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	/**
	* MIT License
	*
	* Copyright (c) 2017 Thibaut Goetghebuer-Planchon <tessil@gmx.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.
	*/
	#ifndef TSL_ROBIN_HASH_H
	#define TSL_ROBIN_HASH_H


	#include <algorithm>
	#include <cassert>
	#include <cmath>
	#include <cstddef>
	#include <cstdint>
	#include <exception>
	#include <iterator>
	#include <limits>
	#include <memory>
	#include <stdexcept>
	#include <tuple>
	#include <type_traits>
	#include <utility>
	#include <vector>
	#include "robin_growth_policy.h"


	namespace tsl {

	namespace detail_robin_hash {

	template<typename T>
	struct make_void {
	using type = void;
	};

	template<typename T, typename = void>
	struct has_is_transparent: std::false_type {
	};

	template<typename T>
	struct has_is_transparent<T, typename make_void<typename T::is_transparent>::type>: std::true_type {
	};

	template<typename U>
	struct is_power_of_two_policy: std::false_type {
	};

	template<std::size_t GrowthFactor>
	struct is_power_of_two_policy<tsl::rh::power_of_two_growth_policy<GrowthFactor>>: std::true_type {
	};

	// Only available in C++17, we need to be compatible with C++11
	template<class T>
	const T& clamp( const T& v, const T& lo, const T& hi) {
	return std::min(hi, std::max(lo, v));
	}

	template<typename T, typename U>
	static T numeric_cast(U value, const char* error_message = "numeric_cast() failed.") {
	T ret = static_cast<T>(value);
	if(static_cast<U>(ret) != value) {
	TSL_RH_THROW_OR_TERMINATE(std::runtime_error, error_message);
	}

	const bool is_same_signedness = (std::is_unsigned<T>::value && std::is_unsigned<U>::value) \|\|
	(std::is_signed<T>::value && std::is_signed<U>::value);
	if(!is_same_signedness && (ret < T{}) != (value < U{})) {
	TSL_RH_THROW_OR_TERMINATE(std::runtime_error, error_message);
	}

	return ret;
	}


	using truncated_hash_type = std::uint_least32_t;

	/**
	* Helper class that stores a truncated hash if StoreHash is true and nothing otherwise.
	*/
	template<bool StoreHash>
	class bucket_entry_hash {
	public:
	bool bucket_hash_equal(std::size_t /hash/) const noexcept {
	return true;
	}

	truncated_hash_type truncated_hash() const noexcept {
	return 0;
	}

	protected:
	void set_hash(truncated_hash_type /hash/) noexcept {
	}
	};

	template<>
	class bucket_entry_hash<true> {
	public:
	bool bucket_hash_equal(std::size_t hash) const noexcept {
	return m_hash == truncated_hash_type(hash);
	}

	truncated_hash_type truncated_hash() const noexcept {
	return m_hash;
	}

	protected:
	void set_hash(truncated_hash_type hash) noexcept {
	m_hash = truncated_hash_type(hash);
	}

	private:
	truncated_hash_type m_hash;
	};


	/**
	* Each bucket entry has:
	* - A value of type `ValueType`.
	* - An integer to store how far the value of the bucket, if any, is from its ideal bucket
	* (ex: if the current bucket 5 has the value 'foo' and `hash('foo') % nb_buckets` == 3,
	* `dist_from_ideal_bucket()` will return 2 as the current value of the bucket is two
	* buckets away from its ideal bucket)
	* If there is no value in the bucket (i.e. `empty()` is true) `dist_from_ideal_bucket()` will be < 0.
	* - A marker which tells us if the bucket is the last bucket of the bucket array (useful for the
	* iterator of the hash table).
	* - If `StoreHash` is true, 32 bits of the hash of the value, if any, are also stored in the bucket.
	* If the size of the hash is more than 32 bits, it is truncated. We don't store the full hash
	* as storing the hash is a potential opportunity to use the unused space due to the alignment
	* of the bucket_entry structure. We can thus potentially store the hash without any extra space
	* (which would not be possible with 64 bits of the hash).
	*/
	template<typename ValueType, bool StoreHash>
	class bucket_entry: public bucket_entry_hash<StoreHash> {
	using bucket_hash = bucket_entry_hash<StoreHash>;

	public:
	using value_type = ValueType;
	using distance_type = std::int_least16_t;


