sa8/zkml-github-repos-truncated · Datasets at Hugging Face

text stringlengths 1 2.05k
use regex::Regex; use std::fs; use std::path::Path;
fn main() { let trait_path = "src/operators/tensor/core.cairo"; let doc_path = "docs/framework/operators/tensor"; let label = "tensor"; let trait_name = "TensorTrait"; doc_trait(trait_path, doc_path, label); doc_functions(trait_path, doc_path, trait_name, label); let trait_path = ...
ble_regressor"; let trait_name: &str = "TreeEnsembleRegressorTrait"; doc_trait(trait_path, doc_path, label); doc_functions(trait_path, doc_path, trait_name, label); let trait_path = "src/operators/ml/linear/linear_regressor.cairo"; let doc_path = "docs/framework/operators/machine-learning/line...
fn doc_trait(trait_path: &str, doc_path: &str, label: &str) { let path_str = format!("../{}", trait_path); let path = Path::new(&path_str); let contents = fs::read_to_string(&path).expect("Could not read the file"); let re = Regex::new(r let mut table = String::from("\| function \| de...
fn doc_functions(trait_path: &str, doc_path: &str, trait_name: &str, label: &str) { let filepath_str = format!("../{}", trait_path); let filepath = Path::new(&filepath_str); let contents = fs::read_to_string(filepath).expect("Something went wrong reading the file"); let trait_re = Regex::new(&form...
import os from pathlib
import Path BASE_PATH = "./tests/nodes" class ModFile: def __init__(self): """ Initialize a ModFile object. This method creates a new file with a .cairo extension in the BASE_PATH directory. If the directory doesn't exist, it's created. The contents of the file are then read ...
class CairoTest(File): def __init__(self, file: str): super().__init__(os.path.join(BASE_PATH, file)) @classmethod def base_template( cls, name: str, arg_cnt: int, refs: list[str], func_sig: str, out_cnt: int = 1 ) -> list[str]: """ Create a template for a Cairo test fun...
Cairo test function which expects a tensor sequence. Args: name (str): Name of the test function. arg_cnt (int): Number of arguments for the function. refs (list[str]): List of references (modules) to be used in the function. func_sig (str): The function signatur...
class CairoData(File): def __init__(self, file: str): super().__init__(os.path.join(BASE_PATH, file)) @classmethod def base_template( cls, func: str, dtype: str, refs: list[str], data: list[str], shape: tuple ) -> list[str]: """ Create a base template for data representa...
Returns: list[str]: A list of strings that together form the template of a sequence tensor function in Cairo. This method generates a list of strings representing a function in Cairo for handling a sequence of tensors, each with its own data and shape. """ def expand_sequen...
from enum
import Enum
import os from typing
import List from .file_manager
import CairoTest, CairoData, ModFile
import numpy as np
class FixedImpl(Enum): FP8x23 = 'FP8x23' FP16x16 = 'FP16x16' FP32x32 = 'FP32x32' def to_fp(x: np.ndarray, fp_impl: FixedImpl): match fp_impl: case FixedImpl.FP8x23: return (x * 2*23).astype(np.int64) case FixedImpl.FP16x16: return (x 2**16).astype(np.int...
class Dtype(Enum): FP8x23 = 'FP8x23' FP16x16 = 'FP16x16' FP32x32 = 'FP32x32' I8 = 'i8' I32 = 'i32' U32 = 'u32' BOOL = 'bool' COMPLEX64 = 'complex64' class Tensor: def __init__(self, dtype: Dtype, shape: tuple, data: np.ndarray): self.dtype = dtype self.shape = shape...
class Trait(Enum): TENSOR = 'TENSOR' NN = 'NN' SEQUENCE = 'SEQUENCE' def make_test(inputs: list[Tensor \| Sequence], output: Tensor \| Sequence, func_sig: str, name: str, trait: Trait = Trait.TENSOR): """ Generate and write Cairo tests based on the provided inputs and output. Args: inpu...
x.shape for x in output], ) output_data.dump() case tuple(): for i, out in enumerate(output): output_data = CairoData( os.path.join(name, f"output_{i}.cairo")) output_data.buffer = CairoData.base_template( ...
ef[Trait.TENSOR], dtype_to_tensor[dtype], dtype_to_numbers[dtype], ] return refs def get_data_statement(data: np.ndarray, dtype: Dtype) -> list[str]: match dtype: case Dtype.U32: return [f"{int(x)}" for x in data.flatten()] case Dtype.I32: return ...
"orion::utils::{assert_eq, assert_seq_eq}", ] return refs def find_all_types(tensors: list[Tensor \| Sequence]) -> list[Dtype]: dtypes = [] for tensor in tensors: if isinstance(tensor, list) or isinstance(tensor, tuple): dtypes += [x.dtype for x in tensor] else: ...
