INTERNAL_ASSERT(false, "Unsupported quantization scheme."); + } + at:: Tensor weight_scales = + at::empty( + {num_output_channels_padded}, + at::device(at::kCPU).dtype(at::kFloat)); + float *const weight_scales_data = weight_scales.data_ptr(); + if (qtype == at::kPerTensorAffine) { + for (const auto i : c10::irange(num_output_channels)) { + weight_scales_data[i] = weight_contig.q_scale(); + } + } else if (qtype == at::kPerChannelAffine) { + TORCH_CHECK( + weight_contig.q_per_channel_scales().scalar_type() == at::kDouble, + "Per channel scales dtype must be double."); + const double *const per_channel_scales = + weight_contig.q_per_channel_scales().data_ptr(); + for (const auto i : c10::irange(num_output_channels)) { + weight_scales_data[i] = static_cast(per_channel_scales[i]); + } + } else { + TORCH_INTERNAL_ASSERT(false, "Unsupported quantization scheme."); + } + for (const auto i : c10::irange(num_output_channels, num_output_channels_padded)) { + weight_scales_data[i] = 1.f; + } + return {weight_zp, weight_scales}; +} +} // namespace + +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/QuantUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/QuantUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..e81b0d87916b28b884dfc7edce4a25ad171babe8 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/QuantUtils.h @@ -0,0 +1,240 @@ +#pragma once + +#include +#include +#include +#include +#include +#include + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#include +#else +#include +#include +#include +#endif + +namespace quant_utils { +namespace { + float RawUint16ToFp16(unsigned short value) { + // Convert raw 16 bits half precision floating point number + // to single precision floating point number. + const unsigned short sign_bits = value >> 15; + const unsigned short exponent_bits = value >> 10 & 0x1f; + const unsigned short significand_bits = value & 0x3ff; + + const float sign = sign_bits ? -1 : 1; + const float significand = + 1 + significand_bits * 0.0009765625f; // 0.0009765625f = 0x1p-10 = 2^-10; + const float exponent = exponent_bits - 0xf; + + return sign * std::ldexp(significand, exponent); +} + +template +bool CheckAndSaturate(T max_val, T* element) { + if (*element > max_val) { + *element = max_val; + return true; + } + if (*element < -max_val) { + *element = -max_val; + return true; + } + return false; +} +} +using namespace std; +// A structure to hold quantization parameters 'scale' and 'zero_point'. +// The meaning of these values is as the constants in the quantization equation +// +// real_value = scale * (quantized_value - zero_point) +// +// In other words, 'zero_point' is the quantized value that corresponds +// to the real value 0, and 'scale' is the difference of real values +// corresponding to consecutive quantized values. +struct TensorQuantizationParams { + double scale; + std::int32_t zero_point; + int precision; +}; + +// Use fp16_min as the small scale cutoff because we don't want to use scales in +// fp16 subnormal range. This is to be consistent with Glow and FakeLowP +// implementation for NNPI. +constexpr float SMALL_SCALE_THRESHOLD = 6.1e-5f; + +// Following implementation should be identical to fbgemm::ChooseQuantizationParams +inline TensorQuantizationParams ChooseQuantizationParams( + float min, + float max, + int32_t qmin, + int32_t qmax, + bool preserve_sparsity = false, + bool force_scale_power_of_two = false, + bool reduce_range = false) { + TORCH_CHECK( + min <= max, + "In ChooseQuantizationParams, min should be less than or equal to max"); + + if (reduce_range) { + qmin = qmin/2; + qmax = qmax/2; + } + if (min < 0 && max > 0 && preserve_sparsity) { + int symmetric_qmin = -((qmax - qmin) / 2 + 1); + int symmetric_qmax = (qmax - qmin) / 2; + double max_scale = + std::max(fabs(min / symmetric_qmin), fabs(max / symmetric_qmax)); + min = max_scale * symmetric_qmin; + max = max_scale * symmetric_qmax; + } + + // We extend the [min, max] interval to ensure that it contains 0. + // Otherwise, we would not meet the requirement that 0 be an exactly + // representable value. + min = std::min(min, 0.f); + max = std::max(max, 0.f); + + TORCH_CHECK( + qmin < qmax, + "In ChooseQuantizationParams, qmin should be less than qmax"); + + // Use double precision for intermediate computation but use single precision + // in final number to reflect the actual number used during quantization. + double scale = (static_cast(max) - min) / (qmax - qmin); + // If scale is 0 or too small so its reciprocal is infinity, we arbitrary + // adjust the scale to 0.1 . We want to avoid scale's reciprocal being + // infinity because some of fbgemm code pre-computes scale's reciprocal to do + // multiplication instead of division in the time critical part of code. + if (float(scale) == 0.0f || std::isinf(1.0f / float(scale))) { + scale = 0.1; + } + TORCH_CHECK(scale > 0, "quantization scale should be > 0"); + + if (force_scale_power_of_two) { + if (scale < 1) { + scale = 1.0 / (1 << static_cast(floor(log(1.0 / scale) / log(2)))); + } else { + scale = 1 << static_cast(ceil(log(scale) / log(2))); + } + } + + // Cut off small scale + if (scale < SMALL_SCALE_THRESHOLD) { + float org_scale = scale; + scale = SMALL_SCALE_THRESHOLD; + // Adjust the min and max based on the new scale + if (min == 0.0f) { + max = SMALL_SCALE_THRESHOLD * (qmax - qmin); + } else if (max == 0.0f) { + min = -SMALL_SCALE_THRESHOLD * (qmax - qmin); + } else { + float amplifier = SMALL_SCALE_THRESHOLD / org_scale; + min *= amplifier; + max *= amplifier; + } + } + + // Zero-point computation. + // First the initial floating-point computation. The zero-point can be + // determined from solving an affine equation for any known pair + // (real value, corresponding quantized value). + // We know two such pairs: (rmin, qmin) and (rmax, qmax). + // The arithmetic error on the zero point computed from either pair + // will be roughly machine_epsilon * (sum of absolute values of terms) + // so we want to use the variant that adds the smaller terms. + double zero_point_from_min = qmin - min / static_cast(scale); + double zero_point_from_max = qmax - max / static_cast(scale); + double zero_point_from_min_error = + std::abs(qmin) - std::abs(min / static_cast(scale)); + double zero_point_from_max_error = + std::abs(qmax) - std::abs(max / static_cast(scale)); + double initial_zero_point = + zero_point_from_min_error < zero_point_from_max_error + ? zero_point_from_min + : zero_point_from_max; + + // for symmetric quantization (preserve_sparsity == true), we force zero_point + // to be a middle value between qmin and qmax. + // If either min or max is 0, then we just use 0 as zero_point. + if (min < 0 && max > 0 && preserve_sparsity) { + initial_zero_point = static_cast(qmin + qmax) / 2; + } + + // Now we need to nudge the zero point to be an integer + // (our zero points are integer, and this is motivated by the requirement + // to be able to represent the real value "0" exactly as a quantized value, + // which is required in multiple places, for example in Im2col with zero + // padding). + int32_t nudged_zero_point = 0; + if (initial_zero_point < qmin) { + nudged_zero_point = qmin; + } else if (initial_zero_point > qmax) { + nudged_zero_point = qmax; + } else { + nudged_zero_point = nearbyint(initial_zero_point); + } + + TensorQuantizationParams result; + result.scale = scale; + result.zero_point = nudged_zero_point; + return result; +} + +// This function helps to convert the Conv1D dimensions usable by the Conv2d op. +constexpr int64_t kConv1dSqueezeDim = 0; +[[maybe_unused]] static torch::List MakeArgForConv1d( + const torch::List& arg, + int64_t base_value) { + TORCH_CHECK(!arg.empty(), "Argument must have elements."); + torch::List result({arg.get(0), base_value}); + if (arg.size() == 1) { + result[1] = arg.get(0); + } else { + result[1] = arg.get(1); + } + result[kConv1dSqueezeDim] = base_value; + return result; +} + +// The range for using FP16 quantization of weights requires that the elements +// should be in the range of [5.96e-8, 65504]. If it is out of range, then the +// number will be saturated to max or min representable values by FP16. +inline void HandleWeightsSaturation(int64_t N, float* weight) { + const float kFp16Max = RawUint16ToFp16(0x7BFF); + bool found_out_of_range = false; + for (const auto i : c10::irange(N)) { + bool saturate = CheckAndSaturate(kFp16Max, weight + i); + if (saturate) { + found_out_of_range = true; + } + } + if (found_out_of_range) { + TORCH_WARN("FOUND weight out of range "); + } +} + +// Util function for quantizing bias. +inline at::Tensor QuantizeBias( + bool is_per_channel, + const at::Tensor& bias, + const at::Tensor& weight_contig, + double input_scale) { + at::Tensor qbias; + if (is_per_channel) { + auto bias_quant_scales = + weight_contig.q_per_channel_scales() * input_scale; + auto bias_zp = at::zeros(bias_quant_scales.sizes(), c10::kInt); + qbias = at::native::quantize_per_channel( + bias, bias_quant_scales, bias_zp, 0, c10::kQInt32); + } else { + qbias = at::native::quantize_per_tensor( + bias, weight_contig.q_scale() * input_scale, 0, c10::kQInt32); + } + return qbias; +} + +} // namespace quant_utils diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/QuantizedOps.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/QuantizedOps.h new file mode 100644 index 0000000000000000000000000000000000000000..f39e614e0a3eaef6d49dab1d833f224f00adb53c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/QuantizedOps.h @@ -0,0 +1,256 @@ +#pragma once +#include +#include +#include +#include +#include +#include + +namespace at::native { + +using qrelu_fn = void (*)(const at::Tensor& /*qx*/, at::Tensor& /*qy*/); +using qrelu_leaky_fn = void (*)(Tensor& /*out*/, const Tensor& /*qx*/, + const Scalar& /*negval_*/); +using qgelu_fn = void (*)(const at::Tensor& /*qx*/, at::Tensor& /*qy*/, GeluType /* approximate */); +using qsigmoid_fn = void (*)(const at::Tensor& /*qx*/, at::Tensor& /*qy*/, double output_scale, int64_t output_zero_point); +using qhardsigmoid_fn = void (*)(const at::Tensor& /*qx*/, at::Tensor& /*qy*/); +using qclamp_fn = void (*)( + const at::Tensor& /*qx*/, + const Scalar& min, + const Scalar& max, + at::Tensor& /*qy*/); +using qclamp_minmax_fn = void (*)( + const at::Tensor& /*qx*/, + const Scalar& /*min or max*/, + at::Tensor& /*qy*/); +using qthreshold_fn = void (*)( + const at::Tensor& /*qx*/, + const Scalar& threshold, + const Scalar& value, + at::Tensor& /*qy*/); +using qtanh_fn = void (*)(const at::Tensor& /*qx*/, at::Tensor& /*qy*/); +using qelu_fn = void(*)( + const at::Tensor& /*qx*/, + const Scalar& /*alpha*/, + const Scalar& /*scale*/, + const Scalar& /*input_scale*/, + at::Tensor& /*qy*/); +using qbinary_fn = + void (*)(Tensor& /*out*/, const Tensor& /*self*/, const Tensor& /*other*/); +using qadd_scalar_fn = + void (*)(Tensor& /*out*/, const Tensor& /*self*/, const Scalar& other /*other*/); +using qhardswish_fn = void (*)(const at::Tensor& /*qx*/, at::Tensor& /*qy*/); +using qdropout_fn = void(*)( + const at::Tensor& /*qx*/, + const Scalar& /*p*/, + bool training /*training*/, + at::Tensor& /*qy*/); +using qmaxpool_2d_fn = void (*)( + const Tensor& qx, + int64_t iC, // input/output channels + int64_t iH, + int64_t iW, // input sizes + int64_t oH, + int64_t oW, // output sizes + int64_t kH, + int64_t kW, // kernel size + int64_t sH, + int64_t sW, // strides + int64_t pH, + int64_t pW, // padding + int64_t dH, + int64_t dW, // dilation + Tensor& qy); +using qmaxpool_3d_fn = void (*)( + const Tensor& qx, + int64_t iC, // input/output channels + int64_t iT, + int64_t iH, + int64_t iW, // input sizes + int64_t oT, + int64_t oH, + int64_t oW, // output sizes + int64_t kT, + int64_t kH, + int64_t kW, // kernel size + int64_t sT, + int64_t sH, + int64_t sW, // strides + int64_t pT, + int64_t pH, + int64_t pW, // padding + int64_t dT, + int64_t dH, + int64_t dW, // dilation + Tensor& qy); +using qadaptive_avg_pool2d_fn = void (*)( + const Tensor& qx, + Tensor& qy, + int64_t sizeB, + int64_t sizeC, + int64_t isizeH, + int64_t isizeW, + int64_t osizeH, + int64_t osizeW, + int64_t istrideB, + int64_t istrideC, + int64_t istrideH, + int64_t istrideW); +using qadaptive_avg_pool3d_fn = void (*)( + const Tensor& qx, + Tensor& qy, + int64_t sizeB, + int64_t sizeC, + int64_t isizeD, + int64_t isizeH, + int64_t isizeW, + int64_t osizeD, + int64_t osizeH, + int64_t osizeW, + int64_t istrideB, + int64_t istrideC, + int64_t istrideD, + int64_t istrideH, + int64_t istrideW); +using qavg_pool2d_fn = void (*)( + const Tensor& qx, + Tensor& qy, + int64_t nBatch, + int64_t nInputPlane, + int64_t inputWidth, + int64_t inputHeight, + int64_t outputWidth, + int64_t outputHeight, + int kW, + int kH, + int dW, + int dH, + int padW, + int padH, + bool count_include_pad, + std::optional divisor_override); + +using qavg_pool3d_fn = void (*)( + const Tensor& qx, + Tensor& qy, + int64_t nBatch, + int64_t nInputPlane, + int64_t inputWidth, + int64_t inputHeight, + int64_t inputDepth, + int64_t outputWidth, + int64_t outputHeight, + int64_t outputDepth, + int kW, + int kH, + int kD, + int dW, + int dH, + int dD, + int padW, + int padH, + int padD, + bool count_include_pad, + std::optional divisor_override); + +using qupsample_bilinear2d_fn = void (*)( + Tensor& output, + const Tensor& input, + int64_t input_height, + int64_t input_width, + int64_t output_height, + int64_t output_width, + int64_t nbatch, + int64_t channels, + bool align_corners, + std::optional scales_h, + std::optional scales_w); + +using qcat_nhwc_fn = Tensor (*)( + const MaterializedITensorListRef& qxs, + int64_t dim, + double scale, + int64_t zero_point); +using qtopk_fn = void(*)(Tensor&, Tensor&, const Tensor&, int64_t, int64_t, bool, bool); + +using qbatch_norm_fn = void(*)(int64_t, int64_t, int64_t, int64_t, int64_t, const Tensor&, const Tensor&, const Tensor&, Tensor&); + +using qnormalize_fn = void (*)( + const Tensor& /* X */, + const Tensor& /* gamma */, + const Tensor& /* beta */, + bool /* affine_per_channel */, + int /* num_channels */, + int /* num_groups */, + int64_t /* M */, + int64_t /* N */, + double /* eps */, + Tensor* /* Y */); + +using qmean_inner_dim_fn = void (*)( + const Tensor& /* X */, + OptionalIntArrayRef /* opt_dim */, + bool /* keepdim */, + std::optional /* opt_dtype */, + Tensor& /* Y */); + +using qstd_inner_dim_fn = void (*)( + const Tensor& /* X */, + OptionalIntArrayRef /* dim */, + const std::optional& /* correction */, + bool /* keepdim */, + Tensor& /* Y */); + +using qnormalize_nhwc_fn = void (*)( + const Tensor& /* X */, + const Tensor& /* gamma */, + const Tensor& /* beta */, + bool /* affine_per_channel */, + int /* num_channels */, + int /* num_groups */, + int64_t /* M */, + int64_t /* N */, + double /* eps */, + Tensor* /* Y */); + +using qprelu_fn = void (*)(Tensor& /*out*/, const Tensor& /*qx*/, + const Tensor& /*qw*/); + +DECLARE_DISPATCH(qadaptive_avg_pool2d_fn, qadaptive_avg_pool2d_nhwc_stub) +DECLARE_DISPATCH(qadaptive_avg_pool3d_fn, qadaptive_avg_pool3d_ndhwc_stub) +DECLARE_DISPATCH(qadd_scalar_fn, qadd_scalar_relu_stub) +DECLARE_DISPATCH(qadd_scalar_fn, qadd_scalar_stub) +DECLARE_DISPATCH(qavg_pool2d_fn, qavg_pool2d_nhwc_stub) +DECLARE_DISPATCH(qavg_pool3d_fn, qavg_pool3d_nhwc_stub) +DECLARE_DISPATCH(qbatch_norm_fn, qbatch_norm_relu_stub) +DECLARE_DISPATCH(qbatch_norm_fn, qbatch_norm_stub) +DECLARE_DISPATCH(qbinary_fn, qadd_relu_stub) +DECLARE_DISPATCH(qbinary_fn, qadd_stub) +DECLARE_DISPATCH(qbinary_fn, qmul_relu_stub) +DECLARE_DISPATCH(qbinary_fn, qmul_stub) +DECLARE_DISPATCH(qcat_nhwc_fn, qcat_nhwc_stub) +DECLARE_DISPATCH(qcat_nhwc_fn, qcat_relu_nhwc_stub) +DECLARE_DISPATCH(qclamp_fn, qclamp_stub) +DECLARE_DISPATCH(qclamp_minmax_fn, qclamp_min_stub) +DECLARE_DISPATCH(qclamp_minmax_fn, qclamp_max_stub) +DECLARE_DISPATCH(qelu_fn, qelu_stub) +DECLARE_DISPATCH(qhardsigmoid_fn, qhardsigmoid_stub) +DECLARE_DISPATCH(qhardswish_fn, qhardswish_stub) +DECLARE_DISPATCH(qdropout_fn, qdropout_stub) +DECLARE_DISPATCH(qmaxpool_2d_fn, qmaxpool_2d_nhwc_stub) +DECLARE_DISPATCH(qmaxpool_3d_fn, qmaxpool_3d_nthwc_stub) +DECLARE_DISPATCH(qnormalize_fn, quantized_normalize_stub) +DECLARE_DISPATCH(qnormalize_nhwc_fn, quantized_groupnorm_nhwc_stub) +DECLARE_DISPATCH(qrelu_fn, qrelu_stub) +DECLARE_DISPATCH(qrelu_leaky_fn, qrelu_leaky_stub) +DECLARE_DISPATCH(qgelu_fn, qgelu_stub) +DECLARE_DISPATCH(qsigmoid_fn, qsigmoid_stub) +DECLARE_DISPATCH(qtanh_fn, qtanh_stub) +DECLARE_DISPATCH(qthreshold_fn, qthreshold_stub) +DECLARE_DISPATCH(qtopk_fn, qtopk_stub) +DECLARE_DISPATCH(qupsample_bilinear2d_fn, qupsample_bilinear2d_nhwc_stub) +DECLARE_DISPATCH(qmean_inner_dim_fn, qmean_inner_dim_stub) +DECLARE_DISPATCH(qstd_inner_dim_fn, qstd_inner_dim_stub) +DECLARE_DISPATCH(qprelu_fn, qprelu_stub) + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/RuyUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/RuyUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..ea91cdffdf8a1335cd8a91f3af9db8026f4d5649 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/RuyUtils.h @@ -0,0 +1,17 @@ +#pragma once + +#ifdef USE_RUY_QMATMUL + +#include + +namespace at::native::ruy_utils { + +ruy::Context* get_ruy_context(); + +void quantize_multiplier(double scale, + int* multiplier_fixedpoint, + int* multiplier_exponent); + +} // namespace at::native::ruy_utils + +#endif // USE_RUY_QMATMUL diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/XnnpackUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/XnnpackUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..05616337dc58d23513cd3423dafa440b4e19ec6d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/XnnpackUtils.h @@ -0,0 +1,331 @@ +#pragma once + +#ifdef USE_XNNPACK +#include + +#include +#include + +using xnnpack_operator = at::native::xnnpack::Operator; + +namespace at::native::xnnp_utils { + +/* + * Return shape in the same order as the memory format + * e.g. channels_last will return NHWC instead of NCHW + */ +std::vector get_mem_format_aware_shape(const at::Tensor& in); + +/* + * Input is always int8_t, output can be [int8_t, uint8_t]. + * input + offset = output + * int8_t + 128 = uint8_t + * int8_t + 0 = int8_t + */ +template +void q8_copy_int8_weight_and_add_offset(const at::Tensor& in, at::Tensor& out); + +template +Tensor convert_conv_weights_to_channel_last_tensor( + const at::Tensor& src, + int groups, + bool transpose); + +/* + * Series of create wrapper functions to call xnn_create_[de]conv* functions. + */ +C10_ALWAYS_INLINE +enum xnn_status xnnp_create_convolution2d_nhwc( + uint32_t pad_top, + uint32_t pad_right, + uint32_t pad_bottom, + uint32_t pad_left, + uint32_t kernel_h, + uint32_t kernel_w, + uint32_t stride_h, + uint32_t stride_w, + uint32_t dilation_h, + uint32_t dilation_w, + uint32_t groups, + size_t group_input_channels, + size_t group_output_channels, + size_t ip_chan_stride, + size_t op_chan_stride, + int8_t izp, + float ip_scale, + int8_t kzp, + const float* k_scales, + const int8_t* kernel, + const int32_t* bias, + int8_t ozp, + float op_scale, + int8_t op_min, + int8_t op_max, + uint32_t flags, + xnn_operator_t* op, + bool per_channel, + bool transpose) { + /* Symmetric quantization forces kzp = 0 */ + TORCH_CHECK(!kzp, "XNNPACK Q[SC]8 conv kernels expects kernel zero point to be zero." + "But got: ", kzp); + + if (transpose) { + TORCH_CHECK(!per_channel, "XNNPACK Q[SC]8 does not have a per channel deconvolution!"); + return xnn_create_deconvolution2d_nhwc_qs8( + pad_top, /* uint32_t output_padding_top */ + pad_right, /* uint32_t output_padding_right */ + pad_bottom, /* uint32_t output_padding_bottom */ + pad_left, /* uint32_t output_padding_left */ + kernel_h, /* uint32_t kernel_height */ + kernel_w, /* uint32_t kernel_width */ + stride_h, /* uint32_t stride_height */ + stride_w, /* uint32_t stride_width */ + dilation_h, /* uint32_t dilation_height */ + dilation_w, /* uint32_t dilation_width */ + groups, /* uint32_t groups */ + group_input_channels, /* size_t group_input_channels */ + group_output_channels, /* size_t group_output_channels */ + ip_chan_stride, /* size_t input_pixel_stride */ + op_chan_stride, /* size_t output_pixel_stride */ + izp, /* int8_t input_zero_point */ + ip_scale, /* float input_scale */ + k_scales[0], /* float kernel_scale */ + kernel, /* const int8_t* kernel */ + bias, /* const int32_t* bias */ + ozp, /* int8_t output_zero_point */ + op_scale, /* float output_scale */ + op_min, /* int8_t output_min */ + op_max, /* int8_t output_max */ + flags, /* uint32_t flags */ + nullptr, /* xnn_caches_t caches */ + nullptr, /* xnn_weights_cache_t weights_cache */ + op); /* xnn_operator_t* deconvolution_op_out */ + + } + + if (!per_channel) { + return xnn_create_convolution2d_nhwc_qs8( + pad_top, /* uint32_t input_padding_top */ + pad_right, /* uint32_t input_padding_right */ + pad_bottom, /* uint32_t input_padding_bottom */ + pad_left, /* uint32_t input_padding_left */ + kernel_h, /* uint32_t kernel_height */ + kernel_w, /* uint32_t kernel_width */ + stride_h, /* uint32_t subsampling_height */ + stride_w, /* uint32_t subsampling_width */ + dilation_h, /* uint32_t dilation_height */ + dilation_w, /* uint32_t dilation_width */ + groups, /* uint32_t groups */ + group_input_channels, /* size_t group_input_channels */ + group_output_channels, /* size_t group_output_channels*/ + ip_chan_stride, /* size_t input_channel_stride */ + op_chan_stride, /* size_t output_channel_stride */ + izp, /* int8_t input_zero_point */ + ip_scale, /* float input_scale */ + k_scales[0], /* float kernel_scale */ + kernel, /* const int8_t* kernel */ + bias, /* const int32_t* bias */ + ozp, /* int8_t output_zero_point */ + op_scale, /* float output_scale */ + op_min, /* int8_t output_min */ + op_max, /* int8_t output_max */ + flags, /* uint32_t flags */ + nullptr, /* xnn_caches_t caches */ + nullptr, /* xnn_weights_cache_t weights_cache */ + op); /* xnn_operator_t* convolution_op_out */ + } else { /* per_channel */ + return xnn_create_convolution2d_nhwc_qs8_qc8w( + pad_top, /* uint32_t input_padding_top */ + pad_right, /* uint32_t input_padding_right */ + pad_bottom, /* uint32_t input_padding_bottom */ + pad_left, /* uint32_t input_padding_left */ + kernel_h, /* uint32_t kernel_height */ + kernel_w, /* uint32_t kernel_width */ + stride_h, /* uint32_t subsampling_height */ + stride_w, /* uint32_t subsampling_width */ + dilation_h, /* uint32_t dilation_height */ + dilation_w, /* uint32_t dilation_width */ + groups, /* uint32_t groups */ + group_input_channels, /* size_t group_input_channels */ + group_output_channels, /* size_t group_output_channels*/ + ip_chan_stride, /* size_t input_channel_stride */ + op_chan_stride, /* size_t output_channel_stride */ + izp, /* int8_t input_zero_point */ + ip_scale, /* float input_scale */ + k_scales, /* const float* kernel_scale */ + kernel, /* const int8_t* kernel */ + bias, /* const int32_t* bias */ + ozp, /* int8_t output_zero_point */ + op_scale, /* float output_scale */ + op_min, /* int8_t output_min */ + op_max, /* int8_t output_max */ + flags, /* uint32_t flags */ + nullptr, /* xnn_caches_t caches */ + nullptr, /* xnn_weights_cache_t weights_cache */ + op); /* xnn_operator_t* convolution_op_out */ + } +} + +/* + * Series of reshape wrapper functions to call xnn_reshape_[de]conv* functions. + */ +C10_ALWAYS_INLINE +enum xnn_status xnnp_reshape_convolution2d_nhwc( + xnn_operator_t op, + size_t batch, + size_t in_h, + size_t in_w, + pthreadpool_t pt_pool, + bool per_channel = false, + bool transpose = false, + uint32_t adj_h = 0, + uint32_t adj_w = 0) { + if(transpose) { + TORCH_CHECK(!per_channel, "XNNPACK Q[SC]8 does not have a per channel deconvolution!"); + return xnn_reshape_deconvolution2d_nhwc_qs8( + op, /* xnn_operator_t deconvolution_op */ + batch, /* size_t batch_size */ + in_h, /* size_t input_height */ + in_w, /* size_t input_width */ + adj_h, /* uint32_t adjustment_height */ + adj_w, /* uint32_t adjustment_width */ + nullptr, /* size_t* output_height_out */ + nullptr, /* size_t* output_width_out */ + pt_pool); /* pthreadpool_t threadpool */ + } + + size_t workspace_size = SIZE_MAX; + size_t workspace_alignment = SIZE_MAX; + + if (!per_channel) { + return xnn_reshape_convolution2d_nhwc_qs8( + op, /* xnn_operator_t convolution_op */ + batch, /* size_t batch_size */ + in_h, /* size_t input_height */ + in_w, /* size_t input_width */ + &workspace_size, /* size_t* workspace_size */ + &workspace_alignment, /* size_t* workspace_alignment */ + nullptr, /* size_t* output_height_out */ + nullptr, /* size_t* output_width_out */ + pt_pool); /* pthreadpool_t threadpool */ + } else { /* per_channel */ + return xnn_reshape_convolution2d_nhwc_qs8_qc8w( + op, /* xnn_operator_t convolution_op */ + batch, /* size_t batch_size */ + in_h, /* size_t input_height */ + in_w, /* size_t input_width */ + &workspace_size, /* size_t* workspace_size */ + &workspace_alignment, /* size_t* workspace_alignment */ + nullptr, /* size_t* output_height_out */ + nullptr, /* size_t* output_width_out */ + pt_pool); /* pthreadpool_t threadpool */ + } +} + + +/* + * Series of setup wrapper functions to call xnn_setup_[de]conv* functions. + */ +C10_ALWAYS_INLINE +enum xnn_status xnnp_setup_convolution2d_nhwc( + xnn_operator_t op, + const int8_t* inp, + int8_t* outp, + bool per_channel = false, + bool transpose = false) { + if(transpose) { + TORCH_CHECK(!per_channel, "XNNPACK Q[SC]8 does not have a per channel deconvolution!"); + + return xnn_setup_deconvolution2d_nhwc_qs8( + op, /* xnn_operator_t deconvolution_op */ + inp, /* const int8_t* input */ + outp); /* int8_t* output */ + } + + if (!per_channel) { + return xnn_setup_convolution2d_nhwc_qs8( + op, /* xnn_operator_t deconvolution_op */ + nullptr, /* void workspace */ + inp, /* const int8_t* input */ + outp); /* int8_t* output */ + } else { /* per_channel */ + return xnn_setup_convolution2d_nhwc_qs8_qc8w( + op, /* xnn_operator_t deconvolution_op */ + nullptr, /* void workspace */ + inp, /* const int8_t* input */ + outp); /* int8_t* output */ + } +} + + +/* + * Series of wrapper functions to call xnn_create* and xnn_setup* + * functions for linear + */ +C10_ALWAYS_INLINE +enum xnn_status xnnp_create_fully_connected_nc( + size_t input_channels, + size_t output_channels, + size_t input_stride, + size_t output_stride, + int8_t input_zero_point, + float input_scale, + int8_t kernel_zero_point, + float kernel_scale, + const int8_t* kernel, + const int32_t* bias, + int8_t output_zero_point, + float output_scale, + int8_t output_min, + int8_t output_max, + uint32_t flags, + xnn_operator_t* fully_connected_op_out) { + /* Symmetric quantization forces kzp = 0 */ + TORCH_CHECK(!kernel_zero_point, "XNNPACK QS8 linear kernel expects kernel zero point to be zero." + "But got: ", kernel_zero_point); + return xnn_create_fully_connected_nc_qs8( + input_channels, /* size_t input_channels */ + output_channels, /* size_t output_channels */ + input_stride, /* size_t input_stride */ + output_stride, /* size_t output_stride */ + input_zero_point, /* int8_t input_zero_point */ + input_scale, /* float input_scale */ + kernel_scale, /* float kernel_scale */ + kernel, /* const int8_t* kernel */ + bias, /* const int32_t* bias */ + output_zero_point, /* int8_t output_zero_point */ + output_scale, /* float output_scale */ + output_min, /* int8_t output_min */ + output_max, /* int8_t output_max */ + flags, /* uint32_t flags */ + nullptr, /* xnn_caches_t caches */ + nullptr, /* xnn_weights_cache_t */ + fully_connected_op_out); /* xnn_operator_t* fully_connected_op_out */ +} + +C10_ALWAYS_INLINE +enum xnn_status xnnp_reshape_fully_connected_nc( + xnn_operator_t fully_connected_op, + size_t batch_size, + pthreadpool_t threadpool) { + return xnn_reshape_fully_connected_nc_qs8( + fully_connected_op, /* xnn_operator_t fully_connected_op */ + batch_size, /* size_t batch_size */ + threadpool); /* pthreadpool_t threadpool */ +} + +C10_ALWAYS_INLINE +enum xnn_status xnnp_setup_fully_connected_nc( + xnn_operator_t fully_connected_op, + const int8_t* input, + int8_t* output) { + return xnn_setup_fully_connected_nc_qs8( + fully_connected_op, /* xnn_operator_t fully_connected_op */ + input, /* const int8_t* input */ + output /* int8_t* output */ + ); +} + +} // namespace at::native::xnnp_utils + +#endif // USE_XNNPACK diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/conv_serialization.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/conv_serialization.h new file mode 100644 index 0000000000000000000000000000000000000000..3edd398fa789a7399700ce12d320025e6af4cfca --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/conv_serialization.h @@ -0,0 +1,417 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#if !defined(__s390x__) && !defined(__powerpc__) +#include +#endif + +#ifndef AT_PER_OPERATOR_HEADERS +#include +#else +#include +#endif + + +#include + +/* Convolution prepacked parameters serialization. + * + * Version 1 + * + * - Fields: + * 1. weight + * 2. bias + * 3. stride x kSpatialDim + * 4. padding x kSpatialDim + * 5. dilation x kSpatialDim + * 6. groups + * + * Version 2 + * + * - Fields: + * 0. version (string) + * 1. list of non-optional tensors + * 0: packed parameters (int16_t) + * - kSpatialDim + * - stride x kSpatialDim + * - padding x kSpatialDim + * - dilation x kSpatialDim + * - output_padding x kSpatialDim + * - groups + * - transpose (0 or 1) + * 1: weight + * 2. list of optional tensors + * 0: bias + * + * Version 3 + * + * - Fields: + * 0. version (int64_t) + * 1. list of int64_t configuration values + * - kSpatialDim + * - stride x kSpatialDim + * - padding x kSpatialDim + * - dilation x kSpatialDim + * - output_padding x kSpatialDim + * - groups + * - flags (bitmask) + * - (1 << 0) transpose (1 = yes) + * 2. list of optional tensors + * 0: None (helps with type inference) + * 1: weight (this must be present) + * 2: bias + */ + +using ConvParamsSerializationTypeV2 = std::tuple< + // version, for versions 2 and up + std::string, + // non-optional tensors + std::vector, + // optional tensors + std::vector>>; + +using ConvParamsSerializationTypeV3 = std::tuple< + // version, int for versions 3 and up + int64_t, + // configuration values + std::vector, + // optional tensors + std::vector>>; + +// Parses any historical conv packed params format into +// the current format. +template +ConvParamsSerializationTypeV3 parse_conv_serialized_state(const c10::IValue& v) { + + // determine the version based on IValue contents + int version = -1; + if (v.isTuple()) { + const auto& elements = v.toTupleRef().elements(); + if (!elements.empty()) { + auto firstElement = elements[0]; + if (firstElement.isTensor()) { + version = 1; + } else if (firstElement.isString()) { + const std::string& version_str = firstElement.toStringRef(); + // note: not parsing the string to automatically handle bad + // inputs + if (version_str == "2") { + version = 2; + } + } else if (firstElement.isInt()) { + auto raw_version = firstElement.toInt(); + if (raw_version == 3) { + version = 3; + } + } + } + } + TORCH_INTERNAL_ASSERT(version != -1, "Unable to parse serialization version"); + + if (version == 1) { + // version 1 - convert to version 3 manually + + const auto& elements = v.toTupleRef().elements(); + + at::Tensor weight = elements[0].toTensor(); + std::optional bias = elements[1].toOptional(); + torch::List stride_x_kSpatialDim = elements[2].toTensorList(); + torch::List padding_x_kSpatialDim = elements[3].toTensorList(); + torch::List dilation_x_kSpatialDim = elements[4].toTensorList(); + at::Tensor groups = elements[5].toTensor(); + + std::vector config_vals; + config_vals.reserve( + stride_x_kSpatialDim.size() + padding_x_kSpatialDim.size() + + dilation_x_kSpatialDim.size() + kSpatialDim + 3); + config_vals.push_back(kSpatialDim); + for (const auto i : c10::irange(stride_x_kSpatialDim.size())) { + auto const & stride = stride_x_kSpatialDim.get(i); + config_vals.push_back(stride[0].item()); + } + for (const auto i : c10::irange(padding_x_kSpatialDim.size())) { + auto const &padding = padding_x_kSpatialDim.get(i); + config_vals.push_back(padding[0].item()); + } + for (const auto i : c10::irange(dilation_x_kSpatialDim.size())) { + auto const &dilation = dilation_x_kSpatialDim.get(i); + config_vals.push_back(dilation[0].item()); + } + // output_padding does not exist in v1, so we fill in a default value + for ([[maybe_unused]] const auto i : c10::irange(kSpatialDim)) { + config_vals.push_back(0); + } + config_vals.push_back(groups[0].item()); + // transpose does not exist in v1, so we fill in a default value + config_vals.push_back(0); + + std::vector> tensors; + tensors.emplace_back(); + tensors.emplace_back(weight); + tensors.emplace_back(bias); + + int64_t version = 3; + return std::tie(version, config_vals, tensors); + } else if (version == 2) { + // version 2 + const auto& elements = v.toTupleRef().elements(); + std::vector non_optional = elements[1].toTensorList().vec(); + std::vector> optional; + + if (elements[2].isTensorList()) { + for (const auto& elem : elements[2].toTensorList()) { + optional.emplace_back(static_cast(elem)); + } + } else { + for (const auto& elem : elements[2].toList()) { + optional.emplace_back(static_cast(elem).toOptional()); + } + } + // create default optional value for bias + if (optional.empty()) { + optional.emplace_back(); + } + + auto config_a = non_optional[0].accessor(); + std::vector config_vals; + config_vals.reserve(config_a.size(0)); + for (const auto i : c10::irange(config_a.size(0))) { + config_vals.emplace_back(config_a[i]); + } + + auto weight = non_optional[1]; + auto bias = optional[0]; + + std::vector> tensors; + tensors.emplace_back(); + tensors.emplace_back(weight); + tensors.emplace_back(bias); + + int64_t version = 3; + return std::tie(version, config_vals, tensors); + } else if (version == 3) { + return v.to(); + } else { + TORCH_INTERNAL_ASSERT(false, "Unexpected serialized qconv version: ", + version); + } +} + +#define QCONV_SERIALIZATION_VERSION 2 + +#if QCONV_SERIALIZATION_VERSION == 2 +using ConvParamsSerializationType = ConvParamsSerializationTypeV2; + +template +ConvParamsSerializationTypeV2 serialize_conv( + const c10::intrusive_ptr>& params) { + + std::string version = "2"; + std::vector non_optional; + std::vector> optional; + + // create a packed int8_t tensor for conv params + std::vector params_vec; + params_vec.push_back(kSpatialDim); + auto stride = params->stride().vec(); + params_vec.insert(params_vec.end(), stride.begin(), stride.end()); + auto padding = params->padding().vec(); + params_vec.insert(params_vec.end(), padding.begin(), padding.end()); + auto dilation = params->dilation().vec(); + params_vec.insert(params_vec.end(), dilation.begin(), dilation.end()); + auto output_padding = params->output_padding().vec(); + params_vec.insert(params_vec.end(), output_padding.begin(), + output_padding.end()); + params_vec.push_back(params->groups()); + params_vec.push_back(params->transpose()); + int64_t vec_size = params_vec.size(); + at::Tensor params_tensor = at::from_blob( + params_vec.data(), {vec_size}, + at::TensorOptions().dtype(at::kShort)) + // clone to retain ownership of the data + .clone(); + + auto [weight, bias] = params->unpack(); + + non_optional.emplace_back(std::move(params_tensor)); + non_optional.emplace_back(std::move(weight)); + optional.emplace_back(std::move(bias)); + + return std::tie(version, non_optional, optional); +} + +#elif QCONV_SERIALIZATION_VERSION == 3 +using ConvParamsSerializationType = ConvParamsSerializationTypeV3; + +template +ConvParamsSerializationTypeV3 serialize_conv( + const c10::intrusive_ptr>& params) { + std::vector config_vals; + config_vals.push_back(kSpatialDim); + auto stride = params->stride().vec(); + config_vals.insert(config_vals.end(), stride.begin(), stride.end()); + auto padding = params->padding().vec(); + config_vals.insert(config_vals.end(), padding.begin(), padding.end()); + auto dilation = params->dilation().vec(); + config_vals.insert(config_vals.end(), dilation.begin(), dilation.end()); + auto output_padding = params->output_padding().vec(); + config_vals.insert(config_vals.end(), output_padding.begin(), + output_padding.end()); + config_vals.push_back(params->groups()); + config_vals.push_back(params->transpose()); + + auto [weight, bias] = params->unpack(); + + std::vector> tensors; + tensors.emplace_back(); + tensors.emplace_back(weight); + tensors.emplace_back(bias); + + int64_t version = 3; + return std::tie(version, config_vals, tensors); +} + +#else +#error "Invalid qconv serialization version." +#endif + +template +c10::intrusive_ptr> deserialize_conv( + ConvParamsSerializationTypeV3 state) { + auto & [version, config_vals, tensors] = state; + TORCH_INTERNAL_ASSERT(version == 3, "Unexpected serialized qconv version: ", version); + + TORCH_CHECK(tensors.size() == 3, "Wrong number of tensors", tensors.size()); + auto & weight = tensors[1]; + auto & bias [[maybe_unused]] = tensors[2]; + TORCH_INTERNAL_ASSERT(weight.has_value(), "Weight should always be present in serialized qconv."); + + torch::List stride, padding, output_padding, dilation; + // skip kSpatialDim + int idx = 1; + for ([[maybe_unused]] const auto i : c10::irange(kSpatialDim)) { + stride.emplace_back(config_vals.at(idx)); + idx++; + } + for ([[maybe_unused]] const auto i : c10::irange(kSpatialDim)) { + padding.emplace_back(config_vals.at(idx)); + idx++; + } + for ([[maybe_unused]] const auto i : c10::irange(kSpatialDim)) { + dilation.emplace_back(config_vals.at(idx)); + idx++; + } + for ([[maybe_unused]] const auto i : c10::irange(kSpatialDim)) { + TORCH_INTERNAL_ASSERT( + idx < static_cast(config_vals.size()), + "Unexpected index = ", + idx, + " for config_vals of size ", + config_vals.size()); + output_padding.emplace_back(config_vals.at(idx)); + idx++; + } + int64_t groups [[maybe_unused]] = config_vals.at(idx); + idx++; + int64_t flags [[maybe_unused]] = config_vals.at(idx); + idx++; + TORCH_INTERNAL_ASSERT(idx == static_cast(config_vals.size()), + "Unexpected length of config_vals, expected ", + idx, + " got ", + config_vals.size()); + + bool transpose [[maybe_unused]] = flags & (1 << 0); + + int64_t other_flags = flags & ~(1 << 0); + TORCH_INTERNAL_ASSERT(other_flags == 0, "Unexpected flags set in ", flags, "."); + + auto& ctx = at::globalContext(); + +#ifdef USE_FBGEMM + if (ctx.qEngine() == at::QEngine::X86) { +#if AT_MKLDNN_ENABLED() + bool use_onednn = onednn_utils::should_use_onednn_quant( + weight.value(), transpose, groups, output_padding); + if (use_onednn) { + return PackedConvWeightsOnednn::prepack( + std::move(weight.value()), + std::move(bias), + stride, + padding, + output_padding, + dilation, + groups, + transpose + ); + } +#endif + return PackedConvWeight::prepack( + std::move(weight.value()), + std::move(bias), + stride, + padding, + output_padding, + dilation, + groups, + transpose + ); + } // x86 +#endif + +#ifdef USE_FBGEMM + if (ctx.qEngine() == at::QEngine::FBGEMM) { + return PackedConvWeight::prepack( + std::move(weight.value()), + std::move(bias), + stride, + padding, + output_padding, + dilation, + groups, + transpose + ); + } +#endif // USE_FBGEMM +#ifdef USE_PYTORCH_QNNPACK + if (ctx.qEngine() == at::QEngine::QNNPACK) { + TORCH_CHECK( + kSpatialDim == 2, + "prepack/__setstate__: QNNPACK only supports Conv2d " + "now."); + return PackedConvWeightsQnnp::prepack( + std::move(weight.value()), + std::move(bias), + stride, + padding, + output_padding, + dilation, + groups, + transpose + ); + } +#endif // USE_PYTORCH_QNNPACK +#if AT_MKLDNN_ENABLED() + if (ctx.qEngine() == at::QEngine::ONEDNN) { + return PackedConvWeightsOnednn::prepack( + std::move(weight.value()), + std::move(bias), + stride, + padding, + output_padding, + dilation, + groups, + transpose + ); + } +#endif // AT_MKLDNN_ENABLED() +TORCH_CHECK( + false, + "Didn't find engine for when deserializing ConvPackedParams: ", + toString(ctx.qEngine())); +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/fbgemm_utils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/fbgemm_utils.h new file mode 100644 index 0000000000000000000000000000000000000000..e6d86cf03df130ba4a42efa61ab557a90f4fd898 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/fbgemm_utils.h @@ -0,0 +1,408 @@ +#pragma once + +#include +#include +#include +#include +#include + +#ifdef USE_FBGEMM +#include +C10_DIAGNOSTIC_PUSH_AND_IGNORED_IF_DEFINED("-Winconsistent-missing-destructor-override") +#include +C10_DIAGNOSTIC_POP() +#include + +// The struct for the packed weight matrix (PackBMatrix) and the corresponding +// column offsets used for the fully connect layer, which are both prepared in +// the prepacking step to save the computations in the inference. Note the +// column offsets include the sum of the B columns as well as the scalar term +// B_zero_point * K, whereas the row offsets created by +// PackAWithQuantRowOffset/PackAWithIm2Col/PackAWithRowOffset are only the sum +// of the A rows. The column offsets are needed for the asymmetric quantization +// (affine quantization) of input matrix. +// Note that in JIT mode we can think of a way to fuse col_offsets with bias. +struct TORCH_API PackedLinearWeight : public LinearPackedParamsBase { + PackedLinearWeight( + std::unique_ptr> w, + std::optional bias, + std::vector col_offsets, + std::vector w_scale, + std::vector w_zp, + c10::QScheme q_scheme) + : w(std::move(w)), + bias_(std::move(bias)), + col_offsets(std::move(col_offsets)), + w_scale(std::move(w_scale)), + w_zp(std::move(w_zp)), + q_scheme(std::move(q_scheme)) {} + std::unique_ptr> w; + std::optional bias_; + std::vector col_offsets; + std::vector w_scale; + std::vector w_zp; + c10::QScheme q_scheme; + + at::Tensor apply( + at::Tensor input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor apply_relu( + at::Tensor input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor& apply_out( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point, + at::Tensor& output) override; + + at::Tensor& apply_relu_out( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point, + at::Tensor& output) override; + + at::Tensor apply_with_input_q_dq_qweight_dq_output_fp32( + at::Tensor input, + double input_scale, + int64_t input_zero_point) override; + + at::Tensor apply_with_input_q_dq_qweight_dq_relu_output_fp32( + at::Tensor input, + double input_scale, + int64_t input_zero_point) override; + + at::Tensor apply_dynamic(at::Tensor input, bool reduce_range = false) + override; + + at::Tensor apply_dynamic_relu(at::Tensor input, bool reduce_range = false) + override; + + std::tuple> unpack() override; + + std::optional bias() override { + return bias_; + } + + static c10::intrusive_ptr prepack( + at::Tensor weight, + std::optional bias); + + private: + template + at::Tensor& apply_impl( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point, + at::Tensor& output); + + template + at::Tensor apply_with_input_q_dq_qweight_dq_output_fp32_impl( + const at::Tensor& input, + double input_scale, + int64_t input_zero_point); + + template + at::Tensor apply_dynamic_impl(at::Tensor input, bool reduce_range = false); +}; + +struct TORCH_API PackedLinearWeightFp16 : public LinearPackedParamsBase { + PackedLinearWeightFp16( + std::unique_ptr w, + std::optional bias) + : w(std::move(w)), bias_(std::move(bias)) {} + + std::unique_ptr w; + std::optional bias_; + + at::Tensor apply( + at::Tensor /*input*/, + double /*output_scale*/, + int64_t /*output_zero_point*/) override { + TORCH_INTERNAL_ASSERT(false); + } + at::Tensor apply_relu( + at::Tensor /*input*/, + double /*output_scale*/, + int64_t /*output_zero_point*/) override { + TORCH_INTERNAL_ASSERT(false); + } + + at::Tensor apply_dynamic(at::Tensor input, bool reduce_range = false) + override; + at::Tensor apply_dynamic_relu(at::Tensor input, bool reduce_range = false) + override; + + at::Tensor& apply_dynamic_out( + const at::Tensor& input, + at::Tensor& output, + bool reduce_range = false) override; + at::Tensor& apply_dynamic_relu_out( + const at::Tensor& input, + at::Tensor& output, + bool reduce_range = false) override; + + std::tuple> unpack() override; + + std::optional bias() override { + return bias_; + } + + static c10::intrusive_ptr prepack( + at::Tensor weight, + std::optional bias); + + void set_bias(std::optional bias) override; + + private: + template + at::Tensor& apply_dynamic_impl(const at::Tensor& input, at::Tensor& output); +}; + +template +struct TORCH_API PackedConvWeight : public ConvPackedParamsBase { + PackedConvWeight( + std::unique_ptr> w, + std::optional bias, + torch::List stride, + torch::List padding, + torch::List output_padding, + torch::List dilation, + int64_t groups, + uint8_t transpose, + std::vector col_offsets, + std::vector kernel, + std::vector w_scale, + std::vector w_zp, + c10::QScheme q_scheme) + : w(std::move(w)), + bias(std::move(bias)), + stride_(std::move(stride)), + padding_(std::move(padding)), + output_padding_(std::move(output_padding)), + dilation_(std::move(dilation)), + groups_(groups), + transpose_(transpose), + col_offsets(std::move(col_offsets)), + kernel(std::move(kernel)), + w_scale(std::move(w_scale)), + w_zp(std::move(w_zp)), + q_scheme(q_scheme) {} + + std::unique_ptr> w; + std::optional bias; + torch::List stride_; + torch::List padding_; + torch::List output_padding_; + torch::List dilation_; + int64_t groups_; + uint8_t transpose_; + std::vector col_offsets; + std::vector kernel; + std::vector w_scale; + std::vector w_zp; + c10::QScheme q_scheme; + + at::Tensor apply( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor apply_relu( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point) override; + + at::Tensor apply_dynamic( + const at::Tensor& input, + bool reduce_range) override; + + std::tuple> unpack() override; + + static c10::intrusive_ptr> prepack( + at::Tensor weight, + std::optional bias, + torch::List stride, + torch::List padding, + torch::List output_padding, + torch::List dilation, + int64_t groups, + bool transpose); + + const float* GetBiasData(at::Tensor* bias); + + void GetQuantizationParams( + float act_scale, + float out_scale, + std::vector* output_multiplier_float, + std::vector* act_times_w_scale); + + torch::List stride() const override { + return stride_; + } + + torch::List padding() const override { + return padding_; + } + + torch::List output_padding() const override { + return output_padding_; + } + + torch::List dilation() const override { + return dilation_; + } + + int64_t groups() const override { + return groups_; + } + + bool transpose() const override { + return (bool)transpose_; + } + + private: + template + at::Tensor apply_impl( + const at::Tensor& input, + double output_scale, + int64_t output_zero_point); +}; + +// PackWeight: Convert the weight from uint8 to int8. +inline void convert_uint8_int8( + int len, + const uint8_t* src_uint8, + int8_t* dst_int8) { + for (const auto i : c10::irange(len)) { + dst_int8[i] = static_cast(static_cast(src_uint8[i]) - 128); + } +} + +// UnpackWeight: Convert the weight from int8 to uint8. +inline void convert_int8_uint8( + int len, + const int8_t* src_int8, + uint8_t* dst_uint8) { + for (const auto i : c10::irange(len)) { + dst_uint8[i] = + static_cast(static_cast(src_int8[i]) + 128); + } +} + +namespace at::native::fbgemm_utils { + +template +fbgemm::conv_param_t MakeFbgemmConvParam( + int N, + int C, + int M, + const std::vector& image_shape, + int groups, + const std::vector& kernels, + const std::vector& strides, + const std::vector& pads, + const std::vector& dilations, + const std::vector& output_padding = std::vector(kSpatialDim, 0), + bool transposed = false); + +// TODO: Remove functions below when ChannelsLast3d is ready. +Tensor MakeStridedQTensorCPU( + const IntArrayRef& sizes, + const IntArrayRef& strides, + const TensorOptions& options, + QuantizerPtr quantizer); + +Tensor MakeEmptyAffineQuantizedChannelsLast3dTensor( + int64_t N, + int64_t C, + int64_t D, + int64_t H, + int64_t W, + const TensorOptions& options, + double scale, + int64_t zero_point); + +Tensor MakeEmptyPerChannelAffineQuantizedChannelsLast3dTensor( + int64_t N, + int64_t C, + int64_t D, + int64_t H, + int64_t W, + const TensorOptions& options, + const Tensor& scales, + const Tensor& zero_points); + +Tensor ConvertToChannelsLast3dTensor(const Tensor& src); + +template +Tensor TransposeConvTensorUnpackConversion(const Tensor& src, int groups); + +template +Tensor ConvertConvWeightsToChannelLastTensor( + const at::Tensor& src, + int groups, + bool transpose); +} // at::native::namespace fbgemm_utils + +#endif // USE_FBGEMM + +struct TORCH_API PackedEmbeddingBagWeight : public EmbeddingPackedParamsBase { + PackedEmbeddingBagWeight( + at::Tensor packed_w, + std::vector w_scale, + std::vector w_zp, + int64_t bit_rate, + c10::QScheme q_scheme, + int64_t version) + : packed_w(std::move(packed_w)), + w_scale(std::move(w_scale)), + w_zp(std::move(w_zp)), + bit_rate_(bit_rate), + q_scheme(q_scheme), + version_(version) { + if (!this->packed_w.is_contiguous()) { + this->packed_w = this->packed_w.contiguous(); + } + } + + at::Tensor packed_w; + std::vector w_scale; + std::vector w_zp; + int64_t bit_rate_; + c10::QScheme q_scheme; + int64_t version_; + + at::Tensor unpack() override; + static c10::intrusive_ptr prepack( + at::Tensor weight); + + int64_t bit_rate() const override { + return bit_rate_; + } + + int64_t version() const override { + return version_; + } + + at::Tensor embeddingbag_byte( + const at::Tensor& indices, + const std::optional& offsets, + bool pruned_weights, + const std::optional& per_sample_weights_, + const std::optional& compressed_indices_mapping, + bool include_last_offset, + bool is_embedding_op) override; + + at::Tensor embeddingbag_4bit( + const at::Tensor& indices, + const std::optional& offsets, + bool pruned_weights, + const std::optional& per_sample_weights_, + const std::optional& compressed_indices_mapping, + bool include_last_offset, + bool is_embedding_op) override; +}; diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/init_qnnpack.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/init_qnnpack.h new file mode 100644 index 0000000000000000000000000000000000000000..96dd2b3b274f31015c6e738a077e11bb1d38f6a1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/init_qnnpack.h @@ -0,0 +1,11 @@ +#pragma once + +#ifdef USE_PYTORCH_QNNPACK + +namespace at::native { + +void initQNNPACK(); + +} // namespace at::native + +#endif diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qconv.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qconv.h new file mode 100644 index 0000000000000000000000000000000000000000..0be160aa3522e80dd378729e8bb787d3619f683e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qconv.h @@ -0,0 +1,100 @@ +#pragma once +#include +#include + +namespace at { +namespace native { + +class QConvoneDNN final { + public: + + C10_API static at::Tensor run_pointwise( + at::Tensor act, // contains quantized values but not QTensor + double act_scale, + int64_t act_zero_point, + at::Tensor weight, // contains quantized values but not QTensor + at::Tensor weight_scales, + at::Tensor weight_zero_points, + std::optional bias, + torch::List stride, + torch::List padding, + torch::List dilation, + int64_t groups, + double output_scale, + int64_t output_zero_point, + std::optional output_dtype, + std::string_view attr, + torch::List> scalars, + std::optional algorithm); + + C10_API static at::Tensor run_pointwise_tensor( + at::Tensor act, // contains quantized values but not QTensor + at::Tensor act_scale, + at::Tensor act_zero_point, + at::Tensor weight, // contains quantized values but not QTensor + at::Tensor weight_scales, + at::Tensor weight_zero_points, + std::optional bias, + torch::List stride, + torch::List padding, + torch::List dilation, + int64_t groups, + double output_scale, + int64_t output_zero_point, + std::optional output_dtype, + std::string_view attr, + torch::List> scalars, + std::optional algorithm); + + C10_API static at::Tensor run_pointwise_binary( + at::Tensor act, // contains quantized values but not QTensor + double act_scale, + int64_t act_zero_point, + at::Tensor weight, // contains quantized values but not QTensor + at::Tensor weight_scales, + at::Tensor weight_zero_points, + at::Tensor accum, // contains quantized values but not QTensor + std::optional bias, + torch::List stride, + torch::List padding, + torch::List dilation, + int64_t groups, + double output_scale, + int64_t output_zero_point, + std::optional output_dtype, + double accum_scale, + int64_t accum_zero_point, + std::string_view binary_attr, + std::optional alpha, + std::optional unary_attr, + torch::List> unary_scalars, + std::optional unary_algorithm); + + C10_API static at::Tensor run_pointwise_binary_tensor( + at::Tensor act, // contains quantized values but not QTensor + at::Tensor act_scale, + at::Tensor act_zero_point, + at::Tensor weight, // contains quantized values but not QTensor + at::Tensor weight_scales, + at::Tensor weight_zero_points, + at::Tensor accum, // contains quantized values but not QTensor + std::optional bias, + torch::List stride, + torch::List padding, + torch::List dilation, + int64_t groups, + double output_scale, + int64_t output_zero_point, + std::optional output_dtype, + double accum_scale, + int64_t accum_zero_point, + std::string_view binary_attr, + std::optional alpha, + std::optional unary_attr, + torch::List> unary_scalars, + std::optional unary_algorithm); + +}; + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qembeddingbag.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qembeddingbag.h new file mode 100644 index 0000000000000000000000000000000000000000..a489c0dc3b387cfa4ec366a1d7d370e25c4cc38c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qembeddingbag.h @@ -0,0 +1,32 @@ +#pragma once +#include +#include + +namespace at::native { +Tensor& embedding_bag_byte_rowwise_offsets_out( + Tensor& output, + const Tensor& weight, + const Tensor& indices, + const std::optional& offsets_in, + const bool /* scale_grad_by_freq */, + const int64_t /* mode */, + bool pruned_weights, + const std::optional& per_sample_weights_, + const std::optional& compressed_indices_mapping, + bool include_last_offset); + +Tensor& embedding_bag_4bit_rowwise_offsets_out( + Tensor& output, + const Tensor& weight, + const Tensor& indices, + const std::optional& offsets_in, + const bool /* scale_grad_by_freq */, + const int64_t /* mode */, + bool pruned_weights, + const std::optional& per_sample_weights_, + const std::optional& compressed_indices_mapping, + bool include_last_offset); + +Tensor& qembeddingbag_byte_unpack_out(Tensor& output, const Tensor& packed_weight); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qembeddingbag_prepack.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qembeddingbag_prepack.h new file mode 100644 index 0000000000000000000000000000000000000000..e157405c107b81442392502d5ccb54d6c0c2cd1d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qembeddingbag_prepack.h @@ -0,0 +1,12 @@ +#pragma once +#include + +namespace at::native { + +Tensor& qembeddingbag_byte_prepack_out(Tensor& output, const Tensor& weight); + +Tensor qembeddingbag_byte_prepack(const Tensor& weight); + +Tensor qembeddingbag_byte_prepack_meta(const Tensor& weight); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qlinear.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qlinear.h new file mode 100644 index 0000000000000000000000000000000000000000..60501c6b5373853fb723fe71d14bd4461fc6f6f2 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/cpu/qlinear.h @@ -0,0 +1,51 @@ +#pragma once +#include +#include + +namespace at::native { + +class QLinearOnednn final { + public: + C10_API static Tensor run_pointwise_tensor( + Tensor act, // int8 CPU tensor, not QTensor + Tensor act_scale, + Tensor act_zero_point, + Tensor onednn_weight, // int8 tensor from MkldnnCPU + Tensor weight_scales, + Tensor weight_zero_points, + std::optional bias, + double output_scale, + int64_t output_zero_point, + std::optional output_dtype, + std::string_view post_op_name, + c10::List> post_op_args, + std::string_view post_op_algorithm); + +C10_API static Tensor run_pointwise_binary_tensor( + Tensor act, // int8 CPU tensor, not QTensor + Tensor act_scale, + Tensor act_zero_point, + Tensor onednn_weight, // int8 tensor from MkldnnCPU + Tensor weight_scales, + Tensor weight_zero_points, + std::optional other, // extra input for binary post-op + std::optional bias, + double output_scale, + int64_t output_zero_point, + std::optional output_dtype, + double other_scale, + int64_t other_zero_point, + std::string_view binary_post_op, // e.g. "none", "sum", "add" + double binary_alpha, + std::string_view unary_post_op, // e.g. "none", "relu" + c10::List> unary_post_op_args, + std::string_view unary_post_op_algorithm); +}; + +C10_API Tensor _weight_int4pack_mm_cpu_tensor( + const Tensor& A, + const Tensor& B, + const Tensor& qGroupSize, + const Tensor& qScaleAndZeros); + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/library.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/library.h new file mode 100644 index 0000000000000000000000000000000000000000..09fa2f626603567e50ac305c03a53326ce4a0879 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/quantized/library.h @@ -0,0 +1,8 @@ +#pragma once + +#include + +TORCH_API int register_linear_params(); +int register_embedding_params(); + +template TORCH_API int register_conv_params(); diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/transformers/attention.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/transformers/attention.h new file mode 100644 index 0000000000000000000000000000000000000000..7bb75f00acff497a0edea81d962224c059496565 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/transformers/attention.h @@ -0,0 +1,70 @@ +#pragma once +#include +#include +#include +#include +#include + +namespace at::native { + +using fused_sdp_choice_fn = int64_t (*)(const Tensor& query_, const Tensor& key, const Tensor& value, + const std::optional& attn_mask_, double dropout_p, bool is_causal, std::optional scale, bool enable_gqa); + +DECLARE_DISPATCH(fused_sdp_choice_fn, _fused_sdp_choice_stub) + +TORCH_API Tensor bmm_nt(const Tensor& a, const Tensor& b); +TORCH_API Tensor masked_softmax( + Tensor& attn_scores, + std::optional attn_mask, + const Tensor& query, + std::optional mask_type = {}); + +using transform_bias_rescale_qkv_fn = void(*)( + at::ScalarType type, + void* _q_k_v, + const void* _qkv, + const void* _qkv_bias, + int64_t B, + int64_t T, + int64_t D, + int64_t num_head); + +DECLARE_DISPATCH(transform_bias_rescale_qkv_fn, transform_bias_rescale_qkv_stub) + +TORCH_API Tensor transform0213_gemm_nt_bias( + const Tensor& a, + const Tensor& b, + const Tensor& c, + const Tensor& query); + +TORCH_API Tensor bmm_nn(Tensor& out, const Tensor& a, const Tensor& b); + +TORCH_API void debug_assert_shape(int line, const Tensor& t, c10::IntArrayRef shape); + +TORCH_API Tensor qkv_projection( + const Tensor& query, + const Tensor& key, + const Tensor& value, + const int64_t embed_dim, + const Tensor& qkv_weight); + +using flash_attention_fn = void (*)( + const Tensor& output, const Tensor& logsumexp, + const Tensor& query, const Tensor& key, const Tensor& value, + double dropout_p, bool is_causal, + std::optional attn_mask, + std::optional scale); + +using flash_attention_backward_fn = void (*)( + const Tensor& grad_q, const Tensor& grad_k, + const Tensor& grad_v, const Tensor& grad_out, + const Tensor& query, const Tensor& key, + const Tensor& value, const Tensor& out, const Tensor& logsumexp, + double dropout_p, bool is_causal, + std::optional attn_mask, + std::optional scale); + +DECLARE_DISPATCH(flash_attention_fn, flash_attention_kernel) +DECLARE_DISPATCH(flash_attention_backward_fn, flash_attention_backward_kernel) + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/transformers/sdp_utils_cpp.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/transformers/sdp_utils_cpp.h new file mode 100644 index 0000000000000000000000000000000000000000..22afbac1d079e34f48f219376ce3ad83b7bd882e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/transformers/sdp_utils_cpp.h @@ -0,0 +1,556 @@ +#pragma once +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include + +#include +#include +#include +#include +#include +#include + +namespace sdp { + +constexpr int32_t num_backends = at::num_sdp_backends; +using SDPBackend = at::SDPBackend; + +// Note that if this changed make sure to update +// the templated enum in mem_eff/kernel_forward.h and mem_eff/kernel_backward.h +enum class CustomMaskType { + NoCustomMask = 0, + CausalFromTopLeft = 1, + CausalFromBottomRight = 2, + NumCustomMaskTypes, +}; + +struct sdp_params { + at::Tensor query; + at::Tensor key; + at::Tensor value; + std::optional attn_mask; + double dropout; + bool is_causal; + bool enable_gqa; +}; + +SDPBackend select_sdp_backend_cpp(sdp_params const& kernel_params); + +inline c10::SymFloat calculate_scale( + const at::Tensor& query, + std::optional scale) { + const auto softmax_scale = scale.has_value() + ? scale.value() + : (c10::SymFloat(1.0) / (c10::SymFloat(query.sym_size(-1)).sqrt())); + return c10::SymFloat(softmax_scale); +} + +inline bool input_requires_grad(sdp_params const& params) { + const bool any_inputs_require_grad = params.query.requires_grad() || + params.key.requires_grad() || params.value.requires_grad(); + const bool gradmode_enabled = at::GradMode::is_enabled(); + return any_inputs_require_grad && gradmode_enabled; +} + +inline bool has_for_nested_inputs(sdp_params const& params) { + return + (params.query.is_nested() && params.query.layout() == c10::kStrided) || + (params.key.is_nested() && params.key.layout() == c10::kStrided) || + (params.value.is_nested() && params.value.layout() == c10::kStrided); +} + +inline bool has_for_dense_inputs(sdp_params const& params) { + return !params.query.is_nested() || !params.key.is_nested() || !params.value.is_nested(); +} + +inline bool has_only_dense_inputs(sdp_params const& params) { + return !params.query.is_nested() && !params.key.is_nested() && !params.value.is_nested(); +} + +template +inline bool check_tensor_dtype( + sdp_params const& params, + dtype_vector allowed_dtypes, + bool debug) { + auto query_dtype = params.query.dtype(); + if (!(query_dtype == params.key.dtype() && + query_dtype == params.value.dtype() && + (std::find(allowed_dtypes.begin(), allowed_dtypes.end(), query_dtype) != + allowed_dtypes.end()))) { + if (debug) { + TORCH_WARN( + "Expected query, key and value to all be of dtype: {", + c10::Join(", ", allowed_dtypes), + "}. Got ", + "Query dtype: ", + params.query.dtype(), + ", Key dtype: ", + params.key.dtype(), + ", and Value dtype: ", + params.value.dtype(), + " instead."); + } + return false; + } + return true; +} + + +inline bool try_broadcast_param_size( + const c10::SymInt q_size, + const c10::SymInt k_size, + const c10::SymInt v_size, + std::string_view param_name, + bool debug) { + auto max_size = std::max({q_size, k_size, v_size}); + if ((q_size != max_size && q_size != 1) || + (k_size != max_size && k_size != 1) || + (v_size != max_size && v_size != 1)) { + if (debug) { + TORCH_WARN( + "Both fused kernels require query, key and value to have broadcastable ", + param_name, + "got Query ", + param_name, + q_size, + ", Key ", + param_name, + k_size, + ", Value ", + param_name, + v_size, + " instead."); + } + return false; + } + return true; +} + +inline bool check_for_seq_len_0_and_consistent_head_dim_nested_tensor_helper( + at::Tensor const& param, + std::string_view param_name, + bool debug) { + const auto nt_tensor_impl = at::native::get_nested_tensor_impl(param); + const at::Tensor& sizes = nt_tensor_impl->get_nested_sizes(); + auto num_head_dims = nt_tensor_impl->opt_size(1); + if (!num_head_dims.has_value()) { + // num_head_dims is ragged + if (debug) { + TORCH_WARN( + "Fused kernels do not support ragged num_head_dims, ", + param_name, + "has a ragged num_heads."); + } + return false; + } + + auto* sizes_ptr = sizes.data_ptr(); + const int64_t n_tensors = param.size(0); + const int64_t size_tensor_stride = sizes.stride(0); + + // This is being called inside sdp with shape [batch, heads, {seq_len}, dim] + for (const auto i : c10::irange(n_tensors)) { + if (sizes_ptr[(i * size_tensor_stride) + 1] == 0) { + if (debug) { + TORCH_WARN( + "Fused kernels do not support seq_len == 0, ", + param_name, + "has a seq len of 0."); + } + return false; + } + } + return true; +} + +inline bool check_for_seq_len_0_nested_tensor(sdp_params const& params, bool debug) { + // When this function is called we are assured that the nt is dim==4 + bool q_is_safe = params.query.is_nested() + ? check_for_seq_len_0_and_consistent_head_dim_nested_tensor_helper( + params.query, "query ", debug) + : true; + // short circuit if any is unsafe + if (!q_is_safe) { + return false; + } + + bool k_is_safe = params.key.is_nested() + ? check_for_seq_len_0_and_consistent_head_dim_nested_tensor_helper( + params.key, "key ", debug) + : true; + if (!k_is_safe) { + return false; + } + + bool v_is_safe = params.value.is_nested() + ? check_for_seq_len_0_and_consistent_head_dim_nested_tensor_helper( + params.value, "value ", debug) + : true; + if (!v_is_safe) { + return false; + } + + // We now know none of the inputs have ragged num_heads, so we can safely + // access .size(1) + auto q_num_heads = params.query.size(1); + auto k_num_heads = params.key.size(1); + auto v_num_heads = params.value.size(1); + bool same_num_heads = + q_num_heads == k_num_heads && q_num_heads == v_num_heads; + + if (!same_num_heads) { + if (input_requires_grad(params)){ + if (debug) { + TORCH_WARN( + "Both fused kernels do not support training with broadcasted NT inputs."); + } + return false; + } + return try_broadcast_param_size( + q_num_heads, k_num_heads, v_num_heads, "num heads ", debug); + } + + return true; +} + +inline bool check_nested_tensor(sdp_params const& params, bool debug) { + // Return false if have nested tensor + if (!has_only_dense_inputs(params)) { + if (debug) { + TORCH_WARN( + "Both fused kernels of cpp version currently do not support Nested Tensor inputs."); + } + return false; + } + return true; +} + +inline bool check_for_dropout(sdp_params const& params, bool debug) { + if (params.dropout > 0.0) { + if (debug) { + TORCH_WARN("Both fused kernels do not support non-zero dropout."); + } + return false; + } + return true; +} + +inline bool check_requires_grad_and_nested(sdp_params const& params, bool debug) { + if (input_requires_grad(params)) { + if (debug) { + TORCH_WARN( + "Memory efficient attention currently doesn't support training with NT inputs."); + } + return false; + } + return true; +} + +inline bool check_for_attn_mask(sdp_params const& params, bool debug) { + if (params.attn_mask.has_value()) { + if (debug) { + TORCH_WARN("Flash Attention does not support non-null attn_mask."); + } + return false; + } + return true; +} + +inline bool check_attn_mask_shape(sdp_params const& params, bool debug) { + auto attn_mask = params.attn_mask; + if (!attn_mask.has_value()) { + return true; + } + if (attn_mask.value().requires_grad()) { + return false; + } + auto batchSize = params.query.sym_size(0); + auto qSize = params.query.sym_size(2); + auto kvSize = params.key.sym_size(2); + auto num_head = params.query.sym_size(1); + if (attn_mask.value().sym_size(-2) != qSize && attn_mask.value().sym_size(-2) != 1) { + return false; + } + if (attn_mask.value().sym_size(-1) != kvSize && attn_mask.value().sym_size(-1) != 1) { + return false; + } + if (attn_mask.value().dim() == 2) { + return true; + } else if (attn_mask.value().dim() == 4) { + if ((attn_mask.value().sym_size(0) == 1 || attn_mask.value().sym_size(0) == batchSize) + && (attn_mask.value().sym_size(1) == 1 || attn_mask.value().sym_size(1) == num_head)) { + return true; + } + } + if (debug) { + TORCH_WARN("Please use the following attn mask shapes: ", + "2d - ({Q_seq_len, 1} x {KV_seq_len, 1}); ", + "4d - ({Batch, 1} x {Num_heads, 1} x {Q_seq_len, 1} x {KV_seq_len, 1})"); + } + return false; +} + +inline bool check_tensor_shapes(sdp_params const& params, bool debug) { + auto query_dim = params.query.dim(); + if (!(query_dim == params.key.dim() && query_dim == params.value.dim() && + (query_dim == 4))) { + if (debug) { + TORCH_WARN( + "All fused kernels requires query, key and value to be 4 dimensional, but got Query dim: ", + query_dim, + ", Key dim: ", + params.key.dim(), + ", Value dim: ", + params.value.dim(), + " instead."); + } + return false; + } + return true; +} + +inline bool check_safe_kv_broadcast(at::Tensor const& param, bool debug) { + const auto nt_tensor_impl = at::native::get_nested_tensor_impl(param); + auto seq_len = nt_tensor_impl->opt_size(2); + if (!seq_len.has_value()) { + if (debug) { + TORCH_WARN( + "For both fused kernels, if one of key/value batch_size requires " + "broadcasting and the other does not, then the other must have a ", + "consistent seq_len dim.") + } + return false; + } + return true; +} + +inline bool check_grouped_query_attention(sdp_params const& params, bool debug) { + const auto q_num_heads = params.query.sym_size(-3); + const auto k_num_heads = params.key.sym_size(-3); + const auto v_num_heads = params.value.sym_size(-3); + const bool same_kv_heads = k_num_heads == v_num_heads; + + if (!