	bucket_entry() noexcept: bucket_hash(), m_dist_from_ideal_bucket(EMPTY_MARKER_DIST_FROM_IDEAL_BUCKET),
	m_last_bucket(false)
	{
	tsl_rh_assert(empty());
	}

	bucket_entry(bool last_bucket) noexcept: bucket_hash(), m_dist_from_ideal_bucket(EMPTY_MARKER_DIST_FROM_IDEAL_BUCKET),
	m_last_bucket(last_bucket)
	{
	tsl_rh_assert(empty());
	}

	bucket_entry(const bucket_entry& other) noexcept(std::is_nothrow_copy_constructible<value_type>::value):
	bucket_hash(other),
	m_dist_from_ideal_bucket(EMPTY_MARKER_DIST_FROM_IDEAL_BUCKET),
	m_last_bucket(other.m_last_bucket)
	{
	if(!other.empty()) {
	::new (static_cast<void*>(std::addressof(m_value))) value_type(other.value());
	m_dist_from_ideal_bucket = other.m_dist_from_ideal_bucket;
	}
	}

	/**
	* Never really used, but still necessary as we must call resize on an empty `std::vector<bucket_entry>`.
	* and we need to support move-only types. See robin_hash constructor for details.
	*/
	bucket_entry(bucket_entry&& other) noexcept(std::is_nothrow_move_constructible<value_type>::value):
	bucket_hash(std::move(other)),
	m_dist_from_ideal_bucket(EMPTY_MARKER_DIST_FROM_IDEAL_BUCKET),
	m_last_bucket(other.m_last_bucket)
	{
	if(!other.empty()) {
	::new (static_cast<void*>(std::addressof(m_value))) value_type(std::move(other.value()));
	m_dist_from_ideal_bucket = other.m_dist_from_ideal_bucket;
	}
	}

	bucket_entry& operator=(const bucket_entry& other)
	noexcept(std::is_nothrow_copy_constructible<value_type>::value)
	{
	if(this != &other) {
	clear();

	bucket_hash::operator=(other);
	if(!other.empty()) {
	::new (static_cast<void*>(std::addressof(m_value))) value_type(other.value());
	}

	m_dist_from_ideal_bucket = other.m_dist_from_ideal_bucket;
	m_last_bucket = other.m_last_bucket;
	}

	return *this;
	}

	bucket_entry& operator=(bucket_entry&& ) = delete;

	~bucket_entry() noexcept {
	clear();
	}

	void clear() noexcept {
	if(!empty()) {
	destroy_value();
	m_dist_from_ideal_bucket = EMPTY_MARKER_DIST_FROM_IDEAL_BUCKET;
	}
	}

	bool empty() const noexcept {
	return m_dist_from_ideal_bucket == EMPTY_MARKER_DIST_FROM_IDEAL_BUCKET;
	}

	value_type& value() noexcept {
	tsl_rh_assert(!empty());
	return reinterpret_cast<value_type>(std::addressof(m_value));
	}

	const value_type& value() const noexcept {
	tsl_rh_assert(!empty());
	return reinterpret_cast<const value_type>(std::addressof(m_value));
	}

	distance_type dist_from_ideal_bucket() const noexcept {
	return m_dist_from_ideal_bucket;
	}

	bool last_bucket() const noexcept {
	return m_last_bucket;
	}

	void set_as_last_bucket() noexcept {
	m_last_bucket = true;
	}

	template<typename... Args>
	void set_value_of_empty_bucket(distance_type dist_from_ideal_bucket,
	truncated_hash_type hash, Args&&... value_type_args)
	{
	tsl_rh_assert(dist_from_ideal_bucket >= 0);
	tsl_rh_assert(empty());

	::new (static_cast<void*>(std::addressof(m_value))) value_type(std::forward<Args>(value_type_args)...);
	this->set_hash(hash);
	m_dist_from_ideal_bucket = dist_from_ideal_bucket;

	tsl_rh_assert(!empty());
	}

	void swap_with_value_in_bucket(distance_type& dist_from_ideal_bucket,
	truncated_hash_type& hash, value_type& value)
	{
	tsl_rh_assert(!empty());

	using std::swap;
	swap(value, this->value());
	swap(dist_from_ideal_bucket, m_dist_from_ideal_bucket);