ators::tensor::U32TensorPartialEq",], Dtype.I32: ["orion::operators::tensor::I32TensorPartialEq",], Dtype.I8: ["orion::operators::tensor::I8TensorPartialEq",], Dtype.FP8x23: ["orion::operators::tensor::FP8x23TensorPartialEq",], Dtype.FP16x16: ["orion::operators::tensor::FP16x16TensorPartialEq",], Dt...
import argparse import importlib import os import sys class RunAll: @classmethod def run_all(cls): for method_name in dir(cls): if method_name.startswith('__') or method_name == 'run_all': continue method = getattr(cls, method_name) if callable(metho...
import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Abs(RunAll): @staticmethod def abs_i32(): x = np.random.randint(-127, 127, (2, 2)).astype(np.int32) y = abs(x) x = Tensor(Dtype.I32, x.shape, x.flatten()) ...
import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Acos(RunAll): @staticmethod def acos_fp8x23(): x = np.random.uniform(-1, 1, (2, 2)).astype(np.float64) y = np.arccos(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(...
import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Acosh(RunAll): @staticmethod def acosh_fp8x23(): x = np.random.uniform(1, 5, (2, 2)).astype(np.float64) y = np.arccosh(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp( ...
import numpy as np from nodegen.node
import RunAll from ..helpers
import make_test, to_fp, Tensor, Dtype, FixedImpl
class Add(RunAll): @staticmethod def add_u32(): def default(): x = np.random.randint(0, 3, (3, 3, 3)).astype(np.uint32) y = np.random.randint(0, 3, (3, 3, 3)).astype(np.uint32) z = x + y x = Tensor(Dtype.U32, x.shape, x.flatten()) y = Tensor(D...
dom.randint(-3, 3, (3, 3, 3)).astype(np.int8) y = np.random.randint(-3, 3, (3, 3, 3)).astype(np.int8) z = x + y x = Tensor(Dtype.I8, x.shape, x.flatten()) y = Tensor(Dtype.I8, y.shape, y.flatten()) z = Tensor(Dtype.I8, z.shape, z.flatten()) name ...
make_test([x, y], z, "input_0 + input_1", name) default() broadcast() @staticmethod def add_fp16x16(): def default(): x = np.random.randint(-3, 3, (3, 3, 3)).astype(np.float64) y = np.random.randint(-3, 3, (3, 3, 3)).astype(np.float64) z = x + y ...
import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class And(RunAll): @staticmethod def and_bool(): def default(): x = (np.random.randn(3, 4) > 0).astype(bool) y = (np.random.randn(3, 4) > 0).astype(bool) ...
import numpy as np from nodegen.node
import RunAll from ..helpers
import make_test, to_fp, Tensor, Dtype, FixedImpl def argmax_use_numpy(data: np.ndarray, axis: int = 0, keepdims: int = 1) -> np.ndarray: result = np.argmax(data, axis=axis) if keepdims == 1: result = np.expand_dims(result, axis) return result.astype(np.int64) def argmax_use_numpy_select_last_in...
class Argmax(RunAll): @staticmethod def no_keepdims(): data = np.array([[2, 1], [3, 10]], dtype=np.float32) axis = 1 keepdims = 0 result = argmax_use_numpy(data, axis=axis, keepdims=keepdims) x = Tensor(Dtype.FP16x16, data.shape, data.flatten()) y = Tensor(Dtype...
e=np.float32) axis = 1 keepdims = 0 result = argmax_use_numpy_select_last_index( data, axis=axis, keepdims=keepdims) x = Tensor(Dtype.FP16x16, data.shape, data.flatten()) y = Tensor(Dtype.I32, result.shape, result.flatten()) name = "argmax_no_keepdims_select...
rue))", name)
import numpy as np from nodegen.node
import RunAll from ..helpers
import make_test, to_fp, Tensor, Dtype, FixedImpl def argmin_use_numpy(data: np.ndarray, axis: int = 0, keepdims: int = 1, dtype=np.int64) -> np.ndarray: result = np.argmin(data, axis=axis) if keepdims == 1: result = np.expand_dims(result, axis) return result.astype(dtype) def argmin_use_numpy_s...
class Argmin(RunAll): @staticmethod def argmin_u32(): def argmin_1D(): def default_params(): x = np.random.randint(0, 255, (3)).astype(np.uint32) y = argmin_use_numpy(x, dtype=np.uint32).reshape((1)) x = Tensor(Dtype.U32, x.shape, x.flatten()...
[x], y, "input_0.argmin(0, Option::None(()), Option::None(()))", name) def keepdims_false(): x = np.random.randint(0, 255, (2, 2)).astype(np.uint32) y = argmin_use_numpy( x, keepdims=0, dtype=np.uint32) x = Tensor(Dtype.U32, x.shape, x.fl...
e_test( [x], y, "input_0.argmin(0, Option::Some(false), Option::None(()))", name) def last_index(): x = np.random.randint(0, 255, (2, 2, 2)).astype(np.uint32) y = argmin_use_numpy_select_last_index( x, dtype=np.uint32) ...
, y.flatten()) name = "argmin_i32_1D_last_index" make_test( [x], y, "input_0.argmin(0, Option::None(()), Option::Some(true))", name) default_params() keepdims_false() last_index() argmin_1D() def argmin_2D(): ...