(same_kv_heads)){ + if (debug) { + TORCH_WARN( + "Both fused kernels require key and value to have the same num_heads and batch_size but got: ", + "Key sizes: ", + params.key.sizes(), + ", Value sizes: ", + params.value.sizes(), + ", Query sizes: ", + params.query.sizes(), + " instead."); + } + return false; + } + // Check if grouped query attention is supported and validate the number of + // heads + if (q_num_heads % k_num_heads != 0) { + if (debug) { + TORCH_WARN( + "FlashAttentionV2 only supports grouped query attention, where the number of heads in key/value must divide number of heads in query.", + "Got input Key sizes(): ", + params.key.sym_size(-3), + ", Value sizes(): ", + params.value.sym_size(-3), + ", Query sizes(): ", + params.query.sym_size(-3), + " instead."); + } + return false; + } + return true; +} + +template +inline bool check_batch_size_and_num_heads_dense(sdp_params const& params, bool debug) { + // This is expected to be called after check_tensor_shapes ensuring that the + // size() calls won't error since the inputs are all 4 dimensional + + auto q_batch_size = params.query.sym_size(0); + auto k_batch_size = params.key.sym_size(0); + auto v_batch_size = params.value.sym_size(0); + + bool same_batch_size = + q_batch_size == k_batch_size && q_batch_size == v_batch_size; + + auto q_num_heads = params.query.sym_size(-3); + auto k_num_heads = params.key.sym_size(-3); + auto v_num_heads = params.value.sym_size(-3); + + bool same_num_heads = + q_num_heads == k_num_heads && q_num_heads == v_num_heads; + + if (!same_batch_size){ + if(debug) { + TORCH_WARN( + "For dense inputs, both fused kernels require query, key and value to have the same batch_size. ", + "Query.sizes(): ", + params.query.sizes(), + ", Key.sizes(): ", + params.key.sizes(), + ", Value.sizes(): ", + params.value.sizes(), + " instead. To broadcast dense inputs, try using unsqueeze and expand_to before passing them into the kernel."); + } + return false; + } + + if(params.enable_gqa && supports_gqa){ + return check_grouped_query_attention(params, debug); + } + + if (!same_num_heads){ + if (debug) { + TORCH_WARN( + "For dense input, both fused kernels require query, key and value to have the same num_heads. ", + "Query.sizes(): ", + params.query.sizes(), + ", Key sizes(): ", + params.key.sizes(), + ", Value sizes(): ", + params.value.sizes(), + " instead. To broadcast dense inputs, try using unsqueeze and expand_to before passing them into the kernel."); + } + return false; + } + // If all checks pass, return true + return true; +} + +inline bool check_batch_size_nested(sdp_params const& params, bool debug) { + // This is expected to be called after check_tensor_shapes ensuring that the + // size() calls won't error since the inputs are all 4 dimensional + auto q_batch_size = params.query.sym_size(0); + auto k_batch_size = params.key.sym_size(0); + auto v_batch_size = params.value.sym_size(0); + + bool same_batch_size = + q_batch_size == k_batch_size && q_batch_size == v_batch_size; + + // num_heads logic for nested input is checked in + // check_for_seq_len_0_nested_tensor as there is handling there to make sure + // num_heads is not ragged + bool broadcastable_batch_size = true; + if (!same_batch_size) { + if (input_requires_grad(params)){ + if (debug) { + TORCH_WARN( + "Both fused kernels do not support training with broadcasted NT inputs."); + } + return false; + } + // try to broadcast batchsize + broadcastable_batch_size = try_broadcast_param_size( + q_batch_size, k_batch_size, v_batch_size, "batch size ", debug); + + // if only one of k or v require broadcasting of batch size, the other + // must have a consistent seq_len dim + if (broadcastable_batch_size) { + if (k_batch_size == 1 && v_batch_size != 1 && + !check_safe_kv_broadcast(params.value, debug)) { + return false; + } + if (v_batch_size == 1 && k_batch_size != 1 && + !check_safe_kv_broadcast(params.key, debug)) { + return false; + } + } + } + return broadcastable_batch_size; +} + +inline bool check_nonzero_sequence_lengths_dense(sdp_params const& params, bool debug) { + // In some cases people will pass in 0 sized tensors, this will + // cause the fused path to error with unaligned mask + bool zero_seq_len_q = params.query.sym_size(-2) == 0; + bool zero_seq_len_k = params.key.sym_size(-2) == 0; + if (zero_seq_len_q || zero_seq_len_k) { + if (debug) { + TORCH_WARN( + "All fused kernels do not support zero seq_len_q or seq_len_kv."); + } + return false; + } + return true; +} + +template +inline bool check_last_dim_stride_equals_1_dense(sdp_params const& params, bool debug) { + // The stride checking for NestedTensors is done within the kernel + // And .contiguous will be called if needed + + // This function checks that the last dimension of the inputs to + // fused_attention have stride 1 + bool qkv_strides_equal_1 = params.query.sym_stride(-1) == 1 && + params.key.sym_stride(-1) == 1 && params.value.sym_stride(-1) == 1; + + // https://github.com/pytorch/pytorch/issues/116333 + // If the head_dim is size 1 the stride won't matter, but we + // check this condition before padding the head_dim to 1 + if (ignore_singleton_dim){ + qkv_strides_equal_1 = qkv_strides_equal_1 || params.query.sym_size(-1) == 1; + } + bool mask_stride_equal_1 = params.attn_mask.has_value() + ? params.attn_mask.value().sym_stride(-1) == 1 + : true; + if (!(qkv_strides_equal_1 && mask_stride_equal_1)) { + if (debug) { + std::ostringstream epilogue_message; + if (params.attn_mask.has_value()) { + epilogue_message << ", Attn_mask.stride(-1): " + << params.attn_mask.value().sym_stride(-1); + } + epilogue_message << " instead."; + TORCH_WARN( + "All fused kernels require the last dimension of the input to have stride 1. ", + "Got Query.stride(-1): ", + params.query.sym_stride(-1), + ", Key.stride(-1): ", + params.key.sym_stride(-1), + ", Value.stride(-1): ", + params.value.sym_stride(-1), + epilogue_message.str()); + } + + return false; + } + return true; +} + +inline bool check_runtime_disabled_flash(sdp_params const& params, bool debug) { + // We check the global context to see if user has explicitly turned of flash + // sdp kernels + if (!at::globalContext().userEnabledFlashSDP()) { + if (debug) { + TORCH_WARN("Flash attention has been runtime disabled."); + } + return false; + } + return true; +} + +inline bool check_runtime_disabled_mem_efficient(sdp_params const& params, bool debug) { + // We check the global context to see if user has explicitly turned of + // mem_efficient sdp kernels + if (!at::globalContext().userEnabledMemEfficientSDP()) { + if (debug) { + TORCH_WARN("Memory Efficient attention has been runtime disabled."); + } + return false; + } + return true; +} + + +} // namespace sdp diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/utils/Factory.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/utils/Factory.h new file mode 100644 index 0000000000000000000000000000000000000000..8c70435bd313c4d46a2a7248101fd4b5c3240be0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/utils/Factory.h @@ -0,0 +1,20 @@ +#pragma once + +#include + +namespace at::native::mobile { + +Tensor allocate_padded_contiguous_if_needed( + const Tensor& input, + c10::MemoryFormat memory_format); + +// TODO: Remove this function when at::native::empty() is modified to accept a +// custom memory allocator. + +at::Tensor empty_with_tail_padding( + IntArrayRef size, + const caffe2::TypeMeta dtype, + c10::MemoryFormat memory_format, + std::optional maybe_names); + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/utils/ParamUtils.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/utils/ParamUtils.h new file mode 100644 index 0000000000000000000000000000000000000000..c9088c03d81c18bd80eda81e88a172491415a7c6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/utils/ParamUtils.h @@ -0,0 +1,42 @@ +#pragma once + +#include +#include + +namespace at { +namespace native { + +template +inline std::vector _expand_param_if_needed( + ArrayRef list_param, + const char* param_name, + int64_t expected_dim) { + if (list_param.size() == 1) { + return std::vector(expected_dim, list_param[0]); + } else if ((int64_t)list_param.size() != expected_dim) { + std::ostringstream ss; + ss << "expected " << param_name << " to be a single integer value or a " + << "list of " << expected_dim << " values to match the convolution " + << "dimensions, but got " << param_name << "=" << list_param; + TORCH_CHECK(false, ss.str()); + } else { + return list_param.vec(); + } +} + +inline std::vector expand_param_if_needed( + IntArrayRef list_param, + const char* param_name, + int64_t expected_dim) { + return _expand_param_if_needed(list_param, param_name, expected_dim); +} + +inline std::vector expand_param_if_needed( + SymIntArrayRef list_param, + const char* param_name, + int64_t expected_dim) { + return _expand_param_if_needed(list_param, param_name, expected_dim); +} + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/utils/ParamsHash.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/utils/ParamsHash.h new file mode 100644 index 0000000000000000000000000000000000000000..6b7894cb8549f59d34b9b52d660780b729ada575 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/utils/ParamsHash.h @@ -0,0 +1,104 @@ +#pragma once + +#include +#include +#include + +namespace at::native { + +// Hashing machinery for Params +// Fowler–Noll–Vo hash function +// see +// https://en.wikipedia.org/wiki/Fowler%E2%80%93Noll%E2%80%93Vo_hash_function +template +struct ParamsHash { + // Params must be a POD because we read out its memory + // contents as char* when hashing + static_assert(std::is_standard_layout_v, "Params is not POD"); + + size_t operator()(const Params& params) const { + auto ptr = reinterpret_cast(¶ms); + uint32_t value = 0x811C9DC5; + for (const auto i : c10::irange(sizeof(Params))) { + value ^= ptr[i]; + value *= 0x01000193; + } + return (size_t)value; + } +}; + +template +struct ParamsEqual { + // Params must be a POD because we read out its memory + // contents as char* when comparing + static_assert(std::is_standard_layout_v, "Params is not POD"); + + bool operator()(const Params& a, const Params& b) const { + auto ptr1 = reinterpret_cast(&a); + auto ptr2 = reinterpret_cast(&b); + return memcmp(ptr1, ptr2, sizeof(Params)) == 0; + } +}; + +// Provide explicit byte-for-byte constructors to avoid uwittingly leaving +// padding bytes unitialized (e.g., when passing Params by value) +template +struct ParamsWrapper { + T pod; + static_assert( + std::is_standard_layout_v, + "ParamsWrapper cannot wrap non-POD data"); + + ParamsWrapper() { + memset(&(this->pod), 0, sizeof(this->pod)); + } + + ParamsWrapper(const ParamsWrapper& other) { + memcpy(&(this->pod), &(other.pod), sizeof(this->pod)); + } + + ParamsWrapper(ParamsWrapper&& other) noexcept { + memcpy(&(this->pod), &(other.pod), sizeof(this->pod)); + } + + ParamsWrapper& operator=(const ParamsWrapper& other) { + memcpy(&(this->pod), &(other.pod), sizeof(this->pod)); + return *this; + } + + ParamsWrapper& operator=(ParamsWrapper&& other) noexcept { + memcpy(&(this->pod), &(other.pod), sizeof(this->pod)); + return *this; + } + + inline friend bool operator==( + const ParamsWrapper& lhs, + const ParamsWrapper& rhs) noexcept { + auto ptr1 = reinterpret_cast(&(lhs.pod)); + auto ptr2 = reinterpret_cast(&(rhs.pod)); + return memcmp(ptr1, ptr2, sizeof(lhs.pod)) == 0; + } +}; + +// Wrapped version: this allows the outer struct to have custom copy and move +// constructors for additional safety +template +struct ParamsWrapperHash { + // Params must be a POD because we read out its memory + // contents as char* when hashing + static_assert( + std::is_standard_layout_v, + "ParamsWrapper cannot wrap non-POD data"); + + size_t operator()(const ParamsWrapper& params_wrapper) const { + auto ptr = reinterpret_cast(&(params_wrapper.pod)); + uint32_t value = 0x811C9DC5; + for (const auto i : c10::irange(sizeof(params_wrapper.pod))) { + value ^= ptr[i]; + value *= 0x01000193; + } + return (size_t)value; + } +}; + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/verbose_wrapper.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/verbose_wrapper.h new file mode 100644 index 0000000000000000000000000000000000000000..59d9682e345b4440e103a1f95c6da42208764aba --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/verbose_wrapper.h @@ -0,0 +1,8 @@ +#pragma once + +#include + +namespace torch::verbose { +TORCH_API int _mkl_set_verbose(int enable); +TORCH_API int _mkldnn_set_verbose(int level); +} // namespace torch::verbose diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/vol2col.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/vol2col.h new file mode 100644 index 0000000000000000000000000000000000000000..fa5c46b8c52e874791337a30fc9d4f1e5ff3db1d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/native/vol2col.h @@ -0,0 +1,109 @@ +#pragma once + +#include + +namespace at::native { + +template +void vol2col( + const T* data_vol, + const int64_t channels, + const int64_t depth, + const int64_t height, + const int64_t width, + const int64_t depth_col, + const int64_t height_col, + const int64_t width_col, + const int64_t kT, + const int64_t kernel_height, + const int64_t kernel_width, + const int64_t pT, + const int64_t pH, + const int64_t pW, + const int64_t dT, + const int64_t dH, + const int64_t dW, + const int64_t dilationT, + const int64_t dilationH, + const int64_t dilationW, + T* data_col) { + int64_t c, t, h, w; + int64_t channels_col = channels * kT * kernel_height * kernel_width; + for (c = 0; c < channels_col; ++c) { + int64_t w_offset = c % kernel_width; + int64_t h_offset = (c / kernel_width) % kernel_height; + int64_t t_offset = (c / kernel_width / kernel_height) % kT; + int64_t c_vol = c / kT / kernel_height / kernel_width; + for (t = 0; t < depth_col; ++t) { + int64_t t_pad = t * dT - pT + t_offset * dilationT; + for (h = 0; h < height_col; ++h) { + int64_t h_pad = h * dH - pH + h_offset * dilationH; + for (w = 0; w < width_col; ++w) { + int64_t w_pad = w * dW - pW + w_offset * dilationW; + if (t_pad >= 0 && t_pad < depth && h_pad >= 0 && h_pad < height && + w_pad >= 0 && w_pad < width) + data_col[((c * depth_col + t) * height_col + h) * width_col + w] = + data_vol + [((c_vol * depth + t_pad) * height + h_pad) * width + + w_pad]; + else + data_col[((c * depth_col + t) * height_col + h) * width_col + w] = + 0; + } + } + } + } +} + +template +void col2vol( + const T* data_col, + const int64_t channels, + const int64_t depth, + const int64_t height, + const int64_t width, + const int64_t out_depth, + const int64_t out_height, + const int64_t out_width, + const int64_t kT, + const int64_t kernel_height, + const int64_t kernel_width, + const int64_t pT, + const int64_t pH, + const int64_t pW, + const int64_t dT, + const int64_t dH, + const int64_t dW, + const int64_t dilationT, + const int64_t dilationH, + const int64_t dilationW, + T* data_vol) { + memset(data_vol, 0, sizeof(T) * depth * height * width * channels); + int64_t depth_col = out_depth; + int64_t height_col = out_height; + int64_t width_col = out_width; + int64_t channels_col = channels * kT * kernel_height * kernel_width; + for (int64_t c = 0; c < channels_col; ++c) { + int64_t w_offset = c % kernel_width; + int64_t h_offset = (c / kernel_width) % kernel_height; + int64_t t_offset = (c / kernel_width / kernel_height) % kT; + int64_t c_vol = c / kT / kernel_height / kernel_width; + for (int64_t t = 0; t < depth_col; ++t) { + int64_t t_pad = t * dT - pT + t_offset * dilationT; + for (int64_t h = 0; h < height_col; ++h) { + int64_t h_pad = h * dH - pH + h_offset * dilationH; + for (int64_t w = 0; w < width_col; ++w) { + int64_t w_pad = w * dW - pW + w_offset * dilationW; + if (t_pad >= 0 && t_pad < depth && h_pad >= 0 && h_pad < height && + w_pad >= 0 && w_pad < width) + data_vol + [((c_vol * depth + t_pad) * height + h_pad) * width + w_pad] += + data_col + [((c * depth_col + t) * height_col + h) * width_col + w]; + } + } + } + } +} + +} // namespace at::native diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view.h new file mode 100644 index 0000000000000000000000000000000000000000..b8d7cc1c841df02674edf9be2cb524cdc7b7e992 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view.h @@ -0,0 +1,40 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +namespace symint { + template >> + at::Tensor view(const at::Tensor & self, at::IntArrayRef size) { + return at::_ops::view::call(self, c10::fromIntArrayRefSlow(size)); + } +} + +namespace symint { + template >> + at::Tensor view(const at::Tensor & self, c10::SymIntArrayRef size) { + return at::_ops::view::call(self, size); + } +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_copy_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_copy_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..2535b8f5789c7afe36e3a87ad9d2d98db150e9b7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_copy_ops.h @@ -0,0 +1,40 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API view_as_complex_copy { + using schema = at::Tensor (const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_as_complex_copy"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "view_as_complex_copy(Tensor self) -> Tensor"; + static at::Tensor call(const at::Tensor & self); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self); +}; + +struct TORCH_API view_as_complex_copy_out { + using schema = at::Tensor & (const at::Tensor &, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_as_complex_copy"; + static constexpr const char* overload_name = "out"; + static constexpr const char* schema_str = "view_as_complex_copy.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Tensor & self, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, at::Tensor & out); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_cpu_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_cpu_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..b867f9f4f550b2bbb12b9b494a27af850fc87c46 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_cpu_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cpu { + +TORCH_API at::Tensor view_as_complex(const at::Tensor & self); + +} // namespace cpu +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_cuda_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_cuda_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..f1e571fcf2c497f02a4942aea90d55dfcf34bf74 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_cuda_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cuda { + +TORCH_API at::Tensor view_as_complex(const at::Tensor & self); + +} // namespace cuda +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_meta_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_meta_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..188579f0915744a3d727213296e8785efa056711 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_meta_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace meta { + +TORCH_API at::Tensor view_as_complex(const at::Tensor & self); + +} // namespace meta +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_native.h new file mode 100644 index 0000000000000000000000000000000000000000..5c16c2886f0937900f171c8db992520237426334 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_native.h @@ -0,0 +1,21 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor view_as_complex(const at::Tensor & self); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..85afd92c4a6585bca529525b5ce95b54f4403674 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_complex_ops.h @@ -0,0 +1,29 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API view_as_complex { + using schema = at::Tensor (const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_as_complex"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "view_as_complex(Tensor(a) self) -> Tensor(a)"; + static at::Tensor call(const at::Tensor & self); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_compositeimplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_compositeimplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..ca57511cb42bc27bd05e434a80937e49584a362c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_compositeimplicitautograd_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeimplicitautograd { + +TORCH_API at::Tensor view_as(const at::Tensor & self, const at::Tensor & other); + +} // namespace compositeimplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_native.h new file mode 100644 index 0000000000000000000000000000000000000000..309ad0fa4f6cc402028540157be87d5270950a90 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_native.h @@ -0,0 +1,21 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor view_as(const at::Tensor & self, const at::Tensor & other); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real.h new file mode 100644 index 0000000000000000000000000000000000000000..8184251ccc84457aaba8109cf197d9845a89e902 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real.h @@ -0,0 +1,31 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::view_as_real(Tensor(a) self) -> Tensor(a) +inline at::Tensor view_as_real(const at::Tensor & self) { + return at::_ops::view_as_real::call(self); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy.h new file mode 100644 index 0000000000000000000000000000000000000000..b2ac27e34c37fdd978a225da15a6798bfba8948a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy.h @@ -0,0 +1,40 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::view_as_real_copy(Tensor self) -> Tensor +inline at::Tensor view_as_real_copy(const at::Tensor & self) { + return at::_ops::view_as_real_copy::call(self); +} + +// aten::view_as_real_copy.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & view_as_real_copy_out(at::Tensor & out, const at::Tensor & self) { + return at::_ops::view_as_real_copy_out::call(self, out); +} +// aten::view_as_real_copy.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & view_as_real_copy_outf(const at::Tensor & self, at::Tensor & out) { + return at::_ops::view_as_real_copy_out::call(self, out); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_compositeexplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_compositeexplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..9054bc9e2eeb9cbabe83cd443455ad272907d533 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_compositeexplicitautograd_dispatch.h @@ -0,0 +1,24 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautograd { + +TORCH_API at::Tensor & view_as_real_copy_out(at::Tensor & out, const at::Tensor & self); +TORCH_API at::Tensor & view_as_real_copy_outf(const at::Tensor & self, at::Tensor & out); + +} // namespace compositeexplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_compositeexplicitautogradnonfunctional_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_compositeexplicitautogradnonfunctional_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..86d644a2f214ba08720dcc0b946e9044ed2e7bd9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_compositeexplicitautogradnonfunctional_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautogradnonfunctional { + +TORCH_API at::Tensor view_as_real_copy(const at::Tensor & self); + +} // namespace compositeexplicitautogradnonfunctional +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_native.h new file mode 100644 index 0000000000000000000000000000000000000000..bece11bea2fb2b99817c029d3445af19abbca081 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_native.h @@ -0,0 +1,22 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor & view_as_real_copy_out(const at::Tensor & self, at::Tensor & out); +TORCH_API at::Tensor view_as_real_copy(const at::Tensor & self); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..19283e2abbaf656ee09c2260e1358ceea4b9fbe9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_copy_ops.h @@ -0,0 +1,40 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API view_as_real_copy { + using schema = at::Tensor (const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_as_real_copy"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "view_as_real_copy(Tensor self) -> Tensor"; + static at::Tensor call(const at::Tensor & self); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self); +}; + +struct TORCH_API view_as_real_copy_out { + using schema = at::Tensor & (const at::Tensor &, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_as_real_copy"; + static constexpr const char* overload_name = "out"; + static constexpr const char* schema_str = "view_as_real_copy.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Tensor & self, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, at::Tensor & out); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_cpu_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_cpu_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..d830e8bb2aa6e3b6f518e3168899d50c72a416c3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_cpu_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cpu { + +TORCH_API at::Tensor view_as_real(const at::Tensor & self); + +} // namespace cpu +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_cuda_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_cuda_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..f73e2a9b5f1aede026ad7cd32488f728cd2eb2d6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_cuda_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cuda { + +TORCH_API at::Tensor view_as_real(const at::Tensor & self); + +} // namespace cuda +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_meta_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_meta_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..6b21edfc305bb42905aeb9b68bb7cbeaa74fd7df --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_meta_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace meta { + +TORCH_API at::Tensor view_as_real(const at::Tensor & self); + +} // namespace meta +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_native.h new file mode 100644 index 0000000000000000000000000000000000000000..933fd19e84b14f94abd391c28aa9a8d276e04bec --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_native.h @@ -0,0 +1,21 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor view_as_real(const at::Tensor & self); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..c46751f99c8e469c13e84b0bfa19401e0b3eda42 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_as_real_ops.h @@ -0,0 +1,29 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API view_as_real { + using schema = at::Tensor (const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_as_real"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "view_as_real(Tensor(a) self) -> Tensor(a)"; + static at::Tensor call(const at::Tensor & self); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_compositeexplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_compositeexplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..ba8e92f6a12174ee3fbf24376b6d1b8ad81951da --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_compositeexplicitautograd_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautograd { + +TORCH_API at::Tensor view(const at::Tensor & self, at::ScalarType dtype); + +} // namespace compositeexplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy.h new file mode 100644 index 0000000000000000000000000000000000000000..ae10cc10cfc395f3154e6af913bd3592edf5b02f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy.h @@ -0,0 +1,106 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::view_copy(Tensor self, SymInt[] size) -> Tensor +inline at::Tensor view_copy(const at::Tensor & self, at::IntArrayRef size) { + return at::_ops::view_copy::call(self, c10::fromIntArrayRefSlow(size)); +} +namespace symint { + template >> + at::Tensor view_copy(const at::Tensor & self, at::IntArrayRef size) { + return at::_ops::view_copy::call(self, c10::fromIntArrayRefSlow(size)); + } +} + +// aten::view_copy(Tensor self, SymInt[] size) -> Tensor +inline at::Tensor view_copy_symint(const at::Tensor & self, c10::SymIntArrayRef size) { + return at::_ops::view_copy::call(self, size); +} +namespace symint { + template >> + at::Tensor view_copy(const at::Tensor & self, c10::SymIntArrayRef size) { + return at::_ops::view_copy::call(self, size); + } +} + +// aten::view_copy.dtype(Tensor self, ScalarType dtype) -> Tensor +inline at::Tensor view_copy(const at::Tensor & self, at::ScalarType dtype) { + return at::_ops::view_copy_dtype::call(self, dtype); +} + +// aten::view_copy.out(Tensor self, SymInt[] size, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & view_copy_out(at::Tensor & out, const at::Tensor & self, at::IntArrayRef size) { + return at::_ops::view_copy_out::call(self, c10::fromIntArrayRefSlow(size), out); +} +namespace symint { + template >> + at::Tensor & view_copy_out(at::Tensor & out, const at::Tensor & self, at::IntArrayRef size) { + return at::_ops::view_copy_out::call(self, c10::fromIntArrayRefSlow(size), out); + } +} + +// aten::view_copy.out(Tensor self, SymInt[] size, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & view_copy_outf(const at::Tensor & self, at::IntArrayRef size, at::Tensor & out) { + return at::_ops::view_copy_out::call(self, c10::fromIntArrayRefSlow(size), out); +} +namespace symint { + template >> + at::Tensor & view_copy_outf(const at::Tensor & self, at::IntArrayRef size, at::Tensor & out) { + return at::_ops::view_copy_out::call(self, c10::fromIntArrayRefSlow(size), out); + } +} + +// aten::view_copy.out(Tensor self, SymInt[] size, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & view_copy_symint_out(at::Tensor & out, const at::Tensor & self, c10::SymIntArrayRef size) { + return at::_ops::view_copy_out::call(self, size, out); +} +namespace symint { + template >> + at::Tensor & view_copy_out(at::Tensor & out, const at::Tensor & self, c10::SymIntArrayRef size) { + return at::_ops::view_copy_out::call(self, size, out); + } +} + +// aten::view_copy.out(Tensor self, SymInt[] size, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & view_copy_symint_outf(const at::Tensor & self, c10::SymIntArrayRef size, at::Tensor & out) { + return at::_ops::view_copy_out::call(self, size, out); +} +namespace symint { + template >> + at::Tensor & view_copy_outf(const at::Tensor & self, c10::SymIntArrayRef size, at::Tensor & out) { + return at::_ops::view_copy_out::call(self, size, out); + } +} + +// aten::view_copy.dtype_out(Tensor self, ScalarType dtype, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & view_copy_out(at::Tensor & out, const at::Tensor & self, at::ScalarType dtype) { + return at::_ops::view_copy_dtype_out::call(self, dtype, out); +} +// aten::view_copy.dtype_out(Tensor self, ScalarType dtype, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & view_copy_outf(const at::Tensor & self, at::ScalarType dtype, at::Tensor & out) { + return at::_ops::view_copy_dtype_out::call(self, dtype, out); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_compositeexplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_compositeexplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..7827b3e7ad7c2aae9690cb28e325c447effc406b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_compositeexplicitautograd_dispatch.h @@ -0,0 +1,28 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautograd { + +TORCH_API at::Tensor & view_copy_out(at::Tensor & out, const at::Tensor & self, at::IntArrayRef size); +TORCH_API at::Tensor & view_copy_outf(const at::Tensor & self, at::IntArrayRef size, at::Tensor & out); +TORCH_API at::Tensor & view_copy_symint_out(at::Tensor & out, const at::Tensor & self, c10::SymIntArrayRef size); +TORCH_API at::Tensor & view_copy_symint_outf(const at::Tensor & self, c10::SymIntArrayRef size, at::Tensor & out); +TORCH_API at::Tensor & view_copy_out(at::Tensor & out, const at::Tensor & self, at::ScalarType dtype); +TORCH_API at::Tensor & view_copy_outf(const at::Tensor & self, at::ScalarType dtype, at::Tensor & out); + +} // namespace compositeexplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_compositeexplicitautogradnonfunctional_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_compositeexplicitautogradnonfunctional_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..f2dd2c20b76e29daa972f8c5a6ecac15ff704e47 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_compositeexplicitautogradnonfunctional_dispatch.h @@ -0,0 +1,25 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautogradnonfunctional { + +TORCH_API at::Tensor view_copy(const at::Tensor & self, at::IntArrayRef size); +TORCH_API at::Tensor view_copy_symint(const at::Tensor & self, c10::SymIntArrayRef size); +TORCH_API at::Tensor view_copy(const at::Tensor & self, at::ScalarType dtype); + +} // namespace compositeexplicitautogradnonfunctional +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_native.h new file mode 100644 index 0000000000000000000000000000000000000000..181610609dd7d983ef29da296033c91cafb02b15 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_native.h @@ -0,0 +1,24 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor & view_copy_out_symint(const at::Tensor & self, c10::SymIntArrayRef size, at::Tensor & out); +TORCH_API at::Tensor view_copy_symint(const at::Tensor & self, c10::SymIntArrayRef size); +TORCH_API at::Tensor & view_copy_dtype_out(const at::Tensor & self, at::ScalarType dtype, at::Tensor & out); +TORCH_API at::Tensor view_copy_dtype(const at::Tensor & self, at::ScalarType dtype); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..0f6f4a15a64bd78604be9cb5229f0e7aabdc4e34 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_copy_ops.h @@ -0,0 +1,62 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API view_copy { + using schema = at::Tensor (const at::Tensor &, c10::SymIntArrayRef); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_copy"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "view_copy(Tensor self, SymInt[] size) -> Tensor"; + static at::Tensor call(const at::Tensor & self, c10::SymIntArrayRef size); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, c10::SymIntArrayRef size); +}; + +struct TORCH_API view_copy_dtype { + using schema = at::Tensor (const at::Tensor &, at::ScalarType); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_copy"; + static constexpr const char* overload_name = "dtype"; + static constexpr const char* schema_str = "view_copy.dtype(Tensor self, ScalarType dtype) -> Tensor"; + static at::Tensor call(const at::Tensor & self, at::ScalarType dtype); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, at::ScalarType dtype); +}; + +struct TORCH_API view_copy_out { + using schema = at::Tensor & (const at::Tensor &, c10::SymIntArrayRef, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_copy"; + static constexpr const char* overload_name = "out"; + static constexpr const char* schema_str = "view_copy.out(Tensor self, SymInt[] size, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Tensor & self, c10::SymIntArrayRef size, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, c10::SymIntArrayRef size, at::Tensor & out); +}; + +struct TORCH_API view_copy_dtype_out { + using schema = at::Tensor & (const at::Tensor &, at::ScalarType, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view_copy"; + static constexpr const char* overload_name = "dtype_out"; + static constexpr const char* schema_str = "view_copy.dtype_out(Tensor self, ScalarType dtype, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Tensor & self, at::ScalarType dtype, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, at::ScalarType dtype, at::Tensor & out); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_cpu_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_cpu_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..91fec458ab91b112c78fd1fd6cb18955c469d394 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_cpu_dispatch.h @@ -0,0 +1,24 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cpu { + +TORCH_API at::Tensor view(const at::Tensor & self, at::IntArrayRef size); +TORCH_API at::Tensor view_symint(const at::Tensor & self, c10::SymIntArrayRef size); + +} // namespace cpu +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_cuda_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_cuda_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..0b3f3cd53a586a6dbd1954b2b0a2aaed364277ab --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_cuda_dispatch.h @@ -0,0 +1,24 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cuda { + +TORCH_API at::Tensor view(const at::Tensor & self, at::IntArrayRef size); +TORCH_API at::Tensor view_symint(const at::Tensor & self, c10::SymIntArrayRef size); + +} // namespace cuda +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_meta_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_meta_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..a03452aa9fd2a975250c202e431fe0f21012f286 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_meta_dispatch.h @@ -0,0 +1,24 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace meta { + +TORCH_API at::Tensor view(const at::Tensor & self, at::IntArrayRef size); +TORCH_API at::Tensor view_symint(const at::Tensor & self, c10::SymIntArrayRef size); + +} // namespace meta +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_native.h new file mode 100644 index 0000000000000000000000000000000000000000..2e19524228faa48136974eb7f3ec64eac22a2b7a --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_native.h @@ -0,0 +1,24 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor view(const at::Tensor & self, at::IntArrayRef size); +TORCH_API at::Tensor view_nested(const at::Tensor & self, at::IntArrayRef size); +TORCH_API at::Tensor mkldnn_view(const at::Tensor & self, at::IntArrayRef size); +TORCH_API at::Tensor view_dtype(const at::Tensor & self, at::ScalarType dtype); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..80b4e080ed2df1d9167e3231689c07ddee13e16d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/view_ops.h @@ -0,0 +1,40 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API view { + using schema = at::Tensor (const at::Tensor &, c10::SymIntArrayRef); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "view(Tensor(a) self, SymInt[] size) -> Tensor(a)"; + static at::Tensor call(const at::Tensor & self, c10::SymIntArrayRef size); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, c10::SymIntArrayRef size); +}; + +struct TORCH_API view_dtype { + using schema = at::Tensor (const at::Tensor &, at::ScalarType); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::view"; + static constexpr const char* overload_name = "dtype"; + static constexpr const char* schema_str = "view.dtype(Tensor(a) self, ScalarType dtype) -> Tensor(a)"; + static at::Tensor call(const at::Tensor & self, at::ScalarType dtype); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, at::ScalarType dtype); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit.h new file mode 100644 index 0000000000000000000000000000000000000000..a575586ed5e118d10f3570b165942208bec89931 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit.h @@ -0,0 +1,36 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::vsplit.int(Tensor(a -> *) self, int sections) -> Tensor(a)[] +inline ::std::vector vsplit(const at::Tensor & self, int64_t sections) { + return at::_ops::vsplit_int::call(self, sections); +} + +// aten::vsplit.array(Tensor(a -> *) self, int[] indices) -> Tensor(a)[] +inline ::std::vector vsplit(const at::Tensor & self, at::IntArrayRef indices) { + return at::_ops::vsplit_array::call(self, indices); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit_compositeimplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit_compositeimplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..248adc9ead211c73a62affee2bf6b4721a9109e7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit_compositeimplicitautograd_dispatch.h @@ -0,0 +1,24 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeimplicitautograd { + +TORCH_API ::std::vector vsplit(const at::Tensor & self, int64_t sections); +TORCH_API ::std::vector vsplit(const at::Tensor & self, at::IntArrayRef indices); + +} // namespace compositeimplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit_native.h new file mode 100644 index 0000000000000000000000000000000000000000..dcc1bd9688e18eccd067a2fb6a500b3a6bb70f3b --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit_native.h @@ -0,0 +1,22 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API ::std::vector vsplit(const at::Tensor & self, int64_t sections); +TORCH_API ::std::vector vsplit(const at::Tensor & self, at::IntArrayRef indices); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..6748cf33e6262bd255604ead923a9d8516c8b4d1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vsplit_ops.h @@ -0,0 +1,40 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API vsplit_int { + using schema = ::std::vector (const at::Tensor &, int64_t); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::vsplit"; + static constexpr const char* overload_name = "int"; + static constexpr const char* schema_str = "vsplit.int(Tensor(a -> *) self, int sections) -> Tensor(a)[]"; + static ::std::vector call(const at::Tensor & self, int64_t sections); + static ::std::vector redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, int64_t sections); +}; + +struct TORCH_API vsplit_array { + using schema = ::std::vector (const at::Tensor &, at::IntArrayRef); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::vsplit"; + static constexpr const char* overload_name = "array"; + static constexpr const char* schema_str = "vsplit.array(Tensor(a -> *) self, int[] indices) -> Tensor(a)[]"; + static ::std::vector call(const at::Tensor & self, at::IntArrayRef indices); + static ::std::vector redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, at::IntArrayRef indices); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack.h new file mode 100644 index 0000000000000000000000000000000000000000..0d90795a83ceef2c6781a126683f2b93182191a0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack.h @@ -0,0 +1,40 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::vstack(Tensor[] tensors) -> Tensor +inline at::Tensor vstack(at::TensorList tensors) { + return at::_ops::vstack::call(tensors); +} + +// aten::vstack.out(Tensor[] tensors, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & vstack_out(at::Tensor & out, at::TensorList tensors) { + return at::_ops::vstack_out::call(tensors, out); +} +// aten::vstack.out(Tensor[] tensors, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & vstack_outf(at::TensorList tensors, at::Tensor & out) { + return at::_ops::vstack_out::call(tensors, out); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack_compositeimplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack_compositeimplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..f8f829aed908d8f009cc4c69672c9b621e80d7f7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack_compositeimplicitautograd_dispatch.h @@ -0,0 +1,25 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeimplicitautograd { + +TORCH_API at::Tensor vstack(at::TensorList tensors); +TORCH_API at::Tensor & vstack_out(at::Tensor & out, at::TensorList tensors); +TORCH_API at::Tensor & vstack_outf(at::TensorList tensors, at::Tensor & out); + +} // namespace compositeimplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack_native.h new file mode 100644 index 0000000000000000000000000000000000000000..59a1f20de5857ecfdc0340da07d712620aaa8556 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack_native.h @@ -0,0 +1,22 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor vstack(at::TensorList tensors); +TORCH_API at::Tensor & vstack_out(at::TensorList tensors, at::Tensor & out); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..b81480840adccfb55cae0ea6e9001d2b79614c25 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/vstack_ops.h @@ -0,0 +1,40 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API vstack { + using schema = at::Tensor (at::TensorList); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::vstack"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "vstack(Tensor[] tensors) -> Tensor"; + static at::Tensor call(at::TensorList tensors); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, at::TensorList tensors); +}; + +struct TORCH_API vstack_out { + using schema = at::Tensor & (at::TensorList, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::vstack"; + static constexpr const char* overload_name = "out"; + static constexpr const char* schema_str = "vstack.out(Tensor[] tensors, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(at::TensorList tensors, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, at::TensorList tensors, at::Tensor & out); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where.h new file mode 100644 index 0000000000000000000000000000000000000000..0b30de618dece7e401bb8aa73cf4f0ffebd70dd3 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where.h @@ -0,0 +1,60 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::where.self(Tensor condition, Tensor self, Tensor other) -> Tensor +inline at::Tensor where(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other) { + return at::_ops::where_self::call(condition, self, other); +} + +// aten::where.self_out(Tensor condition, Tensor self, Tensor other, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & where_out(at::Tensor & out, const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other) { + return at::_ops::where_self_out::call(condition, self, other, out); +} +// aten::where.self_out(Tensor condition, Tensor self, Tensor other, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & where_outf(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other, at::Tensor & out) { + return at::_ops::where_self_out::call(condition, self, other, out); +} + +// aten::where.ScalarSelf(Tensor condition, Scalar self, Tensor other) -> Tensor +inline at::Tensor where(const at::Tensor & condition, const at::Scalar & self, const at::Tensor & other) { + return at::_ops::where_ScalarSelf::call(condition, self, other); +} + +// aten::where.ScalarOther(Tensor condition, Tensor self, Scalar other) -> Tensor +inline at::Tensor where(const at::Tensor & condition, const at::Tensor & self, const at::Scalar & other) { + return at::_ops::where_ScalarOther::call(condition, self, other); +} + +// aten::where.Scalar(Tensor condition, Scalar self, Scalar other) -> Tensor +inline at::Tensor where(const at::Tensor & condition, const at::Scalar & self, const at::Scalar & other) { + return at::_ops::where_Scalar::call(condition, self, other); +} + +// aten::where(Tensor condition) -> Tensor[] +inline ::std::vector where(const at::Tensor & condition) { + return at::_ops::where::call(condition); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_compositeimplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_compositeimplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..36e00246c6e08e9b5bcf1365eadfb8eb971fa2bc --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_compositeimplicitautograd_dispatch.h @@ -0,0 +1,26 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeimplicitautograd { + +TORCH_API at::Tensor where(const at::Tensor & condition, const at::Scalar & self, const at::Tensor & other); +TORCH_API at::Tensor where(const at::Tensor & condition, const at::Tensor & self, const at::Scalar & other); +TORCH_API at::Tensor where(const at::Tensor & condition, const at::Scalar & self, const at::Scalar & other); +TORCH_API ::std::vector where(const at::Tensor & condition); + +} // namespace compositeimplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_cpu_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_cpu_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..f47c36a91f2d70d6fc347e2b9940a4ab754202a7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_cpu_dispatch.h @@ -0,0 +1,25 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cpu { + +TORCH_API at::Tensor where(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & where_out(at::Tensor & out, const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & where_outf(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other, at::Tensor & out); + +} // namespace cpu +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_cuda_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_cuda_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..204567ea097a53a4dcdcecad030420508afb11b7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_cuda_dispatch.h @@ -0,0 +1,25 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cuda { + +TORCH_API at::Tensor where(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & where_out(at::Tensor & out, const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & where_outf(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other, at::Tensor & out); + +} // namespace cuda +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_native.h new file mode 100644 index 0000000000000000000000000000000000000000..7da092cb38236ee876d7d4fed50bc3f4cd358e96 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_native.h @@ -0,0 +1,28 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor where(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & where_self_out(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other, at::Tensor & out); +TORCH_API at::Tensor NestedTensor_where(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & NestedTensor_where_out(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other, at::Tensor & out); +TORCH_API at::Tensor where(const at::Tensor & condition, const at::Scalar & self, const at::Tensor & other); +TORCH_API at::Tensor where(const at::Tensor & condition, const at::Tensor & self, const at::Scalar & other); +TORCH_API at::Tensor where(const at::Tensor & condition, const at::Scalar & self, const at::Scalar & other); +TORCH_API ::std::vector where(const at::Tensor & condition); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..020a7832f1ae49f8d8e8932aeb7bfcef04989bd8 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/where_ops.h @@ -0,0 +1,84 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API where_self { + using schema = at::Tensor (const at::Tensor &, const at::Tensor &, const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::where"; + static constexpr const char* overload_name = "self"; + static constexpr const char* schema_str = "where.self(Tensor condition, Tensor self, Tensor other) -> Tensor"; + static at::Tensor call(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other); +}; + +struct TORCH_API where_self_out { + using schema = at::Tensor & (const at::Tensor &, const at::Tensor &, const at::Tensor &, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::where"; + static constexpr const char* overload_name = "self_out"; + static constexpr const char* schema_str = "where.self_out(Tensor condition, Tensor self, Tensor other, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & condition, const at::Tensor & self, const at::Tensor & other, at::Tensor & out); +}; + +struct TORCH_API where_ScalarSelf { + using schema = at::Tensor (const at::Tensor &, const at::Scalar &, const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::where"; + static constexpr const char* overload_name = "ScalarSelf"; + static constexpr const char* schema_str = "where.ScalarSelf(Tensor condition, Scalar self, Tensor other) -> Tensor"; + static at::Tensor call(const at::Tensor & condition, const at::Scalar & self, const at::Tensor & other); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & condition, const at::Scalar & self, const at::Tensor & other); +}; + +struct TORCH_API where_ScalarOther { + using schema = at::Tensor (const at::Tensor &, const at::Tensor &, const at::Scalar &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::where"; + static constexpr const char* overload_name = "ScalarOther"; + static constexpr const char* schema_str = "where.ScalarOther(Tensor condition, Tensor self, Scalar other) -> Tensor"; + static at::Tensor call(const at::Tensor & condition, const at::Tensor & self, const at::Scalar & other); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & condition, const at::Tensor & self, const at::Scalar & other); +}; + +struct TORCH_API where_Scalar { + using schema = at::Tensor (const at::Tensor &, const at::Scalar &, const at::Scalar &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::where"; + static constexpr const char* overload_name = "Scalar"; + static constexpr const char* schema_str = "where.Scalar(Tensor condition, Scalar self, Scalar other) -> Tensor"; + static at::Tensor call(const at::Tensor & condition, const at::Scalar & self, const at::Scalar & other); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & condition, const at::Scalar & self, const at::Scalar & other); +}; + +struct TORCH_API where { + using schema = ::std::vector (const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::where"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "where(Tensor condition) -> Tensor[]"; + static ::std::vector call(const at::Tensor & condition); + static ::std::vector redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & condition); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy.h new file mode 100644 index 0000000000000000000000000000000000000000..5750fa0ca25a574e5809c4d65157c31615c279ee --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy.h @@ -0,0 +1,78 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::xlogy.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor xlogy(const at::Tensor & self, const at::Tensor & other) { + return at::_ops::xlogy_Tensor::call(self, other); +} + +// aten::xlogy.Scalar_Self(Scalar self, Tensor other) -> Tensor +inline at::Tensor xlogy(const at::Scalar & self, const at::Tensor & other) { + return at::_ops::xlogy_Scalar_Self::call(self, other); +} + +// aten::xlogy.Scalar_Other(Tensor self, Scalar other) -> Tensor +inline at::Tensor xlogy(const at::Tensor & self, const at::Scalar & other) { + return at::_ops::xlogy_Scalar_Other::call(self, other); +} + +// aten::xlogy_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!) +inline at::Tensor & xlogy_(at::Tensor & self, const at::Tensor & other) { + return at::_ops::xlogy__Tensor::call(self, other); +} + +// aten::xlogy_.Scalar_Other(Tensor(a!) self, Scalar other) -> Tensor(a!) +inline at::Tensor & xlogy_(at::Tensor & self, const at::Scalar & other) { + return at::_ops::xlogy__Scalar_Other::call(self, other); +} + +// aten::xlogy.OutTensor(Tensor self, Tensor other, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & xlogy_out(at::Tensor & out, const at::Tensor & self, const at::Tensor & other) { + return at::_ops::xlogy_OutTensor::call(self, other, out); +} +// aten::xlogy.OutTensor(Tensor self, Tensor other, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & xlogy_outf(const at::Tensor & self, const at::Tensor & other, at::Tensor & out) { + return at::_ops::xlogy_OutTensor::call(self, other, out); +} + +// aten::xlogy.OutScalar_Self(Scalar self, Tensor other, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & xlogy_out(at::Tensor & out, const at::Scalar & self, const at::Tensor & other) { + return at::_ops::xlogy_OutScalar_Self::call(self, other, out); +} +// aten::xlogy.OutScalar_Self(Scalar self, Tensor other, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & xlogy_outf(const at::Scalar & self, const at::Tensor & other, at::Tensor & out) { + return at::_ops::xlogy_OutScalar_Self::call(self, other, out); +} + +// aten::xlogy.OutScalar_Other(Tensor self, Scalar other, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & xlogy_out(at::Tensor & out, const at::Tensor & self, const at::Scalar & other) { + return at::_ops::xlogy_OutScalar_Other::call(self, other, out); +} +// aten::xlogy.OutScalar_Other(Tensor self, Scalar other, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & xlogy_outf(const at::Tensor & self, const at::Scalar & other, at::Tensor & out) { + return at::_ops::xlogy_OutScalar_Other::call(self, other, out); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_compositeexplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_compositeexplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..2430dac31d52acedb6f05431b878d10248666252 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_compositeexplicitautograd_dispatch.h @@ -0,0 +1,29 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautograd { + +TORCH_API at::Tensor xlogy(const at::Scalar & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_out(at::Tensor & out, const at::Scalar & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_outf(const at::Scalar & self, const at::Tensor & other, at::Tensor & out); +TORCH_API at::Tensor xlogy(const at::Tensor & self, const at::Scalar & other); +TORCH_API at::Tensor & xlogy_out(at::Tensor & out, const at::Tensor & self, const at::Scalar & other); +TORCH_API at::Tensor & xlogy_outf(const at::Tensor & self, const at::Scalar & other, at::Tensor & out); +TORCH_API at::Tensor & xlogy_(at::Tensor & self, const at::Scalar & other); + +} // namespace compositeexplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_compositeexplicitautogradnonfunctional_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_compositeexplicitautogradnonfunctional_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..44c1228a1aeca10c2716814ea609f3fe87f53df6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_compositeexplicitautogradnonfunctional_dispatch.h @@ -0,0 +1,24 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautogradnonfunctional { + +TORCH_API at::Tensor xlogy(const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_(at::Tensor & self, const at::Tensor & other); + +} // namespace compositeexplicitautogradnonfunctional +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_cpu_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_cpu_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..9010f9c905d49bf2d3438b5968b1a0db8b7db231 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_cpu_dispatch.h @@ -0,0 +1,26 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cpu { + +TORCH_API at::Tensor xlogy(const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_out(at::Tensor & out, const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_outf(const at::Tensor & self, const at::Tensor & other, at::Tensor & out); +TORCH_API at::Tensor & xlogy_(at::Tensor & self, const at::Tensor & other); + +} // namespace cpu +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_cuda_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_cuda_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..bd200e821a75af658957bb5614bb442b02302065 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_cuda_dispatch.h @@ -0,0 +1,26 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cuda { + +TORCH_API at::Tensor xlogy(const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_out(at::Tensor & out, const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_outf(const at::Tensor & self, const at::Tensor & other, at::Tensor & out); +TORCH_API at::Tensor & xlogy_(at::Tensor & self, const at::Tensor & other); + +} // namespace cuda +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_meta.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_meta.h new file mode 100644 index 0000000000000000000000000000000000000000..6c26bb439a81181218870c97045ed0a192076db1 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_meta.h @@ -0,0 +1,27 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeMetaFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at { +namespace meta { + +struct TORCH_API structured_xlogy_Tensor : public TensorIteratorBase { + + + void meta(const at::Tensor & self, const at::Tensor & other); +}; + +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_meta_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_meta_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..d7ac12b254998e5d772f0fd116055e160080f0fd --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_meta_dispatch.h @@ -0,0 +1,26 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace meta { + +TORCH_API at::Tensor xlogy(const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_out(at::Tensor & out, const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_outf(const at::Tensor & self, const at::Tensor & other, at::Tensor & out); +TORCH_API at::Tensor & xlogy_(at::Tensor & self, const at::Tensor & other); + +} // namespace meta +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_native.h new file mode 100644 index 0000000000000000000000000000000000000000..6fae59421c1f3596efe6e4d4cecb2a0c8226565f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_native.h @@ -0,0 +1,28 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +namespace at { +namespace native { +struct TORCH_API structured_xlogy_out : public at::meta::structured_xlogy_Tensor { +void impl(const at::Tensor & self, const at::Tensor & other, const at::Tensor & out); +}; +TORCH_API at::Tensor xlogy(const at::Scalar & self, const at::Tensor & other); +TORCH_API at::Tensor & xlogy_out(const at::Scalar & self, const at::Tensor & other, at::Tensor & out); +TORCH_API at::Tensor xlogy(const at::Tensor & self, const at::Scalar & other); +TORCH_API at::Tensor & xlogy_out(const at::Tensor & self, const at::Scalar & other, at::Tensor & out); +TORCH_API at::Tensor & xlogy_(at::Tensor & self, const at::Scalar & other); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..e6958927148431e78438d82ca5c4f9259d05f00f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xlogy_ops.h @@ -0,0 +1,106 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API xlogy_Tensor { + using schema = at::Tensor (const at::Tensor &, const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::xlogy"; + static constexpr const char* overload_name = "Tensor"; + static constexpr const char* schema_str = "xlogy.Tensor(Tensor self, Tensor other) -> Tensor"; + static at::Tensor call(const at::Tensor & self, const at::Tensor & other); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, const at::Tensor & other); +}; + +struct TORCH_API xlogy_Scalar_Self { + using schema = at::Tensor (const at::Scalar &, const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::xlogy"; + static constexpr const char* overload_name = "Scalar_Self"; + static constexpr const char* schema_str = "xlogy.Scalar_Self(Scalar self, Tensor other) -> Tensor"; + static at::Tensor call(const at::Scalar & self, const at::Tensor & other); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Scalar & self, const at::Tensor & other); +}; + +struct TORCH_API xlogy_Scalar_Other { + using schema = at::Tensor (const at::Tensor &, const at::Scalar &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::xlogy"; + static constexpr const char* overload_name = "Scalar_Other"; + static constexpr const char* schema_str = "xlogy.Scalar_Other(Tensor self, Scalar other) -> Tensor"; + static at::Tensor call(const at::Tensor & self, const at::Scalar & other); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, const at::Scalar & other); +}; + +struct TORCH_API xlogy__Tensor { + using schema = at::Tensor & (at::Tensor &, const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::xlogy_"; + static constexpr const char* overload_name = "Tensor"; + static constexpr const char* schema_str = "xlogy_.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!)"; + static at::Tensor & call(at::Tensor & self, const at::Tensor & other); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, at::Tensor & self, const at::Tensor & other); +}; + +struct TORCH_API xlogy__Scalar_Other { + using schema = at::Tensor & (at::Tensor &, const at::Scalar &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::xlogy_"; + static constexpr const char* overload_name = "Scalar_Other"; + static constexpr const char* schema_str = "xlogy_.Scalar_Other(Tensor(a!) self, Scalar other) -> Tensor(a!)"; + static at::Tensor & call(at::Tensor & self, const at::Scalar & other); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, at::Tensor & self, const at::Scalar & other); +}; + +struct TORCH_API xlogy_OutTensor { + using schema = at::Tensor & (const at::Tensor &, const at::Tensor &, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::xlogy"; + static constexpr const char* overload_name = "OutTensor"; + static constexpr const char* schema_str = "xlogy.OutTensor(Tensor self, Tensor other, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Tensor & self, const at::Tensor & other, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, const at::Tensor & other, at::Tensor & out); +}; + +struct TORCH_API xlogy_OutScalar_Self { + using schema = at::Tensor & (const at::Scalar &, const at::Tensor &, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::xlogy"; + static constexpr const char* overload_name = "OutScalar_Self"; + static constexpr const char* schema_str = "xlogy.OutScalar_Self(Scalar self, Tensor other, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Scalar & self, const at::Tensor & other, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Scalar & self, const at::Tensor & other, at::Tensor & out); +}; + +struct TORCH_API xlogy_OutScalar_Other { + using schema = at::Tensor & (const at::Tensor &, const at::Scalar &, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::xlogy"; + static constexpr const char* overload_name = "OutScalar_Other"; + static constexpr const char* schema_str = "xlogy.OutScalar_Other(Tensor self, Scalar other, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Tensor & self, const at::Scalar & other, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, const at::Scalar & other, at::Tensor & out); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor.h new file mode 100644 index 0000000000000000000000000000000000000000..e4805bf0edbd05cbffad7e85395822ba42719743 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor.h @@ -0,0 +1,36 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::__xor__.Scalar(Tensor self, Scalar other) -> Tensor +inline at::Tensor __xor__(const at::Tensor & self, const at::Scalar & other) { + return at::_ops::__xor___Scalar::call(self, other); +} + +// aten::__xor__.Tensor(Tensor self, Tensor other) -> Tensor +inline at::Tensor __xor__(const at::Tensor & self, const at::Tensor & other) { + return at::_ops::__xor___Tensor::call(self, other); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor_compositeimplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor_compositeimplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..6aab74f0bb16a4ff25ff5e8b09ea910c660d47d9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor_compositeimplicitautograd_dispatch.h @@ -0,0 +1,26 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeimplicitautograd { + +TORCH_API at::Tensor __xor__(const at::Tensor & self, const at::Scalar & other); +TORCH_API at::Tensor & __ixor__(at::Tensor & self, const at::Scalar & other); +TORCH_API at::Tensor __xor__(const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & __ixor__(at::Tensor & self, const at::Tensor & other); + +} // namespace compositeimplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor_native.h new file mode 100644 index 0000000000000000000000000000000000000000..73289b3182d5aa422910188268e280c1af4c936f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor_native.h @@ -0,0 +1,24 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor __xor__(const at::Tensor & self, const at::Scalar & other); +TORCH_API at::Tensor & __ixor__(at::Tensor & self, const at::Scalar & other); +TORCH_API at::Tensor __xor__(const at::Tensor & self, const at::Tensor & other); +TORCH_API at::Tensor & __ixor__(at::Tensor & self, const at::Tensor & other); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..9dca02786a016b494f674952a7c35c0024ab87e6 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/xor_ops.h @@ -0,0 +1,62 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API __xor___Scalar { + using schema = at::Tensor (const at::Tensor &, const at::Scalar &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::__xor__"; + static constexpr const char* overload_name = "Scalar"; + static constexpr const char* schema_str = "__xor__.Scalar(Tensor self, Scalar other) -> Tensor"; + static at::Tensor call(const at::Tensor & self, const at::Scalar & other); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, const at::Scalar & other); +}; + +struct TORCH_API __xor___Tensor { + using schema = at::Tensor (const at::Tensor &, const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::__xor__"; + static constexpr const char* overload_name = "Tensor"; + static constexpr const char* schema_str = "__xor__.Tensor(Tensor self, Tensor other) -> Tensor"; + static at::Tensor call(const at::Tensor & self, const at::Tensor & other); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, const at::Tensor & other); +}; + +struct TORCH_API __ixor___Scalar { + using schema = at::Tensor & (at::Tensor &, const at::Scalar &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::__ixor__"; + static constexpr const char* overload_name = "Scalar"; + static constexpr const char* schema_str = "__ixor__.Scalar(Tensor(a!) self, Scalar other) -> Tensor(a!)"; + static at::Tensor & call(at::Tensor & self, const at::Scalar & other); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, at::Tensor & self, const at::Scalar & other); +}; + +struct TORCH_API __ixor___Tensor { + using schema = at::Tensor & (at::Tensor &, const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::__ixor__"; + static constexpr const char* overload_name = "Tensor"; + static constexpr const char* schema_str = "__ixor__.Tensor(Tensor(a!) self, Tensor other) -> Tensor(a!)"; + static at::Tensor & call(at::Tensor & self, const at::Tensor & other); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, at::Tensor & self, const at::Tensor & other); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero.h new file mode 100644 index 0000000000000000000000000000000000000000..3fe906bbb42b981ab164f0b1ae5bbd2c46532261 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero.h @@ -0,0 +1,45 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::zero_(Tensor(a!) self) -> Tensor(a!) +inline at::Tensor & zero_(at::Tensor & self) { + return at::_ops::zero_::call(self); +} + +// aten::zero.