nt32) x = Tensor(Dtype.I32, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_i32_3D_default" make_test( [x], y, "input_0.argmin(0, Option::None(()), Option::None(()))", name) def keepdims_f...
use_numpy( x, keepdims=0, dtype=np.uint32).reshape((1)) x = Tensor(Dtype.I8, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_i8_1D_keepdims_false" make_test( [x], y, "input_0.argmin...
y = argmin_use_numpy_select_last_index( x, dtype=np.int8) x = Tensor(Dtype.I8, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_i8_2D_last_index" make_test( [x], y, "input_0.argmin(0...
n_3D() @staticmethod def argmin_fp16x16(): def argmin_1D(): def default_params(): x = to_fp(np.random.randint(-127, 127, (3) ).astype(np.int8), FixedImpl.FP16x16) y = argmin_use_numpy(x, dtype=np.uint32).reshape((1)...
dImpl.FP16x16) y = argmin_use_numpy(x, dtype=np.uint32) x = Tensor(Dtype.FP16x16, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_fp16x16_2D_default" make_test( [x], y, "input_0.argmin(...
fault" make_test( [x], y, "input_0.argmin(0, Option::None(()), Option::None(()))", name) def keepdims_false(): x = to_fp(np.random.randint(-127, 127, (2, 2, 2) ).astype(np.int8), FixedImpl.FP16x16) ...
x = to_fp(np.random.randint(-127, 127, (3) ).astype(np.int8), FixedImpl.FP8x23) y = argmin_use_numpy( x, keepdims=0, dtype=np.uint32).reshape((1)) x = Tensor(Dtype.FP8x23, x.shape, x.flatten()) ...
eepdims=0, dtype=np.uint32) x = Tensor(Dtype.FP8x23, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_fp8x23_2D_keepdims_false" make_test( [x], y, "input_0.argmin(0, Option::S...
.flatten()) name = "argmin_fp8x23_3D_keepdims_false" make_test( [x], y, "input_0.argmin(0, Option::Some(false), Option::None(()))", name) def last_index(): x = to_fp(np.random.randint(-127, 127, (2, 2, 2) ...
import numpy as np from nodegen.node
import RunAll from ..helpers
import make_test, to_fp, Tensor, Dtype, FixedImpl
class Array_feature_extractor(RunAll): @staticmethod def array_feature_extractor_3D(): def array_feature_extractor_i32(): x = np.random.randint(-3, 3, (2, 3, 4)).astype(np.int32) y = np.array([1, 3]).astype(np.uint32) z = (x[..., y]) x = Tensor(Dtype.I32...
def array_feature_extractor_i32(): x = np.random.randint(-3, 3, (3, 4)).astype(np.int32) y = np.array([1, 3]).astype(np.uint32) z = (x[..., y]) x = Tensor(Dtype.I32, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) z = Tensor(Dtyp...
stype(np.int32) y = np.array([1, 3]).astype(np.uint32) z = (x[..., y]) x = Tensor(Dtype.I32, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) z = Tensor(Dtype.I32, z.shape, z.flatten()) name = "array_feature_extractor_1D_i32" ...
import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Asin(RunAll): @staticmethod def asin_fp8x23(): x = np.random.uniform(-1, 1, (2, 2)).astype(np.float64) y = np.arcsin(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(...
import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Asinh(RunAll): @staticmethod def asinh_fp8x23(): x = np.random.uniform(1, 5, (2, 2)).astype(np.float64) y = np.arcsinh(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(...
import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Atan(RunAll): @staticmethod def atan_fp8x23(): x = np.random.uniform(-10, 127, (2, 2)).astype(np.float64) y = np.arctan(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(...
import numpy as np from nodegen.node import RunAll from ..helpers import make_node, make_test, to_fp, Tensor, Dtype, FixedImpl class Binarizer(RunAll): @staticmethod def binarizer_fp8x23(): x = np.random.uniform(-3, 3, (3, 3, 3)).astype(np.float64) threshold = np.float64(1) y = (x > t...
import numpy as np from nodegen.node
import RunAll from ..helpers
import make_test, to_fp, Tensor, Dtype, FixedImpl, Trait, get_data_statement def blackman_window(size, output_datatype=None, periodic=None) -> np.ndarray: if periodic == 1: N_1 = size else: N_1 = size - 1 ni = np.arange(size, dtype=output_datatype) alpha = 0.42 beta = 0.08 y =...
class Blackman_window(RunAll): @staticmethod def fp8x23(): args = [3] args_str = get_data_statement(to_fp(np.array(args).flatten(), FixedImpl.FP8x23), Dtype.FP8x23) y = blackman_window(*args, np.float64) y = Tensor(Dtype.FP8x23, y.shape, to_f...
import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Ceil(RunAll): @staticmethod def ceil_fp8x23(): x = np.random.uniform(-1, 1, (2, 2)).astype(np.float64) y = np.ceil(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(x....