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zero_out(at::Tensor & out, const at::Tensor & self) { + return at::_ops::zero_out::call(self, out); +} +// aten::zero.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zero_outf(const at::Tensor & self, at::Tensor & out) { + return at::_ops::zero_out::call(self, out); +} + +// aten::zero(Tensor self) -> Tensor +inline at::Tensor zero(const at::Tensor & self) { + return at::_ops::zero::call(self); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_compositeexplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_compositeexplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..9f8f134bf0482956e2a688bf7f9a4a2751afa241 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_compositeexplicitautograd_dispatch.h @@ -0,0 +1,25 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautograd { + +TORCH_API at::Tensor zero(const at::Tensor & self); +TORCH_API at::Tensor & zero_out(at::Tensor & out, const at::Tensor & self); +TORCH_API at::Tensor & zero_outf(const at::Tensor & self, at::Tensor & out); + +} // namespace compositeexplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_cpu_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_cpu_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..533113c43f0fdae65703d1221af15b4e30aa8f57 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_cpu_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cpu { + +TORCH_API at::Tensor & zero_(at::Tensor & self); + +} // namespace cpu +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_cuda_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_cuda_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..2c17107c2b5a20b11960c2643c70acbd04aef241 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_cuda_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace cuda { + +TORCH_API at::Tensor & zero_(at::Tensor & self); + +} // namespace cuda +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_meta_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_meta_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..99c49dbe1ae1cb8a9d8d8274ca2c1497784d2fa9 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_meta_dispatch.h @@ -0,0 +1,23 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace meta { + +TORCH_API at::Tensor & zero_(at::Tensor & self); + +} // namespace meta +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_native.h new file mode 100644 index 0000000000000000000000000000000000000000..ac496a1e0cda39be848270d5dc325afe602e9f71 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_native.h @@ -0,0 +1,28 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor zero(const at::Tensor & self); +TORCH_API at::Tensor & zero_out(const at::Tensor & self, at::Tensor & out); +TORCH_API at::Tensor & zero_(at::Tensor & self); +TORCH_API at::Tensor & zero_meta_(at::Tensor & self); +TORCH_API at::Tensor & zero_nested_(at::Tensor & self); +TORCH_API at::Tensor & zero_sparse_(at::Tensor & self); +TORCH_API at::Tensor & zero_sparse_csr_(at::Tensor & self); +TORCH_API at::Tensor & mkldnn_zero_(at::Tensor & self); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..3e2c1b4fd8113139c4a25b8ae03397ed0d121c71 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zero_ops.h @@ -0,0 +1,51 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API zero_ { + using schema = at::Tensor & (at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::zero_"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "zero_(Tensor(a!) self) -> Tensor(a!)"; + static at::Tensor & call(at::Tensor & self); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, at::Tensor & self); +}; + +struct TORCH_API zero_out { + using schema = at::Tensor & (const at::Tensor &, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::zero"; + static constexpr const char* overload_name = "out"; + static constexpr const char* schema_str = "zero.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Tensor & self, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, at::Tensor & out); +}; + +struct TORCH_API zero { + using schema = at::Tensor (const at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::zero"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "zero(Tensor self) -> Tensor"; + static at::Tensor call(const at::Tensor & self); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros.h new file mode 100644 index 0000000000000000000000000000000000000000..eabb99f9b02ddbf341f846e2f4d24833bac86bae --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros.h @@ -0,0 +1,132 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::zeros.names(int[] size, *, Dimname[]? names, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor zeros(at::IntArrayRef size, ::std::optional names, at::TensorOptions options={}) { + return at::_ops::zeros_names::call(size, names, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} +// aten::zeros.names(int[] size, *, Dimname[]? names, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor zeros(at::IntArrayRef size, ::std::optional names, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) { + return at::_ops::zeros_names::call(size, names, dtype, layout, device, pin_memory); +} + +// aten::zeros(SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor zeros(at::IntArrayRef size, at::TensorOptions options={}) { + return at::_ops::zeros::call(c10::fromIntArrayRefSlow(size), c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} +namespace symint { + template >> + at::Tensor zeros(at::IntArrayRef size, at::TensorOptions options={}) { + return at::_ops::zeros::call(c10::fromIntArrayRefSlow(size), c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); + } +} + +// aten::zeros(SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor zeros(at::IntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) { + return at::_ops::zeros::call(c10::fromIntArrayRefSlow(size), dtype, layout, device, pin_memory); +} +namespace symint { + template >> + at::Tensor zeros(at::IntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) { + return at::_ops::zeros::call(c10::fromIntArrayRefSlow(size), dtype, layout, device, pin_memory); + } +} + +// aten::zeros(SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor zeros_symint(c10::SymIntArrayRef size, at::TensorOptions options={}) { + return at::_ops::zeros::call(size, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); +} +namespace symint { + template >> + at::Tensor zeros(c10::SymIntArrayRef size, at::TensorOptions options={}) { + return at::_ops::zeros::call(size, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt()); + } +} + +// aten::zeros(SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor +inline at::Tensor zeros_symint(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) { + return at::_ops::zeros::call(size, dtype, layout, device, pin_memory); +} +namespace symint { + template >> + at::Tensor zeros(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory) { + return at::_ops::zeros::call(size, dtype, layout, device, pin_memory); + } +} + +// aten::zeros.out(SymInt[] size, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zeros_out(at::Tensor & out, at::IntArrayRef size) { + return at::_ops::zeros_out::call(c10::fromIntArrayRefSlow(size), out); +} +namespace symint { + template >> + at::Tensor & zeros_out(at::Tensor & out, at::IntArrayRef size) { + return at::_ops::zeros_out::call(c10::fromIntArrayRefSlow(size), out); + } +} + +// aten::zeros.out(SymInt[] size, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zeros_outf(at::IntArrayRef size, at::Tensor & out) { + return at::_ops::zeros_out::call(c10::fromIntArrayRefSlow(size), out); +} +namespace symint { + template >> + at::Tensor & zeros_outf(at::IntArrayRef size, at::Tensor & out) { + return at::_ops::zeros_out::call(c10::fromIntArrayRefSlow(size), out); + } +} + +// aten::zeros.out(SymInt[] size, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zeros_symint_out(at::Tensor & out, c10::SymIntArrayRef size) { + return at::_ops::zeros_out::call(size, out); +} +namespace symint { + template >> + at::Tensor & zeros_out(at::Tensor & out, c10::SymIntArrayRef size) { + return at::_ops::zeros_out::call(size, out); + } +} + +// aten::zeros.out(SymInt[] size, *, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zeros_symint_outf(c10::SymIntArrayRef size, at::Tensor & out) { + return at::_ops::zeros_out::call(size, out); +} +namespace symint { + template >> + at::Tensor & zeros_outf(c10::SymIntArrayRef size, at::Tensor & out) { + return at::_ops::zeros_out::call(size, out); + } +} + +// aten::zeros.names_out(int[] size, *, Dimname[]? names, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zeros_out(at::Tensor & out, at::IntArrayRef size, ::std::optional names) { + return at::_ops::zeros_names_out::call(size, names, out); +} +// aten::zeros.names_out(int[] size, *, Dimname[]? names, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zeros_outf(at::IntArrayRef size, ::std::optional names, at::Tensor & out) { + return at::_ops::zeros_names_out::call(size, names, out); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_compositeexplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_compositeexplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..88da4fff1364ed77f89cca67cdd95430a61a22e7 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_compositeexplicitautograd_dispatch.h @@ -0,0 +1,34 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautograd { + +TORCH_API at::Tensor zeros(at::IntArrayRef size, ::std::optional names, at::TensorOptions options={}); +TORCH_API at::Tensor zeros(at::IntArrayRef size, ::std::optional names, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory); +TORCH_API at::Tensor & zeros_out(at::Tensor & out, at::IntArrayRef size, ::std::optional names); +TORCH_API at::Tensor & zeros_outf(at::IntArrayRef size, ::std::optional names, at::Tensor & out); +TORCH_API at::Tensor zeros(at::IntArrayRef size, at::TensorOptions options={}); +TORCH_API at::Tensor zeros(at::IntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory); +TORCH_API at::Tensor zeros_symint(c10::SymIntArrayRef size, at::TensorOptions options={}); +TORCH_API at::Tensor zeros_symint(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory); +TORCH_API at::Tensor & zeros_out(at::Tensor & out, at::IntArrayRef size); +TORCH_API at::Tensor & zeros_outf(at::IntArrayRef size, at::Tensor & out); +TORCH_API at::Tensor & zeros_symint_out(at::Tensor & out, c10::SymIntArrayRef size); +TORCH_API at::Tensor & zeros_symint_outf(c10::SymIntArrayRef size, at::Tensor & out); + +} // namespace compositeexplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like.h new file mode 100644 index 0000000000000000000000000000000000000000..af045c36881b7e91464fbef493cb2febebb5d169 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like.h @@ -0,0 +1,44 @@ +#pragma once + +// @generated by torchgen/gen.py from Function.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +#include + +namespace at { + + +// aten::zeros_like(Tensor self, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None, MemoryFormat? memory_format=None) -> Tensor +inline at::Tensor zeros_like(const at::Tensor & self, at::TensorOptions options={}, ::std::optional memory_format=::std::nullopt) { + return at::_ops::zeros_like::call(self, c10::optTypeMetaToScalarType(options.dtype_opt()), options.layout_opt(), options.device_opt(), options.pinned_memory_opt(), c10::impl::check_tensor_options_and_extract_memory_format(options, memory_format)); +} +// aten::zeros_like(Tensor self, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None, MemoryFormat? memory_format=None) -> Tensor +inline at::Tensor zeros_like(const at::Tensor & self, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory, ::std::optional memory_format) { + return at::_ops::zeros_like::call(self, dtype, layout, device, pin_memory, memory_format); +} + +// aten::zeros_like.out(Tensor self, *, MemoryFormat? memory_format=None, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zeros_like_out(at::Tensor & out, const at::Tensor & self, ::std::optional memory_format=::std::nullopt) { + return at::_ops::zeros_like_out::call(self, memory_format, out); +} +// aten::zeros_like.out(Tensor self, *, MemoryFormat? memory_format=None, Tensor(a!) out) -> Tensor(a!) +inline at::Tensor & zeros_like_outf(const at::Tensor & self, ::std::optional memory_format, at::Tensor & out) { + return at::_ops::zeros_like_out::call(self, memory_format, out); +} + +} diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_compositeexplicitautograd_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_compositeexplicitautograd_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..446a2ffd34ba4c7fbf956ff09dfccbfa4e589b34 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_compositeexplicitautograd_dispatch.h @@ -0,0 +1,26 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeexplicitautograd { + +TORCH_API at::Tensor zeros_like(const at::Tensor & self, at::TensorOptions options={}, ::std::optional memory_format=::std::nullopt); +TORCH_API at::Tensor zeros_like(const at::Tensor & self, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory, ::std::optional memory_format); +TORCH_API at::Tensor & zeros_like_out(at::Tensor & out, const at::Tensor & self, ::std::optional memory_format=::std::nullopt); +TORCH_API at::Tensor & zeros_like_outf(const at::Tensor & self, ::std::optional memory_format, at::Tensor & out); + +} // namespace compositeexplicitautograd +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_compositeimplicitautogradnestedtensor_dispatch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_compositeimplicitautogradnestedtensor_dispatch.h new file mode 100644 index 0000000000000000000000000000000000000000..4f97dace7c589e3aded9cff601c38ab0dc345e47 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_compositeimplicitautogradnestedtensor_dispatch.h @@ -0,0 +1,24 @@ +#pragma once +// @generated by torchgen/gen.py from DispatchKeyFunction.h + +// NB: The implementing C++ file is RegisterDispatchKey.cpp + +// The only #includes we need are for custom classes that have defaults in the C++ API +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { + +namespace compositeimplicitautogradnestedtensor { + +TORCH_API at::Tensor zeros_like(const at::Tensor & self, at::TensorOptions options={}, ::std::optional memory_format=::std::nullopt); +TORCH_API at::Tensor zeros_like(const at::Tensor & self, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory, ::std::optional memory_format); + +} // namespace compositeimplicitautogradnestedtensor +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_native.h new file mode 100644 index 0000000000000000000000000000000000000000..eb0d1cd08b388cc473cccf67e0bfc50f0eec0cb0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_native.h @@ -0,0 +1,22 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor zeros_like(const at::Tensor & self, ::std::optional dtype={}, ::std::optional layout={}, ::std::optional device={}, ::std::optional pin_memory={}, ::std::optional memory_format=::std::nullopt); +TORCH_API at::Tensor & zeros_like_out(const at::Tensor & self, ::std::optional memory_format, at::Tensor & out); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..cbc1e919cb3a15e2b73d8d0151e4de4f3b30e796 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_like_ops.h @@ -0,0 +1,40 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API zeros_like { + using schema = at::Tensor (const at::Tensor &, ::std::optional, ::std::optional, ::std::optional, ::std::optional, ::std::optional); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::zeros_like"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "zeros_like(Tensor self, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None, MemoryFormat? memory_format=None) -> Tensor"; + static at::Tensor call(const at::Tensor & self, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory, ::std::optional memory_format); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory, ::std::optional memory_format); +}; + +struct TORCH_API zeros_like_out { + using schema = at::Tensor & (const at::Tensor &, ::std::optional, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::zeros_like"; + static constexpr const char* overload_name = "out"; + static constexpr const char* schema_str = "zeros_like.out(Tensor self, *, MemoryFormat? memory_format=None, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(const at::Tensor & self, ::std::optional memory_format, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, const at::Tensor & self, ::std::optional memory_format, at::Tensor & out); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_native.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_native.h new file mode 100644 index 0000000000000000000000000000000000000000..ab1bad3edd461fc8406b92f3450c27aefe368b54 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_native.h @@ -0,0 +1,25 @@ +#pragma once + +// @generated by torchgen/gen.py from NativeFunction.h + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + + +namespace at { +namespace native { +TORCH_API at::Tensor zeros(at::IntArrayRef size, ::std::optional names, ::std::optional dtype={}, ::std::optional layout={}, ::std::optional device={}, ::std::optional pin_memory={}); +TORCH_API at::Tensor & zeros_names_out(at::IntArrayRef size, ::std::optional names, at::Tensor & out); +TORCH_API at::Tensor zeros_symint(c10::SymIntArrayRef size, ::std::optional dtype={}, ::std::optional layout={}, ::std::optional device={}, ::std::optional pin_memory={}); +TORCH_API at::Tensor & zeros_out(at::IntArrayRef size, at::Tensor & out); +TORCH_API at::Tensor & zeros_sparse_out(at::IntArrayRef size, at::Tensor & out); +} // namespace native +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_ops.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_ops.h new file mode 100644 index 0000000000000000000000000000000000000000..639a9231eaf3fcb0d5755bfd5ea1ac1c80370813 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/ops/zeros_ops.h @@ -0,0 +1,62 @@ +#pragma once + +// @generated by torchgen/gen.py from Operator.h + +#include +#include +#include + +// Forward declarations of any types needed in the operator signatures. +// We can't directly include these classes because it will cause circular include dependencies. +// This file is included by TensorBody.h, which defines the Tensor class. +#include + +namespace at { +namespace _ops { + + +struct TORCH_API zeros_names { + using schema = at::Tensor (at::IntArrayRef, ::std::optional, ::std::optional, ::std::optional, ::std::optional, ::std::optional); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::zeros"; + static constexpr const char* overload_name = "names"; + static constexpr const char* schema_str = "zeros.names(int[] size, *, Dimname[]? names, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor"; + static at::Tensor call(at::IntArrayRef size, ::std::optional names, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, at::IntArrayRef size, ::std::optional names, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory); +}; + +struct TORCH_API zeros { + using schema = at::Tensor (c10::SymIntArrayRef, ::std::optional, ::std::optional, ::std::optional, ::std::optional); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::zeros"; + static constexpr const char* overload_name = ""; + static constexpr const char* schema_str = "zeros(SymInt[] size, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, bool? pin_memory=None) -> Tensor"; + static at::Tensor call(c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory); + static at::Tensor redispatch(c10::DispatchKeySet dispatchKeySet, c10::SymIntArrayRef size, ::std::optional dtype, ::std::optional layout, ::std::optional device, ::std::optional pin_memory); +}; + +struct TORCH_API zeros_out { + using schema = at::Tensor & (c10::SymIntArrayRef, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::zeros"; + static constexpr const char* overload_name = "out"; + static constexpr const char* schema_str = "zeros.out(SymInt[] size, *, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(c10::SymIntArrayRef size, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, c10::SymIntArrayRef size, at::Tensor & out); +}; + +struct TORCH_API zeros_names_out { + using schema = at::Tensor & (at::IntArrayRef, ::std::optional, at::Tensor &); + using ptr_schema = schema*; + // See Note [static constexpr char* members for windows NVCC] + static constexpr const char* name = "aten::zeros"; + static constexpr const char* overload_name = "names_out"; + static constexpr const char* schema_str = "zeros.names_out(int[] size, *, Dimname[]? names, Tensor(a!) out) -> Tensor(a!)"; + static at::Tensor & call(at::IntArrayRef size, ::std::optional names, at::Tensor & out); + static at::Tensor & redispatch(c10::DispatchKeySet dispatchKeySet, at::IntArrayRef size, ::std::optional names, at::Tensor & out); +}; + +}} // namespace at::_ops diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/quantized/QTensorImpl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/quantized/QTensorImpl.h new file mode 100644 index 0000000000000000000000000000000000000000..127fa78de12d16fadf15ec9971f5f77112ffe580 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/quantized/QTensorImpl.h @@ -0,0 +1,125 @@ +#pragma once + +#include +#include +#include + +namespace at { + +/** + * QTensorImpl is a TensorImpl for Quantized Tensors, it stores Quantizer which + * specifies the quantization scheme and parameters, for more information please + * see ATen/quantized/Quantizer.h + * + * We'll use QTensor in code or documentation to refer to a Tensor with QTensorImpl. + */ +struct TORCH_API QTensorImpl : public c10::TensorImpl { + public: + QTensorImpl( + Storage&& storage, + DispatchKeySet key_set, + const caffe2::TypeMeta data_type, + QuantizerPtr quantizer); + + // See Note [Enum ImplType] + QTensorImpl( + ImplType type, + Storage&& storage, + DispatchKeySet key_set, + const caffe2::TypeMeta data_type, + QuantizerPtr quantizer); + + + // TODO: Expose in PyTorch Frontend + QuantizerPtr quantizer() { + return quantizer_; + } + + void set_quantizer_(QuantizerPtr quantizer) { + quantizer_ = quantizer; + } + + /** + * Return a TensorImpl that is a shallow-copy of this TensorImpl. + * + * For usage of `version_counter` and `allow_tensor_metadata_change`, + * see NOTE [ TensorImpl Shallow-Copying ]. + */ + c10::intrusive_ptr shallow_copy_and_detach( + const c10::VariableVersion& version_counter, + bool allow_tensor_metadata_change) const override { + auto impl = c10::make_intrusive( + Storage(storage()), key_set(), data_type_, quantizer_); + copy_tensor_metadata( + /*src_impl=*/this, + /*dest_impl=*/impl.get(), + /*version_counter=*/version_counter, + /*allow_tensor_metadata_change=*/allow_tensor_metadata_change); + impl->refresh_numel(); + impl->refresh_contiguous(); + return impl; + } + + /** + * Return a TensorImpl that is a shallow-copy of this TensorImpl. + * + * For usage of `version_counter` and `allow_tensor_metadata_change`, + * see NOTE [ TensorImpl Shallow-Copying ]. + */ + c10::intrusive_ptr shallow_copy_and_detach( + c10::VariableVersion&& version_counter, + bool allow_tensor_metadata_change) const override { + auto impl = c10::make_intrusive( + Storage(storage()), key_set(), data_type_, quantizer_); + copy_tensor_metadata( + /*src_impl=*/this, + /*dest_impl=*/impl.get(), + /*version_counter=*/std::move(version_counter), + /*allow_tensor_metadata_change=*/allow_tensor_metadata_change); + impl->refresh_numel(); + impl->refresh_contiguous(); + return impl; + } + + /** + * Shallow-copies data from another TensorImpl into this TensorImpl. + * + * For why this function doesn't check this TensorImpl's `allow_tensor_metadata_change_`, + * see NOTE [ TensorImpl Shallow-Copying ]. + */ + void shallow_copy_from(const c10::intrusive_ptr& impl) override { + AT_ASSERT(has_compatible_shallow_copy_type(impl->key_set())); + auto q_impl = static_cast(impl.get()); + copy_tensor_metadata( + /*src_impl=*/q_impl, + /*dest_impl=*/this, + /*version_counter=*/version_counter(), + /*allow_tensor_metadata_change=*/allow_tensor_metadata_change()); + refresh_numel(); + refresh_contiguous(); + } + + private: + QuantizerPtr quantizer_; + + const char* tensorimpl_type_name() const override; + + /** + * Copy the tensor metadata fields (e.g. sizes / strides / storage pointer / storage_offset) + * from one TensorImpl to another TensorImpl. + * + * For usage of `version_counter` and `allow_tensor_metadata_change`, see NOTE [ TensorImpl Shallow-Copying ]. + */ + static void copy_tensor_metadata( + const QTensorImpl* src_q_impl, + QTensorImpl* dest_q_impl, + const c10::VariableVersion& version_counter, + bool allow_tensor_metadata_change) { + TensorImpl::copy_tensor_metadata(src_q_impl, dest_q_impl, version_counter, allow_tensor_metadata_change); + + // OpaqueTensorImpl-specific fields. + dest_q_impl->quantizer_ = src_q_impl->quantizer_; + } +}; + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/quantized/Quantizer.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/quantized/Quantizer.h new file mode 100644 index 0000000000000000000000000000000000000000..709e073d064b4d715c973172f778cb9b37d90515 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/quantized/Quantizer.h @@ -0,0 +1,279 @@ +#pragma once + +#include +#include +#include +#include +#include +#include +#include + +#include +#include + +#include + +#include +#include +#include + +namespace at { + +/** + * UnknownQuantizer is a placeholder quantizer for functions that implement + * quantization in a two step process. First a tensor is allocated but with + * unknown quantizer, and then the quantization kernel decides what the final + * quantizer will be. + */ +struct TORCH_API UnknownQuantizer : public Quantizer { + explicit UnknownQuantizer(ScalarType scalar_type) + : Quantizer(scalar_type) {} + + Tensor quantize(const Tensor& tensor) override; + Tensor dequantize(const Tensor& qtensor) override; + Tensor& dequantize_out(Tensor& rtensor, const Tensor& qtensor) override; + QScheme qscheme() const override; + bool equalTo(QuantizerPtr other) const override; +}; + +/** + * UniformQuantizer is the parent class for all uniform quantizers. + * These quantization scheme will map float value uniformly to + * the quantized value. For example, affine quantizer is + * the most commonly used scheme in this category. + */ +struct TORCH_API UniformQuantizer : public Quantizer { + explicit UniformQuantizer(ScalarType scalar_type) : Quantizer(scalar_type) {} +}; + +/** + * NonUniformQuantizer is the parent class for all non-uniform quantizers. + * These quantization scheme may map float value non-uniformly to the quantized + * value. K-means quantization is a representative example in this category. + */ +struct TORCH_API NonUniformQuantizer : public Quantizer { + explicit NonUniformQuantizer(ScalarType scalar_type) : Quantizer(scalar_type) {} +}; + +// There is also StochasticQuantizer which is uniform but not affine + +/** + * AffineQuantizer uses affine transformation to do quantization. + * + * For quantize: + * Y = clamp(round(X / scale + zero_point), min, max) + * For dequantize: + * X = (Y - zero_point) * scale + */ +struct TORCH_API AffineQuantizer : public UniformQuantizer { + explicit AffineQuantizer(ScalarType scalar_type) : UniformQuantizer(scalar_type) {} +}; + +// Note that we will not have Symmetric Quantizer in backend to reduce +// complications in quantized kernel implementation. + +/** + * PerTensorAffineQuantizer stores a scale and a zero_point, which is used for + * all the values in the Tensor. + */ +struct TORCH_API PerTensorAffineQuantizer : public AffineQuantizer { + explicit PerTensorAffineQuantizer(ScalarType scalar_type, double scale, int64_t zero_point) + : AffineQuantizer(scalar_type), + scale_(scale), + zero_point_(zero_point) {} + + Tensor quantize(const Tensor& tensor) override; + Tensor dequantize(const Tensor& qtensor) override; + Tensor& dequantize_out(Tensor& rtensor, const Tensor& qtensor) override; + + QScheme qscheme() const override { + return kPerTensorAffine; + } + + double scale() const { + return scale_; + } + + int64_t zero_point() const { + return zero_point_; + } + + bool equalTo(QuantizerPtr other) const override { + if (!other.get() || other->qscheme() != kPerTensorAffine) { + return false; + } + auto* other_per_tensor_affine = + static_cast(other.get()); + return scalar_type() == other_per_tensor_affine->scalar_type() && + scale() == other_per_tensor_affine->scale() && + zero_point() == other_per_tensor_affine->zero_point(); + } + + private: + const double scale_; + // We use int64_t for consistency with Python + const int64_t zero_point_; +}; + +/** + * PerChannelAffineQuantizer is the same as PerTensorAffineQuantizer + * except that we have an independent scale and zero_point parameter + * for each channel. + * + * Also note that per channel quantization is mostly applied to output channels + * of weights since per-input channel of weight quantization or per-channel + * quantization for activations can't be efficiently supported in most of + * processors since it requires each multiplication result within a single + * dot-product to have a different scale. + */ +struct TORCH_API PerChannelAffineQuantizer : public AffineQuantizer { + explicit PerChannelAffineQuantizer( + ScalarType scalar_type, + Tensor scales, + Tensor zero_points, + int64_t axis) + : AffineQuantizer(scalar_type), + scales_(std::move(scales)), + zero_points_(std::move(zero_points)), + axis_(axis) {} + + QScheme qscheme() const override { + return kPerChannelAffine; + } + + Tensor scales() const { + return scales_; + } + + Tensor zero_points() const { + return zero_points_; + } + + int64_t axis() const { + return axis_; + } + + Tensor quantize(const Tensor& tensor) override; + Tensor dequantize(const Tensor& qtensor) override; + Tensor& dequantize_out(Tensor& rtensor, const Tensor& qtensor) override; + + bool equalTo(QuantizerPtr other) const override { + if (!other.get() || other->qscheme() != kPerChannelAffine) { + return false; + } + auto* other_per_channel_affine = + static_cast(other.get()); + return scalar_type() == other_per_channel_affine->scalar_type() && + scales().equal(other_per_channel_affine->scales()) && + zero_points().equal(other_per_channel_affine->zero_points()) && + axis() == other_per_channel_affine->axis(); + } + + protected: + Tensor scales_; + Tensor zero_points_; + const int64_t axis_; +}; + +/** + * PerChannelAffineFloatQParamsQuantizer is the same as PerChannelAffineQuantizer + * except that it expects both scale and zero point to be floating point values. + * + * This quantizer uses the kPerChannelAffineFloatQParams qscheme which is a variant of + * kPerChannelAffine. + * + * The quantize equation in this case looks like - + * Xq = (Xf - zero_point) * inv_scale, where inv_scale = 1.0/scale + * + * Note: Usage of floating point zero point is useful in cases where 0 doesn't need to + * be exactly represented in the quantized space. We can get additional precision by + * using floating point values for zero point. + */ +struct TORCH_API PerChannelAffineFloatQParamsQuantizer : public PerChannelAffineQuantizer { + explicit PerChannelAffineFloatQParamsQuantizer( + ScalarType scalar_type, + Tensor scales, + Tensor zero_points, + int64_t axis) + : PerChannelAffineQuantizer(scalar_type, + scales, + zero_points, + axis) {} + + QScheme qscheme() const override { + return kPerChannelAffineFloatQParams; + } + + Tensor quantize(const Tensor& tensor) override; + Tensor dequantize(const Tensor& qtensor) override; + Tensor& dequantize_out(Tensor& rtensor, const Tensor& qtensor) override; + + bool equalTo(QuantizerPtr other) const override { + if (!other.get() || other->qscheme() != kPerChannelAffineFloatQParams) { + return false; + } + auto* other_per_channel_float_qparams = + static_cast(other.get()); + return scalar_type() == other_per_channel_float_qparams->scalar_type() && + scales().equal(other_per_channel_float_qparams->scales()) && + zero_points().equal(other_per_channel_float_qparams->zero_points()) && + axis() == other_per_channel_float_qparams->axis(); + } +}; + +// This is an internal utility function for getting at the QTensorImpl, +// You should only use this for writing low level +// setters/getters for QTensorImpl fields; otherwise, you should use +// the low level setters/getters that were implemented using this. +// This may be called repeatedly, so make sure it's pretty cheap. +TORCH_API QTensorImpl* get_qtensorimpl(const TensorBase& self); + +// double and int64_t are because of the native function API, we only have these +// argument types right now in native functions +TORCH_API QuantizerPtr +make_per_tensor_affine_quantizer( + double scale, int64_t zero_point, ScalarType scalar_type); + +TORCH_API QuantizerPtr make_per_channel_affine_quantizer( + const Tensor& scales, + const Tensor& zero_points, + int64_t axis, + ScalarType scalar_type); + +TORCH_API QuantizerPtr make_unknown_quantizer(ScalarType scalar_type); + +// Create a Quantized Tensor given arguments for normal Tensor and a quantizer +TORCH_API Tensor new_qtensor( + IntArrayRef sizes, + const TensorOptions& options, + QuantizerPtr quantizer); + +TORCH_API void set_quantizer_(const Tensor& self, ConstQuantizerPtr quantizer); + +TORCH_API Tensor from_blob_quantized_per_tensor_affine( + void* data, + IntArrayRef sizes, + IntArrayRef strides, + std::function deleter, + const float scale, + const int64_t zeroPoint, + const TensorOptions& options); + +TORCH_API Tensor from_blob_quantized_per_tensor_affine( + void* data, + IntArrayRef sizes, + std::function deleter, + const float scale, + const int64_t zeroPoint, + const TensorOptions& options); + +TORCH_API Tensor from_blob_quantized_per_channel_affine( + void* data, + IntArrayRef sizes, + std::function deleter, + const Tensor& scales, + const Tensor& zero_points, + const int64_t axis, + const TensorOptions& options); + +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/CachingHostAllocator.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/CachingHostAllocator.h new file mode 100644 index 0000000000000000000000000000000000000000..5a4afc0dc7486ac43c5191ec9e244dfef4a3b3a4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/CachingHostAllocator.h @@ -0,0 +1,23 @@ +#pragma once + +#include +#include +#include +#include + +namespace at::xpu { + +TORCH_XPU_API c10::Allocator* getCachingHostAllocator(); + +TORCH_XPU_API bool CachingHostAllocator_recordEvent( + void* ptr, + void* ctx, + c10::xpu::XPUStream stream); + +TORCH_XPU_API void CachingHostAllocator_emptyCache(); + +inline TORCH_XPU_API at::DataPtr HostAlloc(size_t size) { + return getCachingHostAllocator()->allocate(size); +} + +} // namespace at::xpu diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/PinnedMemoryAllocator.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/PinnedMemoryAllocator.h new file mode 100644 index 0000000000000000000000000000000000000000..4a209c95524917cbb0cfd165aa061726dde03839 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/PinnedMemoryAllocator.h @@ -0,0 +1,11 @@ +#pragma once + +#include +#include + +namespace at::xpu { + +inline TORCH_XPU_API at::Allocator* getPinnedMemoryAllocator() { + return getCachingHostAllocator(); +} +} // namespace at::xpu diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUContext.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUContext.h new file mode 100644 index 0000000000000000000000000000000000000000..fb8fbe9c0aa4221a3384d6eb7c457d8dad54d0f0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUContext.h @@ -0,0 +1,20 @@ +#pragma once + +#include +#include +#include + +namespace at::xpu { + +// XPU is available if we compiled with XPU. +inline bool is_available() { + return c10::xpu::device_count() > 0; +} + +TORCH_XPU_API DeviceProp* getCurrentDeviceProperties(); + +TORCH_XPU_API DeviceProp* getDeviceProperties(DeviceIndex device); + +TORCH_XPU_API int32_t getGlobalIdxFromDevice(DeviceIndex device); + +} // namespace at::xpu diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUDevice.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUDevice.h new file mode 100644 index 0000000000000000000000000000000000000000..d4ab7187513c15ad0bbc8cff610ec3831f3a51fe --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUDevice.h @@ -0,0 +1,13 @@ +#pragma once + +#include +#include + +namespace at::xpu { + +inline Device getDeviceFromPtr(void* ptr) { + auto device = c10::xpu::get_device_idx_from_pointer(ptr); + return {c10::DeviceType::XPU, device}; +} + +} // namespace at::xpu diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUEvent.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUEvent.h new file mode 100644 index 0000000000000000000000000000000000000000..ededd6ebf4f15b0c132743b0125cfd0c7c95e421 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUEvent.h @@ -0,0 +1,191 @@ +#pragma once +#include + +#include + +namespace at::xpu { + +/* + * XPUEvent are movable not copyable wrappers around SYCL event. XPUEvent are + * constructed lazily when first recorded. It has a device, and this device is + * acquired from the first recording stream. Later streams that record the event + * must match the same device. + * + * Currently, XPUEvent does NOT support to export an inter-process event from + * another process via inter-process comunication(IPC). So it means that + * inter-process communication for event handles between different processes is + * not available. This could impact some applications that rely on cross-process + * synchronization and communication. + */ +struct TORCH_XPU_API XPUEvent { + // Constructors + XPUEvent(bool enable_timing = false) noexcept + : enable_timing_{enable_timing} {} + + ~XPUEvent() { + if (isCreated()) { + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_deletion( + at::kXPU, reinterpret_cast(event_.get())); + } + } + } + + XPUEvent(const XPUEvent&) = delete; + XPUEvent& operator=(const XPUEvent&) = delete; + + XPUEvent(XPUEvent&& other) = default; + XPUEvent& operator=(XPUEvent&& other) = default; + + operator sycl::event&() const { + return event(); + } + + std::optional device() const { + if (isCreated()) { + return at::Device(at::kXPU, device_index_); + } else { + return std::nullopt; + } + } + + inline bool isCreated() const { + return (event_.get() != nullptr); + } + + DeviceIndex device_index() const { + return device_index_; + } + + sycl::event& event() const { + return *event_; + } + + bool query() const { + using namespace sycl::info; + if (!isCreated()) { + return true; + } + + return event().get_info() == + event_command_status::complete; + } + + void record() { + record(getCurrentXPUStream()); + } + + void recordOnce(const XPUStream& stream) { + if (!isCreated()) { + record(stream); + } + } + + void record(const XPUStream& stream) { + if (!isCreated()) { + device_index_ = stream.device_index(); + assignEvent(stream.queue()); + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_creation( + at::kXPU, reinterpret_cast(event_.get())); + } + } else { + TORCH_CHECK( + device_index_ == stream.device_index(), + "Event device ", + device_index_, + " does not match recording stream's device ", + stream.device_index(), + "."); + reassignEvent(stream.queue()); + } + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_record( + at::kXPU, + reinterpret_cast(event_.get()), + reinterpret_cast(&stream.queue())); + } + } + + void block(const XPUStream& stream) { + if (isCreated()) { + std::vector event_list{event()}; + // Make this stream wait until event_ is completed. + stream.queue().ext_oneapi_submit_barrier(event_list); + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_wait( + at::kXPU, + reinterpret_cast(event_.get()), + reinterpret_cast(&stream.queue())); + } + } + } + + double elapsed_time(const XPUEvent& other) const { + TORCH_CHECK( + isCreated() && other.isCreated(), + "Both events must be recorded before calculating elapsed time."); + TORCH_CHECK( + query() && other.query(), + "Both events must be completed before calculating elapsed time."); + TORCH_CHECK( + enable_timing_ && other.enable_timing_, + "Both events must be created with argument 'enable_timing=True'."); + +#if SYCL_COMPILER_VERSION < 20250000 + TORCH_CHECK_NOT_IMPLEMENTED( + false, + "elapsed_time of XPUEvent requires PyTorch to be built with SYCL compiler version 2025.0.0 or newer."); +#endif + + using namespace sycl::info::event_profiling; + // Block until both of the recorded events are completed. + uint64_t end_time_ns = other.event().get_profiling_info(); + uint64_t start_time_ns = event().get_profiling_info(); + // Return the eplased time in milliseconds. + return 1e-6 * + (static_cast(end_time_ns) - static_cast(start_time_ns)); + } + + void synchronize() const { + if (isCreated()) { + const c10::impl::PyInterpreter* interp = c10::impl::GPUTrace::get_trace(); + if (C10_UNLIKELY(interp)) { + (*interp)->trace_gpu_event_synchronization( + at::kXPU, reinterpret_cast(event_.get())); + } + event().wait_and_throw(); + } + } + + private: + void assignEvent(sycl::queue& queue) { +#if SYCL_COMPILER_VERSION >= 20250000 + if (enable_timing_) { + event_ = std::make_unique( + sycl::ext::oneapi::experimental::submit_profiling_tag(queue)); + } else { + event_ = std::make_unique(queue.ext_oneapi_submit_barrier()); + } +#else + event_ = std::make_unique(queue.ext_oneapi_submit_barrier()); +#endif + } + + void reassignEvent(sycl::queue& queue) { + event_.reset(); + assignEvent(queue); + } + + bool enable_timing_ = false; + DeviceIndex device_index_ = -1; + // Only need to track the last event, as events in an in-order queue are + // executed sequentially. + std::unique_ptr event_; +}; + +} // namespace at::xpu diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUGeneratorImpl.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUGeneratorImpl.h new file mode 100644 index 0000000000000000000000000000000000000000..a1f264382a366d70410adc7c98280694b63d6ba5 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/XPUGeneratorImpl.h @@ -0,0 +1,39 @@ +#pragma once + +#include + +namespace at { + +struct TORCH_XPU_API XPUGeneratorImpl : public GeneratorImpl { + // Constructors + XPUGeneratorImpl(DeviceIndex device_index = -1); + ~XPUGeneratorImpl() override = default; + + // XPUGeneratorImpl methods + std::shared_ptr clone() const; + void set_current_seed(uint64_t seed) override; + void set_offset(uint64_t offset) override; + uint64_t get_offset() const override; + uint64_t current_seed() const override; + uint64_t seed() override; + void set_state(const c10::TensorImpl& new_state) override; + c10::intrusive_ptr get_state() const override; + void set_philox_offset_per_thread(uint64_t offset); + uint64_t philox_offset_per_thread() const; + std::pair philox_engine_inputs(uint64_t increment); + static c10::DeviceType device_type(); + + private: + XPUGeneratorImpl* clone_impl() const override; + uint64_t seed_ = default_rng_seed_val; + uint64_t philox_offset_per_thread_ = 0; +}; + +namespace xpu::detail { + +TORCH_XPU_API const Generator& getDefaultXPUGenerator(DeviceIndex device = -1); + +TORCH_XPU_API Generator createXPUGenerator(DeviceIndex device = -1); + +} // namespace xpu::detail +} // namespace at diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/detail/XPUHooks.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/detail/XPUHooks.h new file mode 100644 index 0000000000000000000000000000000000000000..1103b5b945662c963f8fa7d373df2ede4c25f74d --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/ATen/xpu/detail/XPUHooks.h @@ -0,0 +1,33 @@ +#pragma once + +#include + +namespace at::xpu::detail { + +// The real implementation of XPUHooksInterface +struct XPUHooks : public at::XPUHooksInterface { + XPUHooks(at::XPUHooksArgs) {} + void init() const override; + bool hasXPU() const override; + std::string showConfig() const override; + int32_t getGlobalIdxFromDevice(const at::Device& device) const override; + const Generator& getDefaultGenerator( + DeviceIndex device_index = -1) const override; + Generator getNewGenerator(DeviceIndex device_index = -1) const override; + Device getDeviceFromPtr(void* data) const override; + c10::DeviceIndex getNumGPUs() const override; + DeviceIndex current_device() const override; + void deviceSynchronize(DeviceIndex device_index) const override; + Allocator* getPinnedMemoryAllocator() const override; + + bool isBuilt() const override { + return true; + } + bool isAvailable() const override; + bool isPinnedPtr(const void* data) const override; + bool hasPrimaryContext(DeviceIndex device_index) const override; + DeviceIndex deviceCount() const override; + DeviceIndex getCurrentDevice() const override; +}; + +} // namespace at::xpu::detail diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/AbstractConfig.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/AbstractConfig.h new file mode 100644 index 0000000000000000000000000000000000000000..9a7d66def89369b670498a74eae951c34fe6ef67 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/AbstractConfig.h @@ -0,0 +1,123 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include +#include +#include +#include +#include + +namespace libkineto { + +class AbstractConfig { + public: + AbstractConfig& operator=(const AbstractConfig&) = delete; + AbstractConfig(AbstractConfig&&) = delete; + AbstractConfig& operator=(AbstractConfig&&) = delete; + + virtual ~AbstractConfig() { + for (const auto& p : featureConfigs_) { + delete p.second; + } + } + + // Return a copy of the full derived class + virtual AbstractConfig* cloneDerived(AbstractConfig& parent) const = 0; + + // Returns true if successfully parsed the config string + bool parse(const std::string& conf); + + // Default setup for signal-triggered profiling + virtual void setSignalDefaults() { + for (auto& p : featureConfigs_) { + p.second->setSignalDefaults(); + } + } + + // Default setup for client-triggered profiling + virtual void setClientDefaults() { + for (auto& p : featureConfigs_) { + p.second->setClientDefaults(); + } + } + + // Time config was created / updated + std::chrono::time_point timestamp() const { + return timestamp_; + } + + // Source config string that this was parsed from + const std::string& source() const { + return source_; + } + + AbstractConfig& feature(std::string name) const { + const auto& pos = featureConfigs_.find(name); + return *pos->second; + } + + // Transfers ownership of cfg arg + void addFeature(const std::string& name, AbstractConfig* cfg) { + featureConfigs_[name] = cfg; + } + + protected: + AbstractConfig() {} + AbstractConfig(const AbstractConfig& other) = default; + + // Return true if the option was recognized and successfully parsed. + // Throw std::invalid_argument if val is invalid. + virtual bool handleOption(const std::string& name, std::string& val); + + // Perform post-validation checks, typically conditons involving + // multiple options. + // Throw std::invalid_argument if automatic correction can not be made. + // + // @param fallbackProfileStartTime Specify a fallback profile start timestamp + // in case it was never specified by the client + virtual void validate( + const std::chrono::time_point& + fallbackProfileStartTime) = 0; + + // TODO: Separate out each profiler type into features? + virtual void printActivityProfilerConfig(std::ostream& s) const; + virtual void setActivityDependentConfig(); + + // Helpers for use in handleOption + // Split a string by delimiter and remove external white space + std::vector splitAndTrim(const std::string& s, char delim) const; + // Lowercase for case-insensitive comparisons + std::string toLower(std::string& s) const; + // Does string end with suffix + bool endsWith(const std::string& s, const std::string& suffix) const; + // Conversions + int64_t toIntRange(const std::string& val, int64_t min, int64_t max) const; + int32_t toInt32(const std::string& val) const; + int64_t toInt64(const std::string& val) const; + bool toBool(std::string& val) const; + + void cloneFeaturesInto(AbstractConfig& cfg) const { + for (const auto& feature : featureConfigs_) { + cfg.featureConfigs_[feature.first] = feature.second->cloneDerived(cfg); + } + } + + private: + // Time config was created / updated + std::chrono::time_point timestamp_{}; + + // Original configuration string, used for comparison + std::string source_{""}; + + // Configuration objects for optional features + std::map featureConfigs_{}; +}; + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ActivityProfilerInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ActivityProfilerInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..a9af8198b455967bdc900e8019617a45f107fa07 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ActivityProfilerInterface.h @@ -0,0 +1,108 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include +#include +#include +#include + +#include "ActivityTraceInterface.h" +#include "ActivityType.h" +#include "IActivityProfiler.h" + +namespace libkineto { + +class ActivityProfilerController; +struct CpuTraceBuffer; +class Config; + +class ActivityProfilerInterface { + public: + virtual ~ActivityProfilerInterface() {} + + virtual void init() {} + virtual bool isInitialized() { + return false; + } + virtual bool isActive() { + return false; + } + + // *** Asynchronous API *** + // Instead of starting and stopping the trace manually, provide a start time + // and duration and / or iteration stop criterion. + // Tracing terminates when either condition is met. + virtual void scheduleTrace(const std::string& configStr) {} + + // *** Synchronous API *** + // These must be called in order: + // prepareTrace -> startTrace -> stopTrace. + + // Many tracing structures are lazily initialized during trace collection, + // with potentially high overhead. + // Call prepareTrace to enable tracing, then run the region to trace + // at least once (and ideally run the same code that is to be traced) to + // allow tracing structures to be initialized. + virtual void prepareTrace( + const std::set& activityTypes, + const std::string& configStr = "") {} + + // Toggle GPU tracing as a trace is running to omit certain parts of a graph + virtual void toggleCollectionDynamic(const bool enable) {} + + // Start recording, potentially reusing any buffers allocated since + // prepareTrace was called. + virtual void startTrace() {} + + // Stop and process trace, producing an in-memory list of trace records. + // The processing will be done synchronously (using the calling thread.) + virtual std::unique_ptr stopTrace() { + return nullptr; + } + + // Re-evaluate internal state to allow for triggering operations based + // on number of iteration. each implicitly increments the iteration count + virtual void step() {} + + // *** TraceActivity API *** + // FIXME: Pass activityProfiler interface into clientInterface? + virtual void pushCorrelationId(uint64_t id) {} + virtual void popCorrelationId() {} + virtual void transferCpuTrace(std::unique_ptr traceBuffer) {} + + // Correlation ids for user defined spans + virtual void pushUserCorrelationId(uint64_t) {} + virtual void popUserCorrelationId() {} + + // Saves information for the current thread to be used in profiler output + // Client must record any new kernel thread where the activity has occured. + virtual void recordThreadInfo() {} + + // Record trace metadata, currently supporting only string key and values, + // values with the same key are overwritten + virtual void addMetadata( + const std::string& key, + const std::string& value) = 0; + + // Add a child activity profiler, this enables frameworks in the application + // to enable custom framework events. + virtual void addChildActivityProfiler( + std::unique_ptr profiler) {} + + // Log Invariant Violation to factories enabled. This helps record + // instances when the profiler behaves unexpectedly. + virtual void logInvariantViolation( + const std::string&, + const std::string&, + const std::string&, + const std::string& = "") {} +}; + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ActivityTraceInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ActivityTraceInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..ceae7ca61a527ee7a5477011dcbb65b1bb551b41 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ActivityTraceInterface.h @@ -0,0 +1,28 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include +#include +#include + +namespace libkineto { + +struct ITraceActivity; + +class ActivityTraceInterface { + public: + virtual ~ActivityTraceInterface() {} + virtual const std::vector* activities() { + return nullptr; + } + virtual void save(const std::string& path) {} +}; + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ActivityType.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ActivityType.h new file mode 100644 index 0000000000000000000000000000000000000000..84887c0b58c2ceea1d588a217623a468b50a267c --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ActivityType.h @@ -0,0 +1,65 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include +#include +#include + +namespace libkineto { + +// Note : All activity types are not enabled by default. Please add them +// at correct position in the enum +enum class ActivityType { + // Activity types enabled by default + CPU_OP = 0, // cpu side ops + USER_ANNOTATION, + GPU_USER_ANNOTATION, + GPU_MEMCPY, + GPU_MEMSET, + CONCURRENT_KERNEL, // on-device kernels + EXTERNAL_CORRELATION, + CUDA_RUNTIME, // host side cuda runtime events + CUDA_DRIVER, // host side cuda driver events + CPU_INSTANT_EVENT, // host side point-like events + PYTHON_FUNCTION, + OVERHEAD, // CUPTI induced overhead events sampled from its overhead API. + MTIA_RUNTIME, // host side MTIA runtime events + MTIA_CCP_EVENTS, // MTIA ondevice CCP events + CUDA_SYNC, // synchronization events between runtime and kernels + + // Optional Activity types + GLOW_RUNTIME, // host side glow runtime events + CUDA_PROFILER_RANGE, // CUPTI Profiler range for performance metrics + HPU_OP, // HPU host side runtime event + XPU_RUNTIME, // host side xpu runtime events + COLLECTIVE_COMM, // collective communication + MTIA_WORKLOADD, // MTIA workloadd events + + // PRIVATEUSE1 Activity types are used for custom backends. + // The corresponding device type is `DeviceType::PrivateUse1` in PyTorch. + PRIVATEUSE1_RUNTIME, // host side privateUse1 runtime events + PRIVATEUSE1_DRIVER, // host side privateUse1 driver events + + ENUM_COUNT, // This is to add buffer and not used for any profiling logic. Add + // your new type before it. + OPTIONAL_ACTIVITY_TYPE_START = GLOW_RUNTIME, +}; + +const char* toString(ActivityType t); +ActivityType toActivityType(const std::string& str); + +// Return an array of all activity types except COUNT +constexpr int activityTypeCount = (int)ActivityType::ENUM_COUNT; +constexpr int defaultActivityTypeCount = + (int)ActivityType::OPTIONAL_ACTIVITY_TYPE_START; +const std::array activityTypes(); +const std::array defaultActivityTypes(); + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ClientInterface.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ClientInterface.h new file mode 100644 index 0000000000000000000000000000000000000000..950c3be69004297d85b33a5d3fda36d009b32d6e --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ClientInterface.h @@ -0,0 +1,22 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +namespace libkineto { + +class ClientInterface { + public: + virtual ~ClientInterface() {} + virtual void init() = 0; + virtual void prepare(bool, bool, bool, bool, bool) = 0; + virtual void start() = 0; + virtual void stop() = 0; +}; + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/Config.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/Config.h new file mode 100644 index 0000000000000000000000000000000000000000..eb3d0812bf98b61239d47f255234a0d73c86229f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/Config.h @@ -0,0 +1,516 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include "AbstractConfig.h" +#include "ActivityType.h" + +#include +#include +#include +#include +#include +#include + +namespace libkineto { + +class Config : public AbstractConfig { + public: + Config(); + Config& operator=(const Config&) = delete; + Config(Config&&) = delete; + Config& operator=(Config&&) = delete; + + // Return a full copy including feature config object + std::unique_ptr clone() const { + auto cfg = std::unique_ptr(new Config(*this)); + cloneFeaturesInto(*cfg); + return cfg; + } + + bool handleOption(const std::string& name, std::string& val) override; + + void setClientDefaults() override; + + // Log events to this file + const std::string& eventLogFile() const { + return eventLogFile_; + } + + bool activityProfilerEnabled() const { + return activityProfilerEnabled_ || + activitiesOnDemandTimestamp_.time_since_epoch().count() > 0; + } + + // Log activitiy trace to this file + const std::string& activitiesLogFile() const { + return activitiesLogFile_; + } + + // Log activitiy trace to this url + const std::string& activitiesLogUrl() const { + return activitiesLogUrl_; + } + + void setActivitiesLogUrl(const std::string& url) { + activitiesLogUrl_ = url; + } + + bool activitiesLogToMemory() const { + return activitiesLogToMemory_; + } + + bool eventProfilerEnabled() const { + return !eventNames_.empty() || !metricNames_.empty(); + } + + // Is profiling enabled for the given device? + bool eventProfilerEnabledForDevice(uint32_t dev) const { + return 0 != (eventProfilerDeviceMask_ & (1 << dev)); + } + + // Take a sample (read hardware counters) at this frequency. + // This controls how often counters are read - if all counters cannot + // be collected simultaneously then multiple samples are needed to + // collect all requested counters - see multiplex period. + std::chrono::milliseconds samplePeriod() const { + return samplePeriod_; + } + + void setSamplePeriod(std::chrono::milliseconds period) { + samplePeriod_ = period; + } + + // When all requested counters cannot be collected simultaneously, + // counters will be multiplexed at this frequency. + // Multiplexing can have a large performance impact if done frequently. + // To avoid a perf impact, keep this at 1s or above. + std::chrono::milliseconds multiplexPeriod() const { + return multiplexPeriod_; + } + + void setMultiplexPeriod(std::chrono::milliseconds period) { + multiplexPeriod_ = period; + } + + // Report counters at this frequency. Note that several samples can + // be reported each time, see samplesPerReport. + std::chrono::milliseconds reportPeriod() const { + return reportPeriod_; + } + + void setReportPeriod(std::chrono::milliseconds msecs); + + // Number of samples dispatched each report period. + // Must be in the range [1, report period / sample period]. + // In other words, aggregation is supported but not interpolation. + int samplesPerReport() const { + return samplesPerReport_; + } + + void setSamplesPerReport(int count) { + samplesPerReport_ = count; + } + + // The names of events to collect + const std::set& eventNames() const { + return eventNames_; + } + + // Add additional events to be profiled + void addEvents(const std::set& names) { + eventNames_.insert(names.begin(), names.end()); + } + + // The names of metrics to collect + const std::set& metricNames() const { + return metricNames_; + } + + // Add additional metrics to be profiled + void addMetrics(const std::set& names) { + metricNames_.insert(names.begin(), names.end()); + } + + const std::vector& percentiles() const { + return eventReportPercentiles_; + } + + // Profile for this long, then revert to base config + std::chrono::seconds eventProfilerOnDemandDuration() const { + return eventProfilerOnDemandDuration_; + } + + void setEventProfilerOnDemandDuration(std::chrono::seconds duration) { + eventProfilerOnDemandDuration_ = duration; + } + + // Too many event profilers on a single system can overload the driver. + // At some point, latencies shoot through the roof and collection of samples + // becomes impossible. To avoid this situation we have a limit of profilers + // per GPU. + // NOTE: Communication with a daemon is needed for this feature. + // Library must be built with an active DaemonConfigLoader. + int maxEventProfilersPerGpu() const { + return eventProfilerMaxInstancesPerGpu_; + } + + // On Cuda11 we've seen occasional hangs when reprogramming counters + // Monitor profiling threads and report when a thread is not responding + // for a given number of seconds. + // A period of 0 means disable. + std::chrono::seconds eventProfilerHeartbeatMonitorPeriod() const { + return eventProfilerHeartbeatMonitorPeriod_; + } + + // The types of activities selected in the configuration file + const std::set& selectedActivityTypes() const { + return selectedActivityTypes_; + } + + // Set the types of activities to be traced + bool perThreadBufferEnabled() const { + return perThreadBufferEnabled_; + } + + void setSelectedActivityTypes(const std::set& types) { + selectedActivityTypes_ = types; + } + + bool isReportInputShapesEnabled() const { + return enableReportInputShapes_; + } + + bool isProfileMemoryEnabled() const { + return enableProfileMemory_; + } + + bool isWithStackEnabled() const { + return enableWithStack_; + } + + bool isWithFlopsEnabled() const { + return enableWithFlops_; + } + + bool isWithModulesEnabled() const { + return enableWithModules_; + } + + // Trace for this long + std::chrono::milliseconds activitiesDuration() const { + return activitiesDuration_; + } + + // Trace for this many iterations, determined by external API + int activitiesRunIterations() const { + return activitiesRunIterations_; + } + + int activitiesMaxGpuBufferSize() const { + return activitiesMaxGpuBufferSize_; + } + + std::chrono::seconds activitiesWarmupDuration() const { + return activitiesWarmupDuration_; + } + + int activitiesWarmupIterations() const { + return activitiesWarmupIterations_; + } + + // Show CUDA Synchronization Stream Wait Events + bool activitiesCudaSyncWaitEvents() const { + return activitiesCudaSyncWaitEvents_; + } + + void setActivitiesCudaSyncWaitEvents(bool enable) { + activitiesCudaSyncWaitEvents_ = enable; + } + + // Timestamp at which the profiling to start, requested by the user. + const std::chrono::time_point requestTimestamp() + const { + if (profileStartTime_.time_since_epoch().count()) { + return profileStartTime_; + } + // If no one requested timestamp, return 0. + if (requestTimestamp_.time_since_epoch().count() == 0) { + return requestTimestamp_; + } + + // TODO(T94634890): Deprecate requestTimestamp + return requestTimestamp_ + maxRequestAge() + activitiesWarmupDuration(); + } + + bool hasProfileStartTime() const { + return requestTimestamp_.time_since_epoch().count() > 0 || + profileStartTime_.time_since_epoch().count() > 0; + } + + int profileStartIteration() const { + return profileStartIteration_; + } + + bool hasProfileStartIteration() const { + return profileStartIteration_ >= 0 && activitiesRunIterations_ > 0; + } + + void setProfileStartIteration(int iter) { + profileStartIteration_ = iter; + } + + int profileStartIterationRoundUp() const { + return profileStartIterationRoundUp_; + } + + // calculate the start iteration accounting for warmup + int startIterationIncludingWarmup() const { + if (!hasProfileStartIteration()) { + return -1; + } + return profileStartIteration_ - activitiesWarmupIterations_; + } + + const std::chrono::seconds maxRequestAge() const; + + // All VLOG* macros will log if the verbose log level is >= + // the verbosity specified for the verbose log message. + // Default value is -1, so messages with log level 0 will log by default. + int verboseLogLevel() const { + return verboseLogLevel_; + } + + // Modules for which verbose logging is enabled. + // If empty, logging is enabled for all modules. + const std::vector& verboseLogModules() const { + return verboseLogModules_; + } + + bool sigUsr2Enabled() const { + return enableSigUsr2_; + } + + bool ipcFabricEnabled() const { + return enableIpcFabric_; + } + + std::chrono::seconds onDemandConfigUpdateIntervalSecs() const { + return onDemandConfigUpdateIntervalSecs_; + } + + static std::chrono::milliseconds alignUp( + std::chrono::milliseconds duration, + std::chrono::milliseconds alignment) { + duration += alignment; + return duration - (duration % alignment); + } + + std::chrono::time_point + eventProfilerOnDemandStartTime() const { + return eventProfilerOnDemandTimestamp_; + } + + std::chrono::time_point + eventProfilerOnDemandEndTime() const { + return eventProfilerOnDemandTimestamp_ + eventProfilerOnDemandDuration_; + } + + std::chrono::time_point + activityProfilerRequestReceivedTime() const { + return activitiesOnDemandTimestamp_; + } + + static constexpr std::chrono::milliseconds kControllerIntervalMsecs{1000}; + + // Users may request and set trace id and group trace id. + const std::string& requestTraceID() const { + return requestTraceID_; + } + + void setRequestTraceID(const std::string& tid) { + requestTraceID_ = tid; + } + + const std::string& requestGroupTraceID() const { + return requestGroupTraceID_; + } + + void setRequestGroupTraceID(const std::string& gtid) { + requestGroupTraceID_ = gtid; + } + + size_t cuptiDeviceBufferSize() const { + return cuptiDeviceBufferSize_; + } + + size_t cuptiDeviceBufferPoolLimit() const { + return cuptiDeviceBufferPoolLimit_; + } + + void updateActivityProfilerRequestReceivedTime(); + + void printActivityProfilerConfig(std::ostream& s) const override; + void setActivityDependentConfig() override; + + void validate(const std::chrono::time_point& + fallbackProfileStartTime) override; + + static void addConfigFactory( + std::string name, + std::function factory); + + void print(std::ostream& s) const; + + // Config relies on some state with global static lifetime. If other + // threads are using the config, it's possible that the global state + // is destroyed before the threads stop. By hanging onto this handle, + // correct destruction order can be ensured. + static std::shared_ptr getStaticObjectsLifetimeHandle(); + + bool getTSCTimestampFlag() const { + return useTSCTimestamp_; + } + + void setTSCTimestampFlag(bool flag) { + useTSCTimestamp_ = flag; + } + + private: + explicit Config(const Config& other) = default; + + AbstractConfig* cloneDerived(AbstractConfig& parent) const override { + // Clone from AbstractConfig not supported + assert(false); + return nullptr; + } + + uint8_t createDeviceMask(const std::string& val); + + // Adds valid activity types from the user defined string list in the + // configuration file + void setActivityTypes(const std::vector& selected_activities); + + // Sets the default activity types to be traced + void selectDefaultActivityTypes() { + // If the user has not specified an activity list, add all types + for (ActivityType t : defaultActivityTypes()) { + selectedActivityTypes_.insert(t); + } + } + + int verboseLogLevel_; + std::vector verboseLogModules_; + + // Event profiler + // These settings are also supported in on-demand mode + std::chrono::milliseconds samplePeriod_; + std::chrono::milliseconds reportPeriod_; + int samplesPerReport_; + std::set eventNames_; + std::set metricNames_; + + // On-demand duration + std::chrono::seconds eventProfilerOnDemandDuration_; + // Last on-demand request + std::chrono::time_point + eventProfilerOnDemandTimestamp_; + + int eventProfilerMaxInstancesPerGpu_; + + // Monitor whether event profiler threads are stuck + // at this frequency + std::chrono::seconds eventProfilerHeartbeatMonitorPeriod_; + + // These settings can not be changed on-demand + std::string eventLogFile_; + std::vector eventReportPercentiles_ = {5, 25, 50, 75, 95}; + uint8_t eventProfilerDeviceMask_ = ~0; + std::chrono::milliseconds multiplexPeriod_; + + // Activity profiler + bool activityProfilerEnabled_; + + // Enable per-thread buffer + bool perThreadBufferEnabled_; + std::set selectedActivityTypes_; + + // The activity profiler settings are all on-demand + std::string activitiesLogFile_; + + std::string activitiesLogUrl_; + + // Log activities to memory buffer + bool activitiesLogToMemory_{false}; + + int activitiesMaxGpuBufferSize_; + std::chrono::seconds activitiesWarmupDuration_; + int activitiesWarmupIterations_; + bool activitiesCudaSyncWaitEvents_; + + // Enable Profiler Config Options + // Temporarily disable shape collection until we re-roll out the feature for + // on-demand cases + bool enableReportInputShapes_{false}; + bool enableProfileMemory_{false}; + bool enableWithStack_{false}; + bool enableWithFlops_{false}; + bool enableWithModules_{false}; + + // Profile for specified iterations and duration + std::chrono::milliseconds activitiesDuration_; + int activitiesRunIterations_; + + // Below are not used + // Use this net name for iteration count + std::string activitiesExternalAPIIterationsTarget_; + // Only profile nets that includes this in the name + std::vector activitiesExternalAPIFilter_; + // Only profile nets with at least this many operators + int activitiesExternalAPINetSizeThreshold_; + // Only profile nets with at least this many GPU operators + int activitiesExternalAPIGpuOpCountThreshold_; + // Last activity profiler request + std::chrono::time_point + activitiesOnDemandTimestamp_; + + // ActivityProfilers are triggered by either: + // Synchronized start timestamps + std::chrono::time_point profileStartTime_; + // Or start iterations. + int profileStartIteration_; + int profileStartIterationRoundUp_; + + // DEPRECATED + std::chrono::time_point requestTimestamp_; + + // Enable profiling via SIGUSR2 + bool enableSigUsr2_; + + // Enable IPC Fabric instead of thrift communication + bool enableIpcFabric_; + std::chrono::seconds onDemandConfigUpdateIntervalSecs_; + + // Logger Metadata + std::string requestTraceID_; + std::string requestGroupTraceID_; + + // CUPTI Device Buffer + size_t cuptiDeviceBufferSize_; + size_t cuptiDeviceBufferPoolLimit_; + + // CUPTI Timestamp Format + bool useTSCTimestamp_{true}; +}; + +constexpr char kUseDaemonEnvVar[] = "KINETO_USE_DAEMON"; + +bool isDaemonEnvVarSet(); + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/GenericTraceActivity.