import numpy as np from nodegen.node
import RunAll from ..helpers
import make_test, to_fp, Tensor, Dtype, FixedImpl
class Clip(RunAll): @staticmethod def clip_u32(): def clip_2D(): x = np.random.randint(0, 255, (2, 4)).astype(np.uint32) y = np.clip(x, np.uint32(10), np.uint32(20)) x = Tensor(Dtype.U32, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) ...
.flatten()) y = Tensor(Dtype.I8, y.shape, y.flatten()) name = "clip_i8_2d" make_test( [x], y, "input_0.clip(Option::Some(-10_i8), Option::Some(20_i8))", name) def clip_3D(): x = np.random.randint(-127, 127, (20, 10, 5)).astype(np.int8) ...
.random.randint(-127, 127, (2, 4) ).astype(np.int64), FixedImpl.FP16x16) y = np.clip(x, to_fp(np.int64(-10), FixedImpl.FP16x16), to_fp(np.int64(20), FixedImpl.FP16x16)) x = Tensor(Dtype.FP16x16, x.shape, x.flatten()) y = Tensor(Dtype.FP16x16, ...
import numpy as np from nodegen.node
import RunAll from ..helpers
import make_test, to_fp, Tensor, Dtype, FixedImpl, Trait def col2im(data, image_shape, block_shape, dilations=None, pads=None, strides=None): if dilations is None: dilations = [1 for s in image_shape] if pads is None: pads = [0 for s in image_shape] * 2 if strides is None: stride...
!= block_size: raise ValueError( f"Given n_input_plane={n_input_plane}, X.shape={X.shape}, " f"output_shape={output_shape}, kernel_shape={kernel_shape}, " f"dilations={dilations}, pads={pads}, strides={strides}, " f"expected size of input's dimension 2 to match th...
class Col2im(RunAll): @staticmethod def export_col2im() -> None: x = np.array( [ [ [1.0, 6.0, 11.0, 16.0, 21.0], [2.0, 7.0, 12.0, 17.0, 22.0], [3.0, 8.0, 13.0, 18.0, 23.0], [4.0, 9.0, 14.0, 19....
y.flatten(), FixedImpl.FP16x16)) name = "col2im_strides" func_sig = "NNTrait::col2im(" func_sig += "@input_0," func_sig += "array![5, 5].span()," func_sig += "array![3, 3].span()," func_sig += "Option::None," func_sig += "Option::None," func_sig += "Optio...
ticmethod def export_col2im_dilations() -> None: x = np.array( [ [ [1.0, 5.0, 9.0, 13.0, 17], [2.0, 6.0, 10.0, 14.0, 18], [3.0, 7.0, 11.0, 15.0, 19], [4.0, 8.0, 12.0, 16.0, 20], ] ...
).astype(np.int64) block_shape = np.array([1, 1, 5]).astype(np.int64) y = col2im(x,image_shape,block_shape) y = np.array(y[0]) x = Tensor(Dtype.FP16x16, x.shape, to_fp(x.flatten(), FixedImpl.FP16x16)) y = Tensor(Dtype.FP16x16, y.shape, to_fp(y.flatten(), FixedImpl.FP16x16))...
import numpy as np from nodegen.node
import RunAll from ..helpers
import make_test, to_fp, Tensor, Dtype, FixedImpl, Trait
class Compress(RunAll): @staticmethod def compress_fp16x16(): def compress_3D(): def default(): x1 = np.arange(0,27).reshape(3,3,3).astype(np.int64) x2 = np.array([0, 1, 1]).astype(np.uint32) y = x1.compress(x2, axis=0) ...
_fp16x16_3d_axis2" make_test( inputs = [x1, x2], output = y, func_sig = "input_0.compress(condition:input_1, axis:Option::Some(2))", name= name) def axis3(): x1 = np.arange(0,96).reshape(4,3,4, 2).astype(np.int64) ...
.compress(x2, axis=0) x1 = Tensor(Dtype.FP8x23, x1.shape, to_fp(x1.flatten(), FixedImpl.FP8x23)) x2 = Tensor(Dtype.U32, x2.shape, x2.flatten()) y = Tensor(Dtype.FP8x23, y.shape, to_fp(y.flatten(), FixedImpl.FP8x23)) name = "compress_fp8x23_3d_default" ...
def compress_3D(): def default(): x1 = np.arange(0,27).reshape(3,3,3).astype(np.int8) x2 = np.array([0, 1, 1]).astype(np.uint8) y = x1.compress(x2, axis=0) x1 = Tensor(Dtype.I8, x1.shape, x1.flatten()) x2 = Tensor(Dtype.U32, x...
: def compress_3D(): def default(): x1 = np.arange(0,27).reshape(3,3,3).astype(np.int32) x2 = np.array([0, 1, 1]).astype(np.int32) y = x1.compress(x2, axis=0) x1 = Tensor(Dtype.I32, x1.shape, x1.flatten()) ...
hod def compress_u32(): def compress_3D(): def default(): x1 = np.arange(0,48).reshape(4,4,3).astype(np.uint32) x2 = np.array([1, 1]).astype(np.uint32) y = x1.compress(x2, axis=0) x1 = Tensor(Dtype.U32, x1.shape, x1.f...
e(3,4,5).astype(np.uint32) x2 = np.array([0, 1, 1]).astype(np.uint32) y = x1.compress(x2, axis=2) x1 = Tensor(Dtype.U32, x1.shape, x1.flatten()) x2 = Tensor(Dtype.U32, x2.shape, x2.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) ...
import numpy as np from nodegen.node
import RunAll from ..helpers
import make_test, to_fp, Tensor, Dtype, FixedImpl, Trait
class Concat(RunAll): @staticmethod def concat_u32(): def concat_1D(): x1 = np.arange(0,3).astype(np.uint32) x2 = np.arange(3,6).astype(np.uint32) y = np.concatenate((x1, x2)) x1 = Tensor(Dtype.U32, x1.shape, x1.flatten()) x2 = Tensor(Dtype.U...