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/GenericTraceActivity.h new file mode 100644 index 0000000000000000000000000000000000000000..5d01342d54e7a52f2ebd462f81c5c70cde8d3469 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/GenericTraceActivity.h @@ -0,0 +1,154 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include +#include +#include +#include +#include +#include + +#include "ITraceActivity.h" +#include "ThreadUtil.h" +#include "TraceSpan.h" + +namespace libkineto { + +// Link type, used in GenericTraceActivity.flow.type +constexpr unsigned int kLinkFwdBwd = 1; +constexpr unsigned int kLinkAsyncCpuGpu = 2; + +// @lint-ignore-every CLANGTIDY +// cppcoreguidelines-non-private-member-variables-in-classes +// @lint-ignore-every CLANGTIDY cppcoreguidelines-pro-type-member-init +class GenericTraceActivity : public ITraceActivity { + public: + GenericTraceActivity() + : activityType(ActivityType::ENUM_COUNT), traceSpan_(nullptr) {} + + GenericTraceActivity( + const TraceSpan& trace, + ActivityType type, + const std::string& name) + : activityType(type), activityName(name), traceSpan_(&trace) {} + + int64_t deviceId() const override { + return device; + } + + int64_t resourceId() const override { + return resource; + } + + int32_t getThreadId() const override { + return threadId; + } + + int64_t timestamp() const override { + return startTime; + } + + int64_t duration() const override { + return endTime - startTime; + } + + int64_t correlationId() const override { + return id; + } + + ActivityType type() const override { + return activityType; + } + + const ITraceActivity* linkedActivity() const override { + return linked; + } + + int flowType() const override { + return flow.type; + } + + int64_t flowId() const override { + return flow.id; + } + + bool flowStart() const override { + return flow.start; + } + + const std::string name() const override { + return activityName; + } + + const TraceSpan* traceSpan() const override { + return traceSpan_; + } + + void log(ActivityLogger& logger) const override; + + // Encode client side metadata as a key/value + template + void addMetadata(const std::string& key, const ValType& value) { + metadataMap_.emplace(key, std::make_pair(fmt::format("{}", value), false)); + } + + void addMetadataQuoted(const std::string& key, const std::string& value) { + metadataMap_.emplace(key, std::make_pair(value, true)); + } + + const std::string getMetadataValue(const std::string& key) const override { + if (auto it = metadataMap_.find(key); it != metadataMap_.end()) { + return it->second.first; + } + return ""; + } + + const std::string metadataJson() const override { + std::stringstream json; + bool first = true; + for (const auto& [key, val] : metadataMap_) { + if (!first) { + json << ", "; + } + val.second ? json << fmt::format("\"{}\": \"{}\"", key, val.first) + : json << fmt::format("\"{}\": {}", key, val.first); + first = false; + } + return json.str(); + } + + virtual ~GenericTraceActivity() override {} + + int64_t startTime{0}; + int64_t endTime{0}; + int32_t id{0}; + int32_t device{0}; + int32_t resource{0}; + int32_t threadId{0}; + ActivityType activityType; + std::string activityName; + struct Flow { + Flow() : id(0), type(0), start(0) {} + // Ids must be unique within each type + uint32_t id : 27; + // Type will be used to connect flows between profilers, as + // well as look up flow information (name etc) + uint32_t type : 4; + uint32_t start : 1; + } flow; + const ITraceActivity* linked{nullptr}; + + private: + const TraceSpan* traceSpan_; + // Metadata map: { key: (value, quoted)} + std::unordered_map> metadataMap_; +}; + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/IActivityProfiler.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/IActivityProfiler.h new file mode 100644 index 0000000000000000000000000000000000000000..4c88594e28c1ae1472fa04e6f6f80e5357beccbd --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/IActivityProfiler.h @@ -0,0 +1,167 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include +#include +#include + +#include "Config.h" +#include "GenericTraceActivity.h" + +/* This file includes an abstract base class for an activity profiler + * that can be implemented by multiple tracing agents in the application. + * The high level Kineto profiler can co-ordinate start and end of tracing + * and combine together events from multiple such activity profilers. + */ + +namespace libkineto { + +struct CpuTraceBuffer; + +#ifdef _MSC_VER +// workaround for the predefined ERROR macro on Windows +#undef ERROR +#endif // _MSC_VER + +enum class TraceStatus { + READY, // Accepting trace requests + WARMUP, // Performing trace warmup + RECORDING, // Actively collecting activities + PROCESSING, // Recording is complete, preparing results + ERROR, // One or more errors (and possibly also warnings) occurred. + WARNING, // One or more warnings occurred. +}; + +/* DeviceInfo: + * Can be used to specify process name, sort order, PID and device label. + * The sort order is determined by the sortIndex field to handle ordering of + * processes and gpu rows in the trace viewer. + */ +struct DeviceInfo { + DeviceInfo( + int64_t id, + int64_t sortIndex, + const std::string& name, + const std::string& label) + : id(id), sortIndex(sortIndex), name(name), label(label) {} + int64_t id; // process id + int64_t sortIndex; // position in trace view + const std::string name; // process name + const std::string label; // device label +}; + +/* ResourceInfo: + * Can be used to specify resource inside device + */ +struct ResourceInfo { + ResourceInfo( + int64_t deviceId, + int64_t id, + int64_t sortIndex, + const std::string& name) + : id(id), sortIndex(sortIndex), deviceId(deviceId), name(name) {} + int64_t id; // resource id + int64_t sortIndex; // position in trace view + int64_t deviceId; // id of device which owns this resource (specified in + // DeviceInfo.id) + const std::string name; // resource name +}; + +using getLinkedActivityCallback = std::function; + +/* IActivityProfilerSession: + * an opaque object that can be used by a high level profiler to + * start/stop and return trace events. + */ +class IActivityProfilerSession { + public: + virtual ~IActivityProfilerSession() {} + + // start the trace collection synchronously + virtual void start() = 0; + + // stop the trace collection synchronously + virtual void stop() = 0; + + TraceStatus status() { + return status_; + } + + // returns errors with this trace + virtual std::vector errors() = 0; + + // processes trace activities using logger + virtual void processTrace(ActivityLogger& logger) = 0; + + virtual void processTrace( + ActivityLogger& logger, + getLinkedActivityCallback /*getLinkedActivity*/, + int64_t /*startTime*/, + int64_t /*endTime*/) { + processTrace(logger); + } + + // returns device info used in this trace, could be nullptr + virtual std::unique_ptr getDeviceInfo() = 0; + + // returns resource info used in this trace, could be empty + virtual std::vector getResourceInfos() = 0; + + // release ownership of the trace events and metadata + virtual std::unique_ptr getTraceBuffer() = 0; + + // XXX define trace formats + // virtual save(string name, TraceFormat format) + + virtual void pushCorrelationId(uint64_t /*id*/) {} + virtual void popCorrelationId() {} + + virtual void pushUserCorrelationId(uint64_t /*id*/) {} + virtual void popUserCorrelationId() {} + + virtual std::string getDeviceProperties() { + return ""; + } + + protected: + TraceStatus status_ = TraceStatus::READY; +}; + +/* Activity Profiler Plugins: + * These allow other frameworks to integrate into Kineto's primariy + * activity profiler. While the primary activity profiler handles + * timing the trace collections and correlating events the plugins + * can become source of new trace activity types. + */ +class IActivityProfiler { + public: + virtual ~IActivityProfiler() {} + + // name of profiler + virtual const std::string& name() const = 0; + + // returns activity types this profiler supports + virtual const std::set& availableActivities() const = 0; + + // Calls prepare() on registered tracer providers passing in the relevant + // activity types. Returns a profiler session handle + virtual std::unique_ptr configure( + const std::set& activity_types, + const Config& config) = 0; + + // asynchronous version of the above with future timestamp and duration. + virtual std::unique_ptr configure( + int64_t ts_ms, + int64_t duration_ms, + const std::set& activity_types, + const Config& config) = 0; +}; + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ILoggerObserver.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ILoggerObserver.h new file mode 100644 index 0000000000000000000000000000000000000000..b0bb46183ba4d6a269edac829e6d5ebfca4d38c4 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ILoggerObserver.h @@ -0,0 +1,66 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include + +// Stages in libkineto used when pushing logs to UST Logger. +constexpr char kWarmUpStage[] = "Warm Up"; +constexpr char kCollectionStage[] = "Collection"; +constexpr char kPostProcessingStage[] = "Post Processing"; + +// Special string in UST for determining if traces are empty +constexpr char kEmptyTrace[] = + "No Valid Trace Events (CPU/GPU) found. Outputting empty trace."; + +#if !USE_GOOGLE_LOG + +#include +#include + +#include + +namespace libkineto { + +enum LoggerOutputType { + VERBOSE = 0, + INFO = 1, + WARNING = 2, + STAGE = 3, + ERROR = 4, + ENUM_COUNT = 5 +}; + +const char* toString(LoggerOutputType t); +LoggerOutputType toLoggerOutputType(const std::string& str); + +constexpr int LoggerTypeCount = (int)LoggerOutputType::ENUM_COUNT; + +class ILoggerObserver { + public: + virtual ~ILoggerObserver() = default; + virtual void write(const std::string& message, LoggerOutputType ot) = 0; + virtual const std::map> + extractCollectorMetadata() = 0; + virtual void reset() = 0; + virtual void addDevice(const int64_t device) = 0; + virtual void setTraceDurationMS(const int64_t duration) = 0; + virtual void addEventCount(const int64_t count) = 0; + virtual void setTraceID(const std::string&) {} + virtual void setGroupTraceID(const std::string&) {} + virtual void addDestination(const std::string& dest) = 0; + virtual void setTriggerOnDemand() {} + virtual void addMetadata( + const std::string& key, + const std::string& value) = 0; +}; + +} // namespace libkineto + +#endif // !USE_GOOGLE_LOG diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ITraceActivity.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ITraceActivity.h new file mode 100644 index 0000000000000000000000000000000000000000..23c8dfe28cde915b4a7e15f8b3898c04cfd544e0 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ITraceActivity.h @@ -0,0 +1,64 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include + +#include "ActivityType.h" + +namespace libkineto { + +class ActivityLogger; +struct TraceSpan; + +// Generic activity interface is borrowed from tensorboard protobuf format. +struct ITraceActivity { + virtual ~ITraceActivity() {} + // Device is a physical or logical entity, e.g. CPU, GPU or process + virtual int64_t deviceId() const = 0; + // A resource is something on the device, h/w thread, + // functional units etc. + virtual int64_t resourceId() const = 0; + // s/w thread + virtual int32_t getThreadId() const = 0; + // Start timestamp in nanoseconds + virtual int64_t timestamp() const = 0; + // Duration in nanoseconds + virtual int64_t duration() const = 0; + // Used to link up async activities + virtual int64_t correlationId() const = 0; + // Part of a flow, identified by flow id and type + virtual int flowType() const = 0; + virtual int64_t flowId() const = 0; + virtual bool flowStart() const = 0; + virtual ActivityType type() const = 0; + virtual const std::string name() const = 0; + // Optional linked activity + virtual const ITraceActivity* linkedActivity() const = 0; + // Optional containing trace object + virtual const TraceSpan* traceSpan() const = 0; + // Log activity + virtual void log(ActivityLogger& logger) const = 0; + // Return json formatted metadata + // FIXME: Return iterator to dynamic type map here instead + virtual const std::string metadataJson() const = 0; + // Return the metadata value in string format with key + // @lint-ignore CLANGTIDY: clang-diagnostic-unused-parameter + virtual const std::string getMetadataValue(const std::string& key) const { + return ""; + } + + static int64_t nsToUs(int64_t ns) { + // It's important that this conversion is the same everywhere. + // No rounding! + return ns / 1000; + } +}; + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/LoggingAPI.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/LoggingAPI.h new file mode 100644 index 0000000000000000000000000000000000000000..cc3ac2b27f31ec6b87a35e4bdfdf2b35b6da0502 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/LoggingAPI.h @@ -0,0 +1,14 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +namespace libkineto { +int getLogSeverityLevel(); +void setLogSeverityLevel(int level); +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ThreadUtil.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ThreadUtil.h new file mode 100644 index 0000000000000000000000000000000000000000..ca52c6343c1cbfc4c07fd7c34cd76b6a87c1e7fa --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/ThreadUtil.h @@ -0,0 +1,34 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include +#include +#include +#include + +namespace libkineto { + +int32_t systemThreadId(bool cache = true); +int32_t threadId(); +bool setThreadName(const std::string& name); +std::string getThreadName(); + +int32_t processId(bool cache = true); +std::string processName(int32_t pid); + +// Return a list of pids and process names for the current process +// and its parents. +std::vector> pidCommandPairsOfAncestors(); + +// Resets all cached Thread local state, this must be done on +// forks to prevent stale values from being retained. +void resetTLS(); + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/TraceSpan.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/TraceSpan.h new file mode 100644 index 0000000000000000000000000000000000000000..cc62a2aec6546471231b63ced752e15e4dd5aa55 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/TraceSpan.h @@ -0,0 +1,38 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include +#include +#include + +namespace libkineto { + +struct TraceSpan { + TraceSpan() = delete; + TraceSpan(int64_t startTime, int64_t endTime, std::string name) + : startTime(startTime), endTime(endTime), name(std::move(name)) {} + TraceSpan(int opCount, int it, std::string name, std::string prefix) + : opCount(opCount), + iteration(it), + name(std::move(name)), + prefix(std::move(prefix)) {} + + // FIXME: change to duration? + int64_t startTime{0}; + int64_t endTime{0}; + int opCount{0}; + int iteration{-1}; + // Name is used to identify timeline + std::string name; + // Prefix used to distinguish trace spans on the same timeline + std::string prefix; +}; + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/libkineto.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/libkineto.h new file mode 100644 index 0000000000000000000000000000000000000000..a122a77a524157c1c2129751b14aee48cbdb7cab --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/libkineto.h @@ -0,0 +1,162 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +// Mediator for initialization and profiler control + +#pragma once + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include "ActivityProfilerInterface.h" +#include "ActivityTraceInterface.h" +#include "ActivityType.h" +#include "ClientInterface.h" +#include "GenericTraceActivity.h" +#include "IActivityProfiler.h" +#include "ILoggerObserver.h" +#include "LoggingAPI.h" +#include "TraceSpan.h" + +#include "ThreadUtil.h" + +extern "C" { +void suppressLibkinetoLogMessages(); +int InitializeInjection(void); +void libkineto_init(bool cpuOnly, bool logOnError); +bool hasTestEnvVar(); +} + +namespace libkineto { + +class Config; +class ConfigLoader; + +struct CpuTraceBuffer { + template + void emplace_activity(Args&&... args) { + activities.emplace_back( + std::make_unique(std::forward(args)...)); + } + + static GenericTraceActivity& toRef( + std::unique_ptr& ref) { + return *ref; + } + + static const GenericTraceActivity& toRef( + const std::unique_ptr& ref) { + return *ref; + } + + TraceSpan span{0, 0, "none"}; + int gpuOpCount; + std::deque> activities; +}; + +using ChildActivityProfilerFactory = + std::function()>; + +class LibkinetoApi { + public: + explicit LibkinetoApi(ConfigLoader& configLoader) + : configLoader_(configLoader) {} + + // Called by client that supports tracing API. + // libkineto can still function without this. + void registerClient(ClientInterface* client); + + // Called by libkineto on init + void registerProfiler(std::unique_ptr profiler) { + activityProfiler_ = std::move(profiler); + initClientIfRegistered(); + } + + ActivityProfilerInterface& activityProfiler() { + return *activityProfiler_; + } + + ClientInterface* client() { + return client_; + } + + void initProfilerIfRegistered() { + static std::once_flag once; + if (activityProfiler_) { + std::call_once(once, [this] { + if (!activityProfiler_->isInitialized()) { + activityProfiler_->init(); + initChildActivityProfilers(); + } + }); + } + } + + bool isProfilerInitialized() const { + return activityProfiler_ && activityProfiler_->isInitialized(); + } + + bool isProfilerRegistered() const { + return activityProfiler_ != nullptr; + } + + void suppressLogMessages() { + suppressLibkinetoLogMessages(); + } + + void resetKinetoTLS() { + resetTLS(); + } + + // Provides access to profier configuration manaegement + ConfigLoader& configLoader() { + return configLoader_; + } + + void registerProfilerFactory(ChildActivityProfilerFactory factory) { + if (isProfilerInitialized()) { + activityProfiler_->addChildActivityProfiler(factory()); + } else { + childProfilerFactories_.push_back(factory); + } + } + + private: + void initChildActivityProfilers() { + if (!isProfilerInitialized()) { + return; + } + for (const auto& factory : childProfilerFactories_) { + activityProfiler_->addChildActivityProfiler(factory()); + } + childProfilerFactories_.clear(); + } + + // Client is initialized once both it and libkineto has registered + void initClientIfRegistered(); + + ConfigLoader& configLoader_; + std::unique_ptr activityProfiler_{}; + ClientInterface* client_{}; + int32_t clientRegisterThread_{0}; + + std::vector childProfilerFactories_; +}; + +// Singleton +LibkinetoApi& api(); + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/output_base.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/output_base.h new file mode 100644 index 0000000000000000000000000000000000000000..303d3e9a15bd7643aa70acb23077f40716166998 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/output_base.h @@ -0,0 +1,76 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include +#include +#include +#include +#include + +// TODO(T90238193) +// @lint-ignore-every CLANGTIDY facebook-hte-RelativeInclude +#include "GenericTraceActivity.h" +#include "IActivityProfiler.h" +#include "ThreadUtil.h" +#include "TraceSpan.h" + +namespace KINETO_NAMESPACE { +struct ActivityBuffers; +} + +namespace libkineto { + +using namespace KINETO_NAMESPACE; + +// Used by sortIndex to put GPU tracks at the bottom +// of the trace timelines. The largest valid CPU PID is 4,194,304, +// so 5000000 is enough to guarantee that GPU tracks are sorted after CPU. +constexpr int64_t kExceedMaxPid = 5000000; + +class ActivityLogger { + public: + virtual ~ActivityLogger() = default; + + struct OverheadInfo { + explicit OverheadInfo(const std::string& name) : name(name) {} + const std::string name; + }; + + virtual void handleDeviceInfo(const DeviceInfo& info, uint64_t time) = 0; + + virtual void handleResourceInfo(const ResourceInfo& info, int64_t time) = 0; + + virtual void handleOverheadInfo(const OverheadInfo& info, int64_t time) = 0; + + virtual void handleTraceSpan(const TraceSpan& span) = 0; + + virtual void handleActivity(const libkineto::ITraceActivity& activity) = 0; + virtual void handleGenericActivity( + const libkineto::GenericTraceActivity& activity) = 0; + + virtual void handleTraceStart( + const std::unordered_map& metadata, + const std::string& device_properties) = 0; + + void handleTraceStart() { + handleTraceStart(std::unordered_map(), ""); + } + + virtual void finalizeTrace( + const Config& config, + std::unique_ptr buffers, + int64_t endTime, + std::unordered_map>& metadata) = 0; + + protected: + ActivityLogger() = default; +}; + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/time_since_epoch.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/time_since_epoch.h new file mode 100644 index 0000000000000000000000000000000000000000..17faccec68d446a7cbff76acb243db90bb0c1f40 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/kineto/time_since_epoch.h @@ -0,0 +1,21 @@ +/* + * Copyright (c) Meta Platforms, Inc. and affiliates. + * All rights reserved. + * + * This source code is licensed under the BSD-style license found in the + * LICENSE file in the root directory of this source tree. + */ + +#pragma once + +#include + +namespace libkineto { +template +inline int64_t timeSinceEpoch(const std::chrono::time_point& t) { + return std::chrono::duration_cast( + t.time_since_epoch()) + .count(); +} + +} // namespace libkineto diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/pybind11/attr.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/pybind11/attr.h new file mode 100644 index 0000000000000000000000000000000000000000..1044db94d906ac5fcf6faab6ac7668187314598f --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/pybind11/attr.h @@ -0,0 +1,690 @@ +/* + pybind11/attr.h: Infrastructure for processing custom + type and function attributes + + Copyright (c) 2016 Wenzel Jakob + + All rights reserved. Use of this source code is governed by a + BSD-style license that can be found in the LICENSE file. +*/ + +#pragma once + +#include "detail/common.h" +#include "cast.h" + +#include + +PYBIND11_NAMESPACE_BEGIN(PYBIND11_NAMESPACE) + +/// \addtogroup annotations +/// @{ + +/// Annotation for methods +struct is_method { + handle class_; + explicit is_method(const handle &c) : class_(c) {} +}; + +/// Annotation for setters +struct is_setter {}; + +/// Annotation for operators +struct is_operator {}; + +/// Annotation for classes that cannot be subclassed +struct is_final {}; + +/// Annotation for parent scope +struct scope { + handle value; + explicit scope(const handle &s) : value(s) {} +}; + +/// Annotation for documentation +struct doc { + const char *value; + explicit doc(const char *value) : value(value) {} +}; + +/// Annotation for function names +struct name { + const char *value; + explicit name(const char *value) : value(value) {} +}; + +/// Annotation indicating that a function is an overload associated with a given "sibling" +struct sibling { + handle value; + explicit sibling(const handle &value) : value(value.ptr()) {} +}; + +/// Annotation indicating that a class derives from another given type +template +struct base { + + PYBIND11_DEPRECATED( + "base() was deprecated in favor of specifying 'T' as a template argument to class_") + base() = default; +}; + +/// Keep patient alive while nurse lives +template +struct keep_alive {}; + +/// Annotation indicating that a class is involved in a multiple inheritance relationship +struct multiple_inheritance {}; + +/// Annotation which enables dynamic attributes, i.e. adds `__dict__` to a class +struct dynamic_attr {}; + +/// Annotation which enables the buffer protocol for a type +struct buffer_protocol {}; + +/// Annotation which requests that a special metaclass is created for a type +struct metaclass { + handle value; + + PYBIND11_DEPRECATED("py::metaclass() is no longer required. It's turned on by default now.") + metaclass() = default; + + /// Override pybind11's default metaclass + explicit metaclass(handle value) : value(value) {} +}; + +/// Specifies a custom callback with signature `void (PyHeapTypeObject*)` that +/// may be used to customize the Python type. +/// +/// The callback is invoked immediately before `PyType_Ready`. +/// +/// Note: This is an advanced interface, and uses of it may require changes to +/// work with later versions of pybind11. You may wish to consult the +/// implementation of `make_new_python_type` in `detail/classes.h` to understand +/// the context in which the callback will be run. +struct custom_type_setup { + using callback = std::function; + + explicit custom_type_setup(callback value) : value(std::move(value)) {} + + callback value; +}; + +/// Annotation that marks a class as local to the module: +struct module_local { + const bool value; + constexpr explicit module_local(bool v = true) : value(v) {} +}; + +/// Annotation to mark enums as an arithmetic type +struct arithmetic {}; + +/// Mark a function for addition at the beginning of the existing overload chain instead of the end +struct prepend {}; + +/** \rst + A call policy which places one or more guard variables (``Ts...``) around the function call. + + For example, this definition: + + .. code-block:: cpp + + m.def("foo", foo, py::call_guard()); + + is equivalent to the following pseudocode: + + .. code-block:: cpp + + m.def("foo", [](args...) { + T scope_guard; + return foo(args...); // forwarded arguments + }); + \endrst */ +template +struct call_guard; + +template <> +struct call_guard<> { + using type = detail::void_type; +}; + +template +struct call_guard { + static_assert(std::is_default_constructible::value, + "The guard type must be default constructible"); + + using type = T; +}; + +template +struct call_guard { + struct type { + T guard{}; // Compose multiple guard types with left-to-right default-constructor order + typename call_guard::type next{}; + }; +}; + +/// @} annotations + +PYBIND11_NAMESPACE_BEGIN(detail) +/* Forward declarations */ +enum op_id : int; +enum op_type : int; +struct undefined_t; +template +struct op_; +void keep_alive_impl(size_t Nurse, size_t Patient, function_call &call, handle ret); + +/// Internal data structure which holds metadata about a keyword argument +struct argument_record { + const char *name; ///< Argument name + const char *descr; ///< Human-readable version of the argument value + handle value; ///< Associated Python object + bool convert : 1; ///< True if the argument is allowed to convert when loading + bool none : 1; ///< True if None is allowed when loading + + argument_record(const char *name, const char *descr, handle value, bool convert, bool none) + : name(name), descr(descr), value(value), convert(convert), none(none) {} +}; + +/// Internal data structure which holds metadata about a bound function (signature, overloads, +/// etc.) +struct function_record { + function_record() + : is_constructor(false), is_new_style_constructor(false), is_stateless(false), + is_operator(false), is_method(false), is_setter(false), has_args(false), + has_kwargs(false), prepend(false) {} + + /// Function name + char *name = nullptr; /* why no C++ strings? They generate heavier code.. */ + + // User-specified documentation string + char *doc = nullptr; + + /// Human-readable version of the function signature + char *signature = nullptr; + + /// List of registered keyword arguments + std::vector args; + + /// Pointer to lambda function which converts arguments and performs the actual call + handle (*impl)(function_call &) = nullptr; + + /// Storage for the wrapped function pointer and captured data, if any + void *data[3] = {}; + + /// Pointer to custom destructor for 'data' (if needed) + void (*free_data)(function_record *ptr) = nullptr; + + /// Return value policy associated with this function + return_value_policy policy = return_value_policy::automatic; + + /// True if name == '__init__' + bool is_constructor : 1; + + /// True if this is a new-style `__init__` defined in `detail/init.h` + bool is_new_style_constructor : 1; + + /// True if this is a stateless function pointer + bool is_stateless : 1; + + /// True if this is an operator (__add__), etc. + bool is_operator : 1; + + /// True if this is a method + bool is_method : 1; + + /// True if this is a setter + bool is_setter : 1; + + /// True if the function has a '*args' argument + bool has_args : 1; + + /// True if the function has a '**kwargs' argument + bool has_kwargs : 1; + + /// True if this function is to be inserted at the beginning of the overload resolution chain + bool prepend : 1; + + /// Number of arguments (including py::args and/or py::kwargs, if present) + std::uint16_t nargs; + + /// Number of leading positional arguments, which are terminated by a py::args or py::kwargs + /// argument or by a py::kw_only annotation. + std::uint16_t nargs_pos = 0; + + /// Number of leading arguments (counted in `nargs`) that are positional-only + std::uint16_t nargs_pos_only = 0; + + /// Python method object + PyMethodDef *def = nullptr; + + /// Python handle to the parent scope (a class or a module) + handle scope; + + /// Python handle to the sibling function representing an overload chain + handle sibling; + + /// Pointer to next overload + function_record *next = nullptr; +}; + +/// Special data structure which (temporarily) holds metadata about a bound class +struct type_record { + PYBIND11_NOINLINE type_record() + : multiple_inheritance(false), dynamic_attr(false), buffer_protocol(false), + default_holder(true), module_local(false), is_final(false) {} + + /// Handle to the parent scope + handle scope; + + /// Name of the class + const char *name = nullptr; + + // Pointer to RTTI type_info data structure + const std::type_info *type = nullptr; + + /// How large is the underlying C++ type? + size_t type_size = 0; + + /// What is the alignment of the underlying C++ type? + size_t type_align = 0; + + /// How large is the type's holder? + size_t holder_size = 0; + + /// The global operator new can be overridden with a class-specific variant + void *(*operator_new)(size_t) = nullptr; + + /// Function pointer to class_<..>::init_instance + void (*init_instance)(instance *, const void *) = nullptr; + + /// Function pointer to class_<..