use regex::Regex; use std::fs; use std::path::Path;

fn main() { let trait_path = "src/operators/tensor/core.cairo"; let doc_path = "docs/framework/operators/tensor"; let label = "tensor"; let trait_name = "TensorTrait"; doc_trait(trait_path, doc_path, label); doc_functions(trait_path, doc_path, trait_name, label); let trait_path = ...

ble_regressor"; let trait_name: &str = "TreeEnsembleRegressorTrait"; doc_trait(trait_path, doc_path, label); doc_functions(trait_path, doc_path, trait_name, label); let trait_path = "src/operators/ml/linear/linear_regressor.cairo"; let doc_path = "docs/framework/operators/machine-learning/line...

fn doc_trait(trait_path: &str, doc_path: &str, label: &str) { let path_str = format!("../{}", trait_path); let path = Path::new(&path_str); let contents = fs::read_to_string(&path).expect("Could not read the file"); let re = Regex::new(r let mut table = String::from("| function | de...

fn doc_functions(trait_path: &str, doc_path: &str, trait_name: &str, label: &str) { let filepath_str = format!("../{}", trait_path); let filepath = Path::new(&filepath_str); let contents = fs::read_to_string(filepath).expect("Something went wrong reading the file"); let trait_re = Regex::new(&form...

import os from pathlib

import Path BASE_PATH = "./tests/nodes" class ModFile: def __init__(self): """ Initialize a ModFile object. This method creates a new file with a .cairo extension in the BASE_PATH directory. If the directory doesn't exist, it's created. The contents of the file are then read ...

class CairoTest(File): def __init__(self, file: str): super().__init__(os.path.join(BASE_PATH, file)) @classmethod def base_template( cls, name: str, arg_cnt: int, refs: list[str], func_sig: str, out_cnt: int = 1 ) -> list[str]: """ Create a template for a Cairo test fun...

Cairo test function which expects a tensor sequence. Args: name (str): Name of the test function. arg_cnt (int): Number of arguments for the function. refs (list[str]): List of references (modules) to be used in the function. func_sig (str): The function signatur...

class CairoData(File): def __init__(self, file: str): super().__init__(os.path.join(BASE_PATH, file)) @classmethod def base_template( cls, func: str, dtype: str, refs: list[str], data: list[str], shape: tuple ) -> list[str]: """ Create a base template for data representa...

Returns: list[str]: A list of strings that together form the template of a sequence tensor function in Cairo. This method generates a list of strings representing a function in Cairo for handling a sequence of tensors, each with its own data and shape. """ def expand_sequen...

from enum

import Enum

import os from typing

import List from .file_manager

import CairoTest, CairoData, ModFile

import numpy as np

class FixedImpl(Enum): FP8x23 = 'FP8x23' FP16x16 = 'FP16x16' FP32x32 = 'FP32x32' def to_fp(x: np.ndarray, fp_impl: FixedImpl): match fp_impl: case FixedImpl.FP8x23: return (x * 2**23).astype(np.int64) case FixedImpl.FP16x16: return (x * 2**16).astype(np.int...

class Dtype(Enum): FP8x23 = 'FP8x23' FP16x16 = 'FP16x16' FP32x32 = 'FP32x32' I8 = 'i8' I32 = 'i32' U32 = 'u32' BOOL = 'bool' COMPLEX64 = 'complex64' class Tensor: def __init__(self, dtype: Dtype, shape: tuple, data: np.ndarray): self.dtype = dtype self.shape = shape...

class Trait(Enum): TENSOR = 'TENSOR' NN = 'NN' SEQUENCE = 'SEQUENCE' def make_test(inputs: list[Tensor | Sequence], output: Tensor | Sequence, func_sig: str, name: str, trait: Trait = Trait.TENSOR): """ Generate and write Cairo tests based on the provided inputs and output. Args: inpu...

x.shape for x in output], ) output_data.dump() case tuple(): for i, out in enumerate(output): output_data = CairoData( os.path.join(name, f"output_{i}.cairo")) output_data.buffer = CairoData.base_template( ...

ef[Trait.TENSOR], *dtype_to_tensor[dtype], *dtype_to_numbers[dtype], ] return refs def get_data_statement(data: np.ndarray, dtype: Dtype) -> list[str]: match dtype: case Dtype.U32: return [f"{int(x)}" for x in data.flatten()] case Dtype.I32: return ...

"orion::utils::{assert_eq, assert_seq_eq}", ] return refs def find_all_types(tensors: list[Tensor | Sequence]) -> list[Dtype]: dtypes = [] for tensor in tensors: if isinstance(tensor, list) or isinstance(tensor, tuple): dtypes += [x.dtype for x in tensor] else: ...

ators::tensor::U32TensorPartialEq",], Dtype.I32: ["orion::operators::tensor::I32TensorPartialEq",], Dtype.I8: ["orion::operators::tensor::I8TensorPartialEq",], Dtype.FP8x23: ["orion::operators::tensor::FP8x23TensorPartialEq",], Dtype.FP16x16: ["orion::operators::tensor::FP16x16TensorPartialEq",], Dt...

import argparse import importlib import os import sys class RunAll: @classmethod def run_all(cls): for method_name in dir(cls): if method_name.startswith('__') or method_name == 'run_all': continue method = getattr(cls, method_name) if callable(metho...

import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Abs(RunAll): @staticmethod def abs_i32(): x = np.random.randint(-127, 127, (2, 2)).astype(np.int32) y = abs(x) x = Tensor(Dtype.I32, x.shape, x.flatten()) ...

import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Acos(RunAll): @staticmethod def acos_fp8x23(): x = np.random.uniform(-1, 1, (2, 2)).astype(np.float64) y = np.arccos(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(...

import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Acosh(RunAll): @staticmethod def acosh_fp8x23(): x = np.random.uniform(1, 5, (2, 2)).astype(np.float64) y = np.arccosh(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp( ...

import numpy as np from nodegen.node

import RunAll from ..helpers

import make_test, to_fp, Tensor, Dtype, FixedImpl

class Add(RunAll): @staticmethod def add_u32(): def default(): x = np.random.randint(0, 3, (3, 3, 3)).astype(np.uint32) y = np.random.randint(0, 3, (3, 3, 3)).astype(np.uint32) z = x + y x = Tensor(Dtype.U32, x.shape, x.flatten()) y = Tensor(D...

dom.randint(-3, 3, (3, 3, 3)).astype(np.int8) y = np.random.randint(-3, 3, (3, 3, 3)).astype(np.int8) z = x + y x = Tensor(Dtype.I8, x.shape, x.flatten()) y = Tensor(Dtype.I8, y.shape, y.flatten()) z = Tensor(Dtype.I8, z.shape, z.flatten()) name ...

make_test([x, y], z, "input_0 + input_1", name) default() broadcast() @staticmethod def add_fp16x16(): def default(): x = np.random.randint(-3, 3, (3, 3, 3)).astype(np.float64) y = np.random.randint(-3, 3, (3, 3, 3)).astype(np.float64) z = x + y ...

import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class And(RunAll): @staticmethod def and_bool(): def default(): x = (np.random.randn(3, 4) > 0).astype(bool) y = (np.random.randn(3, 4) > 0).astype(bool) ...

import numpy as np from nodegen.node

import RunAll from ..helpers

import make_test, to_fp, Tensor, Dtype, FixedImpl def argmax_use_numpy(data: np.ndarray, axis: int = 0, keepdims: int = 1) -> np.ndarray: result = np.argmax(data, axis=axis) if keepdims == 1: result = np.expand_dims(result, axis) return result.astype(np.int64) def argmax_use_numpy_select_last_in...

class Argmax(RunAll): @staticmethod def no_keepdims(): data = np.array([[2, 1], [3, 10]], dtype=np.float32) axis = 1 keepdims = 0 result = argmax_use_numpy(data, axis=axis, keepdims=keepdims) x = Tensor(Dtype.FP16x16, data.shape, data.flatten()) y = Tensor(Dtype...

e=np.float32) axis = 1 keepdims = 0 result = argmax_use_numpy_select_last_index( data, axis=axis, keepdims=keepdims) x = Tensor(Dtype.FP16x16, data.shape, data.flatten()) y = Tensor(Dtype.I32, result.shape, result.flatten()) name = "argmax_no_keepdims_select...

rue))", name)

import numpy as np from nodegen.node

import RunAll from ..helpers

import make_test, to_fp, Tensor, Dtype, FixedImpl def argmin_use_numpy(data: np.ndarray, axis: int = 0, keepdims: int = 1, dtype=np.int64) -> np.ndarray: result = np.argmin(data, axis=axis) if keepdims == 1: result = np.expand_dims(result, axis) return result.astype(dtype) def argmin_use_numpy_s...

class Argmin(RunAll): @staticmethod def argmin_u32(): def argmin_1D(): def default_params(): x = np.random.randint(0, 255, (3)).astype(np.uint32) y = argmin_use_numpy(x, dtype=np.uint32).reshape((1)) x = Tensor(Dtype.U32, x.shape, x.flatten()...

[x], y, "input_0.argmin(0, Option::None(()), Option::None(()))", name) def keepdims_false(): x = np.random.randint(0, 255, (2, 2)).astype(np.uint32) y = argmin_use_numpy( x, keepdims=0, dtype=np.uint32) x = Tensor(Dtype.U32, x.shape, x.fl...

e_test( [x], y, "input_0.argmin(0, Option::Some(false), Option::None(()))", name) def last_index(): x = np.random.randint(0, 255, (2, 2, 2)).astype(np.uint32) y = argmin_use_numpy_select_last_index( x, dtype=np.uint32) ...

, y.flatten()) name = "argmin_i32_1D_last_index" make_test( [x], y, "input_0.argmin(0, Option::None(()), Option::Some(true))", name) default_params() keepdims_false() last_index() argmin_1D() def argmin_2D(): ...

nt32) x = Tensor(Dtype.I32, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_i32_3D_default" make_test( [x], y, "input_0.argmin(0, Option::None(()), Option::None(()))", name) def keepdims_f...

use_numpy( x, keepdims=0, dtype=np.uint32).reshape((1)) x = Tensor(Dtype.I8, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_i8_1D_keepdims_false" make_test( [x], y, "input_0.argmin...

y = argmin_use_numpy_select_last_index( x, dtype=np.int8) x = Tensor(Dtype.I8, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_i8_2D_last_index" make_test( [x], y, "input_0.argmin(0...