>::dealloc + void (*dealloc)(detail::value_and_holder &) = nullptr; + + /// List of base classes of the newly created type + list bases; + + /// Optional docstring + const char *doc = nullptr; + + /// Custom metaclass (optional) + handle metaclass; + + /// Custom type setup. + custom_type_setup::callback custom_type_setup_callback; + + /// Multiple inheritance marker + bool multiple_inheritance : 1; + + /// Does the class manage a __dict__? + bool dynamic_attr : 1; + + /// Does the class implement the buffer protocol? + bool buffer_protocol : 1; + + /// Is the default (unique_ptr) holder type used? + bool default_holder : 1; + + /// Is the class definition local to the module shared object? + bool module_local : 1; + + /// Is the class inheritable from python classes? + bool is_final : 1; + + PYBIND11_NOINLINE void add_base(const std::type_info &base, void *(*caster)(void *) ) { + auto *base_info = detail::get_type_info(base, false); + if (!base_info) { + std::string tname(base.name()); + detail::clean_type_id(tname); + pybind11_fail("generic_type: type \"" + std::string(name) + + "\" referenced unknown base type \"" + tname + "\""); + } + + if (default_holder != base_info->default_holder) { + std::string tname(base.name()); + detail::clean_type_id(tname); + pybind11_fail("generic_type: type \"" + std::string(name) + "\" " + + (default_holder ? "does not have" : "has") + + " a non-default holder type while its base \"" + tname + "\" " + + (base_info->default_holder ? "does not" : "does")); + } + + bases.append((PyObject *) base_info->type); + +#if PY_VERSION_HEX < 0x030B0000 + dynamic_attr |= base_info->type->tp_dictoffset != 0; +#else + dynamic_attr |= (base_info->type->tp_flags & Py_TPFLAGS_MANAGED_DICT) != 0; +#endif + + if (caster) { + base_info->implicit_casts.emplace_back(type, caster); + } + } +}; + +inline function_call::function_call(const function_record &f, handle p) : func(f), parent(p) { + args.reserve(f.nargs); + args_convert.reserve(f.nargs); +} + +/// Tag for a new-style `__init__` defined in `detail/init.h` +struct is_new_style_constructor {}; + +/** + * Partial template specializations to process custom attributes provided to + * cpp_function_ and class_. These are either used to initialize the respective + * fields in the type_record and function_record data structures or executed at + * runtime to deal with custom call policies (e.g. keep_alive). + */ +template +struct process_attribute; + +template +struct process_attribute_default { + /// Default implementation: do nothing + static void init(const T &, function_record *) {} + static void init(const T &, type_record *) {} + static void precall(function_call &) {} + static void postcall(function_call &, handle) {} +}; + +/// Process an attribute specifying the function's name +template <> +struct process_attribute : process_attribute_default { + static void init(const name &n, function_record *r) { r->name = const_cast(n.value); } +}; + +/// Process an attribute specifying the function's docstring +template <> +struct process_attribute : process_attribute_default { + static void init(const doc &n, function_record *r) { r->doc = const_cast(n.value); } +}; + +/// Process an attribute specifying the function's docstring (provided as a C-style string) +template <> +struct process_attribute : process_attribute_default { + static void init(const char *d, function_record *r) { r->doc = const_cast(d); } + static void init(const char *d, type_record *r) { r->doc = d; } +}; +template <> +struct process_attribute : process_attribute {}; + +/// Process an attribute indicating the function's return value policy +template <> +struct process_attribute : process_attribute_default { + static void init(const return_value_policy &p, function_record *r) { r->policy = p; } +}; + +/// Process an attribute which indicates that this is an overloaded function associated with a +/// given sibling +template <> +struct process_attribute : process_attribute_default { + static void init(const sibling &s, function_record *r) { r->sibling = s.value; } +}; + +/// Process an attribute which indicates that this function is a method +template <> +struct process_attribute : process_attribute_default { + static void init(const is_method &s, function_record *r) { + r->is_method = true; + r->scope = s.class_; + } +}; + +/// Process an attribute which indicates that this function is a setter +template <> +struct process_attribute : process_attribute_default { + static void init(const is_setter &, function_record *r) { r->is_setter = true; } +}; + +/// Process an attribute which indicates the parent scope of a method +template <> +struct process_attribute : process_attribute_default { + static void init(const scope &s, function_record *r) { r->scope = s.value; } +}; + +/// Process an attribute which indicates that this function is an operator +template <> +struct process_attribute : process_attribute_default { + static void init(const is_operator &, function_record *r) { r->is_operator = true; } +}; + +template <> +struct process_attribute + : process_attribute_default { + static void init(const is_new_style_constructor &, function_record *r) { + r->is_new_style_constructor = true; + } +}; + +inline void check_kw_only_arg(const arg &a, function_record *r) { + if (r->args.size() > r->nargs_pos && (!a.name || a.name[0] == '\0')) { + pybind11_fail("arg(): cannot specify an unnamed argument after a kw_only() annotation or " + "args() argument"); + } +} + +inline void append_self_arg_if_needed(function_record *r) { + if (r->is_method && r->args.empty()) { + r->args.emplace_back("self", nullptr, handle(), /*convert=*/true, /*none=*/false); + } +} + +/// Process a keyword argument attribute (*without* a default value) +template <> +struct process_attribute : process_attribute_default { + static void init(const arg &a, function_record *r) { + append_self_arg_if_needed(r); + r->args.emplace_back(a.name, nullptr, handle(), !a.flag_noconvert, a.flag_none); + + check_kw_only_arg(a, r); + } +}; + +/// Process a keyword argument attribute (*with* a default value) +template <> +struct process_attribute : process_attribute_default { + static void init(const arg_v &a, function_record *r) { + if (r->is_method && r->args.empty()) { + r->args.emplace_back( + "self", /*descr=*/nullptr, /*parent=*/handle(), /*convert=*/true, /*none=*/false); + } + + if (!a.value) { +#if defined(PYBIND11_DETAILED_ERROR_MESSAGES) + std::string descr("'"); + if (a.name) { + descr += std::string(a.name) + ": "; + } + descr += a.type + "'"; + if (r->is_method) { + if (r->name) { + descr += " in method '" + (std::string) str(r->scope) + "." + + (std::string) r->name + "'"; + } else { + descr += " in method of '" + (std::string) str(r->scope) + "'"; + } + } else if (r->name) { + descr += " in function '" + (std::string) r->name + "'"; + } + pybind11_fail("arg(): could not convert default argument " + descr + + " into a Python object (type not registered yet?)"); +#else + pybind11_fail("arg(): could not convert default argument " + "into a Python object (type not registered yet?). " + "#define PYBIND11_DETAILED_ERROR_MESSAGES or compile in debug mode for " + "more information."); +#endif + } + r->args.emplace_back(a.name, a.descr, a.value.inc_ref(), !a.flag_noconvert, a.flag_none); + + check_kw_only_arg(a, r); + } +}; + +/// Process a keyword-only-arguments-follow pseudo argument +template <> +struct process_attribute : process_attribute_default { + static void init(const kw_only &, function_record *r) { + append_self_arg_if_needed(r); + if (r->has_args && r->nargs_pos != static_cast(r->args.size())) { + pybind11_fail("Mismatched args() and kw_only(): they must occur at the same relative " + "argument location (or omit kw_only() entirely)"); + } + r->nargs_pos = static_cast(r->args.size()); + } +}; + +/// Process a positional-only-argument maker +template <> +struct process_attribute : process_attribute_default { + static void init(const pos_only &, function_record *r) { + append_self_arg_if_needed(r); + r->nargs_pos_only = static_cast(r->args.size()); + if (r->nargs_pos_only > r->nargs_pos) { + pybind11_fail("pos_only(): cannot follow a py::args() argument"); + } + // It also can't follow a kw_only, but a static_assert in pybind11.h checks that + } +}; + +/// Process a parent class attribute. Single inheritance only (class_ itself already guarantees +/// that) +template +struct process_attribute::value>> + : process_attribute_default { + static void init(const handle &h, type_record *r) { r->bases.append(h); } +}; + +/// Process a parent class attribute (deprecated, does not support multiple inheritance) +template +struct process_attribute> : process_attribute_default> { + static void init(const base &, type_record *r) { r->add_base(typeid(T), nullptr); } +}; + +/// Process a multiple inheritance attribute +template <> +struct process_attribute : process_attribute_default { + static void init(const multiple_inheritance &, type_record *r) { + r->multiple_inheritance = true; + } +}; + +template <> +struct process_attribute : process_attribute_default { + static void init(const dynamic_attr &, type_record *r) { r->dynamic_attr = true; } +}; + +template <> +struct process_attribute { + static void init(const custom_type_setup &value, type_record *r) { + r->custom_type_setup_callback = value.value; + } +}; + +template <> +struct process_attribute : process_attribute_default { + static void init(const is_final &, type_record *r) { r->is_final = true; } +}; + +template <> +struct process_attribute : process_attribute_default { + static void init(const buffer_protocol &, type_record *r) { r->buffer_protocol = true; } +}; + +template <> +struct process_attribute : process_attribute_default { + static void init(const metaclass &m, type_record *r) { r->metaclass = m.value; } +}; + +template <> +struct process_attribute : process_attribute_default { + static void init(const module_local &l, type_record *r) { r->module_local = l.value; } +}; + +/// Process a 'prepend' attribute, putting this at the beginning of the overload chain +template <> +struct process_attribute : process_attribute_default { + static void init(const prepend &, function_record *r) { r->prepend = true; } +}; + +/// Process an 'arithmetic' attribute for enums (does nothing here) +template <> +struct process_attribute : process_attribute_default {}; + +template +struct process_attribute> : process_attribute_default> {}; + +/** + * Process a keep_alive call policy -- invokes keep_alive_impl during the + * pre-call handler if both Nurse, Patient != 0 and use the post-call handler + * otherwise + */ +template +struct process_attribute> + : public process_attribute_default> { + template = 0> + static void precall(function_call &call) { + keep_alive_impl(Nurse, Patient, call, handle()); + } + template = 0> + static void postcall(function_call &, handle) {} + template = 0> + static void precall(function_call &) {} + template = 0> + static void postcall(function_call &call, handle ret) { + keep_alive_impl(Nurse, Patient, call, ret); + } +}; + +/// Recursively iterate over variadic template arguments +template +struct process_attributes { + static void init(const Args &...args, function_record *r) { + PYBIND11_WORKAROUND_INCORRECT_MSVC_C4100(r); + PYBIND11_WORKAROUND_INCORRECT_GCC_UNUSED_BUT_SET_PARAMETER(r); + using expander = int[]; + (void) expander{ + 0, ((void) process_attribute::type>::init(args, r), 0)...}; + } + static void init(const Args &...args, type_record *r) { + PYBIND11_WORKAROUND_INCORRECT_MSVC_C4100(r); + PYBIND11_WORKAROUND_INCORRECT_GCC_UNUSED_BUT_SET_PARAMETER(r); + using expander = int[]; + (void) expander{0, + (process_attribute::type>::init(args, r), 0)...}; + } + static void precall(function_call &call) { + PYBIND11_WORKAROUND_INCORRECT_MSVC_C4100(call); + using expander = int[]; + (void) expander{0, + (process_attribute::type>::precall(call), 0)...}; + } + static void postcall(function_call &call, handle fn_ret) { + PYBIND11_WORKAROUND_INCORRECT_MSVC_C4100(call, fn_ret); + PYBIND11_WORKAROUND_INCORRECT_GCC_UNUSED_BUT_SET_PARAMETER(fn_ret); + using expander = int[]; + (void) expander{ + 0, (process_attribute::type>::postcall(call, fn_ret), 0)...}; + } +}; + +template +using is_call_guard = is_instantiation; + +/// Extract the ``type`` from the first `call_guard` in `Extras...` (or `void_type` if none found) +template +using extract_guard_t = typename exactly_one_t, Extra...>::type; + +/// Check the number of named arguments at compile time +template ::value...), + size_t self = constexpr_sum(std::is_same::value...)> +constexpr bool expected_num_args(size_t nargs, bool has_args, bool has_kwargs) { + PYBIND11_WORKAROUND_INCORRECT_MSVC_C4100(nargs, has_args, has_kwargs); + return named == 0 || (self + named + size_t(has_args) + size_t(has_kwargs)) == nargs; +} + +PYBIND11_NAMESPACE_END(detail) +PYBIND11_NAMESPACE_END(PYBIND11_NAMESPACE) diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/pybind11/buffer_info.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/pybind11/buffer_info.h new file mode 100644 index 0000000000000000000000000000000000000000..75aec0ba3092a401a73f7cdb09b0894aef85cc27 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/pybind11/buffer_info.h @@ -0,0 +1,208 @@ +/* + pybind11/buffer_info.h: Python buffer object interface + + Copyright (c) 2016 Wenzel Jakob + + All rights reserved. Use of this source code is governed by a + BSD-style license that can be found in the LICENSE file. +*/ + +#pragma once + +#include "detail/common.h" + +PYBIND11_NAMESPACE_BEGIN(PYBIND11_NAMESPACE) + +PYBIND11_NAMESPACE_BEGIN(detail) + +// Default, C-style strides +inline std::vector c_strides(const std::vector &shape, ssize_t itemsize) { + auto ndim = shape.size(); + std::vector strides(ndim, itemsize); + if (ndim > 0) { + for (size_t i = ndim - 1; i > 0; --i) { + strides[i - 1] = strides[i] * shape[i]; + } + } + return strides; +} + +// F-style strides; default when constructing an array_t with `ExtraFlags & f_style` +inline std::vector f_strides(const std::vector &shape, ssize_t itemsize) { + auto ndim = shape.size(); + std::vector strides(ndim, itemsize); + for (size_t i = 1; i < ndim; ++i) { + strides[i] = strides[i - 1] * shape[i - 1]; + } + return strides; +} + +template +struct compare_buffer_info; + +PYBIND11_NAMESPACE_END(detail) + +/// Information record describing a Python buffer object +struct buffer_info { + void *ptr = nullptr; // Pointer to the underlying storage + ssize_t itemsize = 0; // Size of individual items in bytes + ssize_t size = 0; // Total number of entries + std::string format; // For homogeneous buffers, this should be set to + // format_descriptor::format() + ssize_t ndim = 0; // Number of dimensions + std::vector shape; // Shape of the tensor (1 entry per dimension) + std::vector strides; // Number of bytes between adjacent entries + // (for each per dimension) + bool readonly = false; // flag to indicate if the underlying storage may be written to + + buffer_info() = default; + + buffer_info(void *ptr, + ssize_t itemsize, + const std::string &format, + ssize_t ndim, + detail::any_container shape_in, + detail::any_container strides_in, + bool readonly = false) + : ptr(ptr), itemsize(itemsize), size(1), format(format), ndim(ndim), + shape(std::move(shape_in)), strides(std::move(strides_in)), readonly(readonly) { + if (ndim != (ssize_t) shape.size() || ndim != (ssize_t) strides.size()) { + pybind11_fail("buffer_info: ndim doesn't match shape and/or strides length"); + } + for (size_t i = 0; i < (size_t) ndim; ++i) { + size *= shape[i]; + } + } + + template + buffer_info(T *ptr, + detail::any_container shape_in, + detail::any_container strides_in, + bool readonly = false) + : buffer_info(private_ctr_tag(), + ptr, + sizeof(T), + format_descriptor::format(), + static_cast(shape_in->size()), + std::move(shape_in), + std::move(strides_in), + readonly) {} + + buffer_info(void *ptr, + ssize_t itemsize, + const std::string &format, + ssize_t size, + bool readonly = false) + : buffer_info(ptr, itemsize, format, 1, {size}, {itemsize}, readonly) {} + + template + buffer_info(T *ptr, ssize_t size, bool readonly = false) + : buffer_info(ptr, sizeof(T), format_descriptor::format(), size, readonly) {} + + template + buffer_info(const T *ptr, ssize_t size, bool readonly = true) + : buffer_info( + const_cast(ptr), sizeof(T), format_descriptor::format(), size, readonly) {} + + explicit buffer_info(Py_buffer *view, bool ownview = true) + : buffer_info( + view->buf, + view->itemsize, + view->format, + view->ndim, + {view->shape, view->shape + view->ndim}, + /* Though buffer::request() requests PyBUF_STRIDES, ctypes objects + * ignore this flag and return a view with NULL strides. + * When strides are NULL, build them manually. */ + view->strides + ? std::vector(view->strides, view->strides + view->ndim) + : detail::c_strides({view->shape, view->shape + view->ndim}, view->itemsize), + (view->readonly != 0)) { + // NOLINTNEXTLINE(cppcoreguidelines-prefer-member-initializer) + this->m_view = view; + // NOLINTNEXTLINE(cppcoreguidelines-prefer-member-initializer) + this->ownview = ownview; + } + + buffer_info(const buffer_info &) = delete; + buffer_info &operator=(const buffer_info &) = delete; + + buffer_info(buffer_info &&other) noexcept { (*this) = std::move(other); } + + buffer_info &operator=(buffer_info &&rhs) noexcept { + ptr = rhs.ptr; + itemsize = rhs.itemsize; + size = rhs.size; + format = std::move(rhs.format); + ndim = rhs.ndim; + shape = std::move(rhs.shape); + strides = std::move(rhs.strides); + std::swap(m_view, rhs.m_view); + std::swap(ownview, rhs.ownview); + readonly = rhs.readonly; + return *this; + } + + ~buffer_info() { + if (m_view && ownview) { + PyBuffer_Release(m_view); + delete m_view; + } + } + + Py_buffer *view() const { return m_view; } + Py_buffer *&view() { return m_view; } + + /* True if the buffer item type is equivalent to `T`. */ + // To define "equivalent" by example: + // `buffer_info::item_type_is_equivalent_to(b)` and + // `buffer_info::item_type_is_equivalent_to(b)` may both be true + // on some platforms, but `int` and `unsigned` will never be equivalent. + // For the ground truth, please inspect `detail::compare_buffer_info<>`. + template + bool item_type_is_equivalent_to() const { + return detail::compare_buffer_info::compare(*this); + } + +private: + struct private_ctr_tag {}; + + buffer_info(private_ctr_tag, + void *ptr, + ssize_t itemsize, + const std::string &format, + ssize_t ndim, + detail::any_container &&shape_in, + detail::any_container &&strides_in, + bool readonly) + : buffer_info( + ptr, itemsize, format, ndim, std::move(shape_in), std::move(strides_in), readonly) {} + + Py_buffer *m_view = nullptr; + bool ownview = false; +}; + +PYBIND11_NAMESPACE_BEGIN(detail) + +template +struct compare_buffer_info { + static bool compare(const buffer_info &b) { + // NOLINTNEXTLINE(bugprone-sizeof-expression) Needed for `PyObject *` + return b.format == format_descriptor::format() && b.itemsize == (ssize_t) sizeof(T); + } +}; + +template +struct compare_buffer_info::value>> { + static bool compare(const buffer_info &b) { + return (size_t) b.itemsize == sizeof(T) + && (b.format == format_descriptor::value + || ((sizeof(T) == sizeof(long)) + && b.format == (std::is_unsigned::value ? "L" : "l")) + || ((sizeof(T) == sizeof(size_t)) + && b.format == (std::is_unsigned::value ? "N" : "n"))); + } +}; + +PYBIND11_NAMESPACE_END(detail) +PYBIND11_NAMESPACE_END(PYBIND11_NAMESPACE) diff --git a/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/pybind11/cast.h b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/pybind11/cast.h new file mode 100644 index 0000000000000000000000000000000000000000..0f3091f6869900d14d521791198d97fcccf40629 --- /dev/null +++ b/Scripts_RSCM_sim_growth_n_climate_to_Yield/.venv/lib/python3.10/site-packages/torch/include/pybind11/cast.h @@ -0,0 +1,1855 @@ +/* + pybind11/cast.h: Partial template specializations to cast between + C++ and Python types + + Copyright (c) 2016 Wenzel Jakob + + All rights reserved. Use of this source code is governed by a + BSD-style license that can be found in the LICENSE file. +*/ + +#pragma once + +#include "detail/common.h" +#include "detail/descr.h" +#include "detail/type_caster_base.h" +#include "detail/typeid.h" +#include "pytypes.h" + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +PYBIND11_NAMESPACE_BEGIN(PYBIND11_NAMESPACE) + +PYBIND11_WARNING_DISABLE_MSVC(4127) + +PYBIND11_NAMESPACE_BEGIN(detail) + +template +class type_caster : public type_caster_base {}; +template +using make_caster = type_caster>; + +// Shortcut for calling a caster's `cast_op_type` cast operator for casting a type_caster to a T +template +typename make_caster::template cast_op_type cast_op(make_caster &caster) { + using result_t = typename make_caster::template cast_op_type; // See PR #4893 + return caster.operator result_t(); +} +template +typename make_caster::template cast_op_type::type> +cast_op(make_caster &&caster) { + using result_t = typename make_caster::template cast_op_type< + typename std::add_rvalue_reference::type>; // See PR #4893 + return std::move(caster).operator result_t(); +} + +template +class type_caster> { +private: + using caster_t = make_caster; + caster_t subcaster; + using reference_t = type &; + using subcaster_cast_op_type = typename caster_t::template cast_op_type; + + static_assert( + std::is_same::type &, subcaster_cast_op_type>::value + || std::is_same::value, + "std::reference_wrapper caster requires T to have a caster with an " + "`operator T &()` or `operator const T &()`"); + +public: + bool load(handle src, bool convert) { return subcaster.load(src, convert); } + static constexpr auto name = caster_t::name; + static handle + cast(const std::reference_wrapper &src, return_value_policy policy, handle parent) { + // It is definitely wrong to take ownership of this pointer, so mask that rvp + if (policy == return_value_policy::take_ownership + || policy == return_value_policy::automatic) { + policy = return_value_policy::automatic_reference; + } + return caster_t::cast(&src.get(), policy, parent); + } + template + using cast_op_type = std::reference_wrapper; + explicit operator std::reference_wrapper() { return cast_op(subcaster); } +}; + +#define PYBIND11_TYPE_CASTER(type, py_name) \ +protected: \ + type value; \ + \ +public: \ + static constexpr auto name = py_name; \ + template >::value, \ + int> \ + = 0> \ + static ::pybind11::handle cast( \ + T_ *src, ::pybind11::return_value_policy policy, ::pybind11::handle parent) { \ + if (!src) \ + return ::pybind11::none().release(); \ + if (policy == ::pybind11::return_value_policy::take_ownership) { \ + auto h = cast(std::move(*src), policy, parent); \ + delete src; \ + return h; \ + } \ + return cast(*src, policy, parent); \ + } \ + operator type *() { return &value; } /* NOLINT(bugprone-macro-parentheses) */ \ + operator type &() { return value; } /* NOLINT(bugprone-macro-parentheses) */ \ + operator type &&() && { return std::move(value); } /* NOLINT(bugprone-macro-parentheses) */ \ + template \ + using cast_op_type = ::pybind11::detail::movable_cast_op_type + +template +using is_std_char_type = any_of, /* std::string */ +#if defined(PYBIND11_HAS_U8STRING) + std::is_same, /* std::u8string */ +#endif + std::is_same, /* std::u16string */ + std::is_same, /* std::u32string */ + std::is_same /* std::wstring */ + >; + +template +struct type_caster::value && !is_std_char_type::value>> { + using _py_type_0 = conditional_t; + using _py_type_1 = conditional_t::value, + _py_type_0, + typename std::make_unsigned<_py_type_0>::type>; + using py_type = conditional_t::value, double, _py_type_1>; + +public: + bool load(handle src, bool convert) { + py_type py_value; + + if (!src) { + return false; + } + +#if !defined(PYPY_VERSION) + auto index_check = [](PyObject *o) { return PyIndex_Check(o); }; +#else + // In PyPy 7.3.3, `PyIndex_Check` is implemented by calling `__index__`, + // while CPython only considers the existence of `nb_index`/`__index__`. + auto index_check = [](PyObject *o) { return hasattr(o, "__index__"); }; +#endif + + if (std::is_floating_point::value) { + if (convert || PyFloat_Check(src.ptr())) { + py_value = (py_type) PyFloat_AsDouble(src.ptr()); + } else { + return false; + } + } else if (PyFloat_Check(src.ptr()) + || (!convert && !PYBIND11_LONG_CHECK(src.ptr()) && !index_check(src.ptr()))) { + return false; + } else { + handle src_or_index = src; + // PyPy: 7.3.7's 3.8 does not implement PyLong_*'s __index__ calls. +#if PY_VERSION_HEX < 0x03080000 || defined(PYPY_VERSION) + object index; + if (!PYBIND11_LONG_CHECK(src.ptr())) { // So: index_check(src.ptr()) + index = reinterpret_steal(PyNumber_Index(src.ptr())); + if (!index) { + PyErr_Clear(); + if (!convert) + return false; + } else { + src_or_index = index; + } + } +#endif + if (std::is_unsigned::value) { + py_value = as_unsigned(src_or_index.ptr()); + } else { // signed integer: + py_value = sizeof(T) <= sizeof(long) + ? (py_type) PyLong_AsLong(src_or_index.ptr()) + : (py_type) PYBIND11_LONG_AS_LONGLONG(src_or_index.ptr()); + } + } + + // Python API reported an error + bool py_err = py_value == (py_type) -1 && PyErr_Occurred(); + + // Check to see if the conversion is valid (integers should match exactly) + // Signed/unsigned checks happen elsewhere + if (py_err + || (std::is_integral::value && sizeof(py_type) != sizeof(T) + && py_value != (py_type) (T) py_value)) { + PyErr_Clear(); + if (py_err && convert && (PyNumber_Check(src.ptr()) != 0)) { + auto tmp = reinterpret_steal(std::is_floating_point::value + ? PyNumber_Float(src.ptr()) + : PyNumber_Long(src.ptr())); + PyErr_Clear(); + return load(tmp, false); + } + return false; + } + + value = (T) py_value; + return true; + } + + template + static typename std::enable_if::value, handle>::type + cast(U src, return_value_policy /* policy */, handle /* parent */) { + return PyFloat_FromDouble((double) src); + } + + template + static typename std::enable_if::value && std::is_signed::value + && (sizeof(U) <= sizeof(long)), + handle>::type + cast(U src, return_value_policy /* policy */, handle /* parent */) { + return PYBIND11_LONG_FROM_SIGNED((long) src); + } + + template + static typename std::enable_if::value && std::is_unsigned::value + && (sizeof(U) <= sizeof(unsigned long)), + handle>::type + cast(U src, return_value_policy /* policy */, handle /* parent */) { + return PYBIND11_LONG_FROM_UNSIGNED((unsigned long) src); + } + + template + static typename std::enable_if::value && std::is_signed::value + && (sizeof(U) > sizeof(long)), + handle>::type + cast(U src, return_value_policy /* policy */, handle /* parent */) { + return PyLong_FromLongLong((long long) src); + } + + template + static typename std::enable_if::value && std::is_unsigned::value + && (sizeof(U) > sizeof(unsigned long)), + handle>::type + cast(U src, return_value_policy /* policy */, handle /* parent */) { + return PyLong_FromUnsignedLongLong((unsigned long long) src); + } + + PYBIND11_TYPE_CASTER(T, const_name::value>("int", "float")); +}; + +template +struct void_caster { +public: + bool load(handle src, bool) { + if (src && src.is_none()) { + return true; + } + return false; + } + static handle cast(T, return_value_policy /* policy */, handle /* parent */) { + return none().release(); + } + PYBIND11_TYPE_CASTER(T, const_name("None")); +}; + +template <> +class type_caster : public void_caster {}; + +template <> +class type_caster : public type_caster { +public: + using type_caster::cast; + + bool load(handle h, bool) { + if (!h) { + return false; + } + if (h.is_none()) { + value = nullptr; + return true; + } + + /* Check if this is a capsule */ + if (isinstance(h)) { + value = reinterpret_borrow(h); + return true; + } + + /* Check if this is a C++ type */ + const auto &bases = all_type_info((PyTypeObject *) type::handle_of(h).ptr()); + if (bases.size() == 1) { // Only allowing loading from a single-value type + value = values_and_holders(reinterpret_cast(h.ptr())).begin()->value_ptr(); + return true; + } + + /* Fail */ + return false; + } + + static handle cast(const void *ptr, return_value_policy /* policy */, handle /* parent */) { + if (ptr) { + return capsule(ptr).release(); + } + return none().release(); + } + + template + using cast_op_type = void *&; + explicit operator void *&() { return value; } + static constexpr auto name = const_name("capsule"); + +private: + void *value = nullptr; +}; + +template <> +class type_caster : public void_caster {}; + +template <> +class type_caster { +public: + bool load(handle src, bool convert) { + if (!src) { + return false; + } + if (src.ptr() == Py_True) { + value = true; + return true; + } + if (src.ptr() == Py_False) { + value = false; + return true; + } + if (convert || is_numpy_bool(src)) { + // (allow non-implicit conversion for numpy booleans), use strncmp + // since NumPy 1.x had an additional trailing underscore. + + Py_ssize_t res = -1; + if (src.is_none()) { + res = 0; // None is implicitly converted to False + } +#if defined(PYPY_VERSION) + // On PyPy, check that "__bool__" attr exists + else if (hasattr(src, PYBIND11_BOOL_ATTR)) { + res = PyObject_IsTrue(src.ptr()); + } +#else + // Alternate approach for CPython: this does the same as the above, but optimized + // using the CPython API so as to avoid an unneeded attribute lookup. + else if (auto *tp_as_number = src.ptr()->ob_type->tp_as_number) { + if (PYBIND11_NB_BOOL(tp_as_number)) { + res = (*PYBIND11_NB_BOOL(tp_as_number))(src.ptr()); + } + } +#endif + if (res == 0 || res == 1) { + value = (res != 0); + return true; + } + PyErr_Clear(); + } + return false; + } + static handle cast(bool src, return_value_policy /* policy */, handle /* parent */) { + return handle(src ? Py_True : Py_False).inc_ref(); + } + PYBIND11_TYPE_CASTER(bool, const_name("bool")); + +private: + // Test if an object is a NumPy boolean (without fetching the type). + static inline bool is_numpy_bool(handle object) { + const char *type_name = Py_TYPE(object.ptr())->tp_name; + // Name changed to `numpy.bool` in NumPy 2, `numpy.bool_` is needed for 1.x support + return std::strcmp("numpy.bool", type_name) == 0 + || std::strcmp("numpy.bool_", type_name) == 0; + } +}; + +// Helper class for UTF-{8,16,32} C++ stl strings: +template +struct string_caster { + using CharT = typename StringType::value_type; + + // Simplify life by being able to assume standard char sizes (the standard only guarantees + // minimums, but Python requires exact sizes) + static_assert(!std::is_same::value || sizeof(CharT) == 1, + "Unsupported char size != 1"); +#if defined(PYBIND11_HAS_U8STRING) + static_assert(!std::is_same::value || sizeof(CharT) == 1, + "Unsupported char8_t size != 1"); +#endif + static_assert(!std::is_same::value || sizeof(CharT) == 2, + "Unsupported char16_t size != 2"); + static_assert(!std::is_same::value || sizeof(CharT) == 4, + "Unsupported char32_t size != 4"); + // wchar_t can be either 16 bits (Windows) or 32 (everywhere else) + static_assert(!std::is_same::value || sizeof(CharT) == 2 || sizeof(CharT) == 4, + "Unsupported wchar_t size != 2/4"); + static constexpr size_t UTF_N = 8 * sizeof(CharT); + + bool load(handle src, bool) { + handle load_src = src; + if (!src) { + return false; + } + if (!PyUnicode_Check(load_src.ptr())) { + return load_raw(load_src); + } + + // For UTF-8 we avoid the need for a temporary `bytes` object by using + // `PyUnicode_AsUTF8AndSize`. + if (UTF_N == 8) { + Py_ssize_t size = -1; + const auto *buffer + = reinterpret_cast(PyUnicode_AsUTF8AndSize(load_src.ptr(), &size)); + if (!buffer) { + PyErr_Clear(); + return false; + } + value = StringType(buffer, static_cast(size)); + return true; + } + + auto utfNbytes + = reinterpret_steal(PyUnicode_AsEncodedString(load_src.ptr(), + UTF_N == 8 ? "utf-8" + : UTF_N == 16 ? "utf-16" + : "utf-32", + nullptr)); + if (!utfNbytes) { + PyErr_Clear(); + return false; + } + + const auto *buffer + = reinterpret_cast(PYBIND11_BYTES_AS_STRING(utfNbytes.ptr())); + size_t length = (size_t) PYBIND11_BYTES_SIZE(utfNbytes.ptr()) / sizeof(CharT); + // Skip BOM for UTF-16/32 + if (UTF_N > 8) { + buffer++; + length--; + } + value = StringType(buffer, length); + + // If we're loading a string_view we need to keep the encoded Python object alive: + if (IsView) { + loader_life_support::add_patient(utfNbytes); + } + + return true; + } + + static handle + cast(const StringType &src, return_value_policy /* policy */, handle /* parent */) { + const char *buffer = reinterpret_cast(src.data()); + auto nbytes = ssize_t(src.size() * sizeof(CharT)); + handle s = decode_utfN(buffer, nbytes); + if (!s) { + throw error_already_set(); + } + return s; + } + + PYBIND11_TYPE_CASTER(StringType, const_name(PYBIND11_STRING_NAME)); + +private: + static handle decode_utfN(const char *buffer, ssize_t nbytes) { +#if !defined(PYPY_VERSION) + return UTF_N == 8 ? PyUnicode_DecodeUTF8(buffer, nbytes, nullptr) + : UTF_N == 16 ? PyUnicode_DecodeUTF16(buffer, nbytes, nullptr, nullptr) + : PyUnicode_DecodeUTF32(buffer, nbytes, nullptr, nullptr); +#else + // PyPy segfaults when on PyUnicode_DecodeUTF16 (and possibly on PyUnicode_DecodeUTF32 as + // well), so bypass the whole thing by just passing the encoding as a string value, which + // works properly: + return PyUnicode_Decode(buffer, + nbytes, + UTF_N == 8 ? "utf-8" + : UTF_N == 16 ? "utf-16" + : "utf-32", + nullptr); +#endif + } + + // When loading into a std::string or char*, accept a bytes/bytearray object as-is (i.e. + // without any encoding/decoding attempt). For other C++ char sizes this is a no-op. + // which supports loading a unicode from a str, doesn't take this path. + template + bool load_raw(enable_if_t::value, handle> src) { + if (PYBIND11_BYTES_CHECK(src.ptr())) { + // We were passed raw bytes; accept it into a std::string or char* + // without any encoding attempt. + const char *bytes = PYBIND11_BYTES_AS_STRING(src.ptr()); + if (!bytes) { + pybind11_fail("Unexpected PYBIND11_BYTES_AS_STRING() failure."); + } + value = StringType(bytes, (size_t) PYBIND11_BYTES_SIZE(src.ptr())); + return true; + } + if (PyByteArray_Check(src.ptr())) { + // We were passed a bytearray; accept it into a std::string or char* + // without any encoding attempt. + const char *bytearray = PyByteArray_AsString(src.ptr()); + if (!bytearray) { + pybind11_fail("Unexpected PyByteArray_AsString() failure."); + } + value = StringType(bytearray, (size_t) PyByteArray_Size(src.ptr())); + return true; + } + + return false; + } + + template + bool load_raw(enable_if_t::value, handle>) { + return false; + } +}; + +template +struct type_caster, + enable_if_t::value>> + : string_caster> {}; + +#ifdef PYBIND11_HAS_STRING_VIEW +template +struct type_caster, + enable_if_t::value>> + : string_caster, true> {}; +#endif + +// Type caster for C-style strings. We basically use a std::string type caster, but also add the +// ability to use None as a nullptr char* (which the string caster doesn't allow). +template +struct type_caster::value>> { + using StringType = std::basic_string; + using StringCaster = make_caster; + StringCaster str_caster; + bool none = false; + CharT one_char = 0; + +public: + bool load(handle src, bool convert) { + if (!src) { + return false; + } + if (src.is_none()) { + // Defer accepting None to other overloads (if we aren't in convert mode): + if (!convert) { + return false; + } + none = true; + return true; + } + return str_caster.load(src, convert); + } + + static handle cast(const CharT *src, return_value_policy policy, handle parent) { + if (src == nullptr) { + return pybind11::none().release(); + } + return StringCaster::cast(StringType(src), policy, parent); + } + + static handle cast(CharT src, return_value_policy policy, handle parent) { + if (std::is_same::value) { + handle s = PyUnicode_DecodeLatin1((const char *) &src, 1, nullptr); + if (!s) { + throw error_already_set(); + } + return s; + } + return StringCaster::cast(StringType(1, src), policy, parent); + } + + explicit operator CharT *() { + return none ? nullptr : const_cast(static_cast(str_caster).c_str()); + } + explicit operator CharT &() { + if (none) { + throw value_error("Cannot convert None to a character"); + } + + auto &value = static_cast(str_caster); + size_t str_len = value.size(); + if (str_len == 0) { + throw value_error("Cannot convert empty string to a character"); + } + + // If we're in UTF-8 mode, we have two possible failures: one for a unicode character that + // is too high, and one for multiple unicode characters (caught later), so we need to + // figure out how long the first encoded character is in bytes to distinguish between these + // two errors. We also allow want to allow unicode characters U+0080 through U+00FF, as + // those can fit into a single char value. + if (StringCaster::UTF_N == 8 && str_len > 1 && str_len <= 4) { + auto v0 = static_cast(value[0]); + // low bits only: 0-127 + // 0b110xxxxx - start of 2-byte sequence + // 0b1110xxxx - start of 3-byte sequence + // 0b11110xxx - start of 4-byte sequence + size_t char0_bytes = (v0 & 0x80) == 0 ? 1 + : (v0 & 0xE0) == 0xC0 ? 2 + : (v0 & 0xF0) == 0xE0 ? 3 + : 4; + + if (char0_bytes == str_len) { + // If we have a 128-255 value, we can decode it into a single char: + if (char0_bytes == 2 && (v0 & 0xFC) == 0xC0) { // 0x110000xx 0x10xxxxxx + one_char = static_cast(((v0 & 3) << 6) + + (static_cast(value[1]) & 0x3F)); + return one_char; + } + // Otherwise we have a single character, but it's > U+00FF + throw value_error("Character code point not in range(0x100)"); + } + } + + // UTF-16 is much easier: we can only have a surrogate pair for values above U+FFFF, thus a + // surrogate pair with total length 2 instantly indicates a range error (but not a "your + // string was too long" error). + else if (StringCaster::UTF_N == 16 && str_len == 2) { + one_char = static_cast(value[0]); + if (one_char >= 0xD800 && one_char < 0xE000) { + throw value_error("Character code point not in range(0x10000)"); + } + } + + if (str_len != 1) { + throw value_error("Expected a character, but multi-character string found"); + } + + one_char = value[0]; + return one_char; + } + + static constexpr auto name = const_name(PYBIND11_STRING_NAME); + template + using cast_op_type = pybind11::detail::cast_op_type<_T>; +}; + +// Base implementation for std::tuple and std::pair +template