n_3D() @staticmethod def argmin_fp16x16(): def argmin_1D(): def default_params(): x = to_fp(np.random.randint(-127, 127, (3) ).astype(np.int8), FixedImpl.FP16x16) y = argmin_use_numpy(x, dtype=np.uint32).reshape((1)...

dImpl.FP16x16) y = argmin_use_numpy(x, dtype=np.uint32) x = Tensor(Dtype.FP16x16, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_fp16x16_2D_default" make_test( [x], y, "input_0.argmin(...

fault" make_test( [x], y, "input_0.argmin(0, Option::None(()), Option::None(()))", name) def keepdims_false(): x = to_fp(np.random.randint(-127, 127, (2, 2, 2) ).astype(np.int8), FixedImpl.FP16x16) ...

x = to_fp(np.random.randint(-127, 127, (3) ).astype(np.int8), FixedImpl.FP8x23) y = argmin_use_numpy( x, keepdims=0, dtype=np.uint32).reshape((1)) x = Tensor(Dtype.FP8x23, x.shape, x.flatten()) ...

eepdims=0, dtype=np.uint32) x = Tensor(Dtype.FP8x23, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) name = "argmin_fp8x23_2D_keepdims_false" make_test( [x], y, "input_0.argmin(0, Option::S...

.flatten()) name = "argmin_fp8x23_3D_keepdims_false" make_test( [x], y, "input_0.argmin(0, Option::Some(false), Option::None(()))", name) def last_index(): x = to_fp(np.random.randint(-127, 127, (2, 2, 2) ...

import numpy as np from nodegen.node

import RunAll from ..helpers

import make_test, to_fp, Tensor, Dtype, FixedImpl

class Array_feature_extractor(RunAll): @staticmethod def array_feature_extractor_3D(): def array_feature_extractor_i32(): x = np.random.randint(-3, 3, (2, 3, 4)).astype(np.int32) y = np.array([1, 3]).astype(np.uint32) z = (x[..., y]) x = Tensor(Dtype.I32...

def array_feature_extractor_i32(): x = np.random.randint(-3, 3, (3, 4)).astype(np.int32) y = np.array([1, 3]).astype(np.uint32) z = (x[..., y]) x = Tensor(Dtype.I32, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) z = Tensor(Dtyp...

stype(np.int32) y = np.array([1, 3]).astype(np.uint32) z = (x[..., y]) x = Tensor(Dtype.I32, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) z = Tensor(Dtype.I32, z.shape, z.flatten()) name = "array_feature_extractor_1D_i32" ...

import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Asin(RunAll): @staticmethod def asin_fp8x23(): x = np.random.uniform(-1, 1, (2, 2)).astype(np.float64) y = np.arcsin(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(...

import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Asinh(RunAll): @staticmethod def asinh_fp8x23(): x = np.random.uniform(1, 5, (2, 2)).astype(np.float64) y = np.arcsinh(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(...

import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Atan(RunAll): @staticmethod def atan_fp8x23(): x = np.random.uniform(-10, 127, (2, 2)).astype(np.float64) y = np.arctan(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(...

import numpy as np from nodegen.node import RunAll from ..helpers import make_node, make_test, to_fp, Tensor, Dtype, FixedImpl class Binarizer(RunAll): @staticmethod def binarizer_fp8x23(): x = np.random.uniform(-3, 3, (3, 3, 3)).astype(np.float64) threshold = np.float64(1) y = (x > t...

import numpy as np from nodegen.node

import RunAll from ..helpers

import make_test, to_fp, Tensor, Dtype, FixedImpl, Trait, get_data_statement def blackman_window(size, output_datatype=None, periodic=None) -> np.ndarray: if periodic == 1: N_1 = size else: N_1 = size - 1 ni = np.arange(size, dtype=output_datatype) alpha = 0.42 beta = 0.08 y =...

class Blackman_window(RunAll): @staticmethod def fp8x23(): args = [3] args_str = get_data_statement(to_fp(np.array(args).flatten(), FixedImpl.FP8x23), Dtype.FP8x23) y = blackman_window(*args, np.float64) y = Tensor(Dtype.FP8x23, y.shape, to_f...

import numpy as np from nodegen.node import RunAll from ..helpers import make_test, to_fp, Tensor, Dtype, FixedImpl class Ceil(RunAll): @staticmethod def ceil_fp8x23(): x = np.random.uniform(-1, 1, (2, 2)).astype(np.float64) y = np.ceil(x) x = Tensor(Dtype.FP8x23, x.shape, to_fp(x....

import numpy as np from nodegen.node

import RunAll from ..helpers

import make_test, to_fp, Tensor, Dtype, FixedImpl

class Clip(RunAll): @staticmethod def clip_u32(): def clip_2D(): x = np.random.randint(0, 255, (2, 4)).astype(np.uint32) y = np.clip(x, np.uint32(10), np.uint32(20)) x = Tensor(Dtype.U32, x.shape, x.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) ...

.flatten()) y = Tensor(Dtype.I8, y.shape, y.flatten()) name = "clip_i8_2d" make_test( [x], y, "input_0.clip(Option::Some(-10_i8), Option::Some(20_i8))", name) def clip_3D(): x = np.random.randint(-127, 127, (20, 10, 5)).astype(np.int8) ...

.random.randint(-127, 127, (2, 4) ).astype(np.int64), FixedImpl.FP16x16) y = np.clip(x, to_fp(np.int64(-10), FixedImpl.FP16x16), to_fp(np.int64(20), FixedImpl.FP16x16)) x = Tensor(Dtype.FP16x16, x.shape, x.flatten()) y = Tensor(Dtype.FP16x16, ...

import numpy as np from nodegen.node

import RunAll from ..helpers

import make_test, to_fp, Tensor, Dtype, FixedImpl, Trait def col2im(data, image_shape, block_shape, dilations=None, pads=None, strides=None): if dilations is None: dilations = [1 for s in image_shape] if pads is None: pads = [0 for s in image_shape] * 2 if strides is None: stride...

!= block_size: raise ValueError( f"Given n_input_plane={n_input_plane}, X.shape={X.shape}, " f"output_shape={output_shape}, kernel_shape={kernel_shape}, " f"dilations={dilations}, pads={pads}, strides={strides}, " f"expected size of input's dimension 2 to match th...

class Col2im(RunAll): @staticmethod def export_col2im() -> None: x = np.array( [ [ [1.0, 6.0, 11.0, 16.0, 21.0], [2.0, 7.0, 12.0, 17.0, 22.0], [3.0, 8.0, 13.0, 18.0, 23.0], [4.0, 9.0, 14.0, 19....

y.flatten(), FixedImpl.FP16x16)) name = "col2im_strides" func_sig = "NNTrait::col2im(" func_sig += "@input_0," func_sig += "array![5, 5].span()," func_sig += "array![3, 3].span()," func_sig += "Option::None," func_sig += "Option::None," func_sig += "Optio...

ticmethod def export_col2im_dilations() -> None: x = np.array( [ [ [1.0, 5.0, 9.0, 13.0, 17], [2.0, 6.0, 10.0, 14.0, 18], [3.0, 7.0, 11.0, 15.0, 19], [4.0, 8.0, 12.0, 16.0, 20], ] ...

).astype(np.int64) block_shape = np.array([1, 1, 5]).astype(np.int64) y = col2im(x,image_shape,block_shape) y = np.array(y[0]) x = Tensor(Dtype.FP16x16, x.shape, to_fp(x.flatten(), FixedImpl.FP16x16)) y = Tensor(Dtype.FP16x16, y.shape, to_fp(y.flatten(), FixedImpl.FP16x16))...

import numpy as np from nodegen.node

import RunAll from ..helpers

import make_test, to_fp, Tensor, Dtype, FixedImpl, Trait

class Compress(RunAll): @staticmethod def compress_fp16x16(): def compress_3D(): def default(): x1 = np.arange(0,27).reshape(3,3,3).astype(np.int64) x2 = np.array([0, 1, 1]).astype(np.uint32) y = x1.compress(x2, axis=0) ...

_fp16x16_3d_axis2" make_test( inputs = [x1, x2], output = y, func_sig = "input_0.compress(condition:input_1, axis:Option::Some(2))", name= name) def axis3(): x1 = np.arange(0,96).reshape(4,3,4, 2).astype(np.int64) ...

.compress(x2, axis=0) x1 = Tensor(Dtype.FP8x23, x1.shape, to_fp(x1.flatten(), FixedImpl.FP8x23)) x2 = Tensor(Dtype.U32, x2.shape, x2.flatten()) y = Tensor(Dtype.FP8x23, y.shape, to_fp(y.flatten(), FixedImpl.FP8x23)) name = "compress_fp8x23_3d_default" ...

def compress_3D(): def default(): x1 = np.arange(0,27).reshape(3,3,3).astype(np.int8) x2 = np.array([0, 1, 1]).astype(np.uint8) y = x1.compress(x2, axis=0) x1 = Tensor(Dtype.I8, x1.shape, x1.flatten()) x2 = Tensor(Dtype.U32, x...

: def compress_3D(): def default(): x1 = np.arange(0,27).reshape(3,3,3).astype(np.int32) x2 = np.array([0, 1, 1]).astype(np.int32) y = x1.compress(x2, axis=0) x1 = Tensor(Dtype.I32, x1.shape, x1.flatten()) ...

hod def compress_u32(): def compress_3D(): def default(): x1 = np.arange(0,48).reshape(4,4,3).astype(np.uint32) x2 = np.array([1, 1]).astype(np.uint32) y = x1.compress(x2, axis=0) x1 = Tensor(Dtype.U32, x1.shape, x1.f...

e(3,4,5).astype(np.uint32) x2 = np.array([0, 1, 1]).astype(np.uint32) y = x1.compress(x2, axis=2) x1 = Tensor(Dtype.U32, x1.shape, x1.flatten()) x2 = Tensor(Dtype.U32, x2.shape, x2.flatten()) y = Tensor(Dtype.U32, y.shape, y.flatten()) ...

import numpy as np from nodegen.node

import RunAll from ..helpers

import make_test, to_fp, Tensor, Dtype, FixedImpl, Trait

class Concat(RunAll): @staticmethod def concat_u32(): def concat_1D(): x1 = np.arange(0,3).astype(np.uint32) x2 = np.arange(3,6).astype(np.uint32) y = np.concatenate((x1, x2)) x1 = Tensor(Dtype.U32, x1.shape, x1.flatten()) x2 = Tensor(Dtype.U...