	// Avoid warning of unused variable if StoreHash is false
	(void) hash;
	if(StoreHash) {
	const truncated_hash_type tmp_hash = this->truncated_hash();
	this->set_hash(hash);
	hash = tmp_hash;
	}
	}

	static truncated_hash_type truncate_hash(std::size_t hash) noexcept {
	return truncated_hash_type(hash);
	}

	private:
	void destroy_value() noexcept {
	tsl_rh_assert(!empty());
	value().~value_type();
	}

	public:
	static const distance_type DIST_FROM_IDEAL_BUCKET_LIMIT = 4096;
	static_assert(DIST_FROM_IDEAL_BUCKET_LIMIT <= std::numeric_limits<distance_type>::max() - 1,
	"DIST_FROM_IDEAL_BUCKET_LIMIT must be <= std::numeric_limits<distance_type>::max() - 1.");

	private:
	using storage = typename std::aligned_storage<sizeof(value_type), alignof(value_type)>::type;

	static const distance_type EMPTY_MARKER_DIST_FROM_IDEAL_BUCKET = -1;

	distance_type m_dist_from_ideal_bucket;
	bool m_last_bucket;
	storage m_value;
	};



	/**
	* Internal common class used by `robin_map` and `robin_set`.
	*
	* ValueType is what will be stored by `robin_hash` (usually `std::pair<Key, T>` for map and `Key` for set).
	*
	* `KeySelect` should be a `FunctionObject` which takes a `ValueType` in parameter and returns a
	* reference to the key.
	*
	* `ValueSelect` should be a `FunctionObject` which takes a `ValueType` in parameter and returns a
	* reference to the value. `ValueSelect` should be void if there is no value (in a set for example).
	*
	* The strong exception guarantee only holds if the expression
	* `std::is_nothrow_swappable<ValueType>::value && std::is_nothrow_move_constructible<ValueType>::value` is true.
	*
	* Behaviour is undefined if the destructor of `ValueType` throws.
	*/
	template<class ValueType,
	class KeySelect,
	class ValueSelect,
	class Hash,
	class KeyEqual,
	class Allocator,
	bool StoreHash,
	class GrowthPolicy>
	class robin_hash: private Hash, private KeyEqual, private GrowthPolicy {
	private:
	template<typename U>
	using has_mapped_type = typename std::integral_constant<bool, !std::is_same<U, void>::value>;

	static_assert(noexcept(std::declval<GrowthPolicy>().bucket_for_hash(std::size_t(0))), "GrowthPolicy::bucket_for_hash must be noexcept.");
	static_assert(noexcept(std::declval<GrowthPolicy>().clear()), "GrowthPolicy::clear must be noexcept.");

	public:
	template<bool IsConst>
	class robin_iterator;

	using key_type = typename KeySelect::key_type;
	using value_type = ValueType;
	using size_type = std::size_t;
	using difference_type = std::ptrdiff_t;
	using hasher = Hash;
	using key_equal = KeyEqual;
	using allocator_type = Allocator;
	using reference = value_type&;
	using const_reference = const value_type&;
	using pointer = value_type*;
	using const_pointer = const value_type*;
	using iterator = robin_iterator<false>;
	using const_iterator = robin_iterator<true>;


	private:
	/**
	* Either store the hash because we are asked by the `StoreHash` template parameter
	* or store the hash because it doesn't cost us anything in size and can be used to speed up rehash.
	*/
	static constexpr bool STORE_HASH = StoreHash \|\|
	(
	(sizeof(tsl::detail_robin_hash::bucket_entry<value_type, true>) ==
	sizeof(tsl::detail_robin_hash::bucket_entry<value_type, false>))
	&&
	(sizeof(std::size_t) == sizeof(truncated_hash_type) \|\|
	is_power_of_two_policy<GrowthPolicy>::value)
	&&
	// Don't store the hash for primitive types with default hash.
	(!std::is_arithmetic<key_type>::value \|\|
	!std::is_same<Hash, std::hash<key_type>>::value)
	);

	/**
	* Only use the stored hash on lookup if we are explicitly asked. We are not sure how slow
	* the KeyEqual operation is. An extra comparison may slow things down with a fast KeyEqual.
	*/
	static constexpr bool USE_STORED_HASH_ON_LOOKUP = StoreHash;

	/**
	* We can only use the hash on rehash if the size of the hash type is the same as the stored one or
	* if we use a power of two modulo. In the case of the power of two modulo, we just mask
	* the least significant bytes, we just have to check that the truncated_hash_type didn't truncated
	* more bytes.
	*/
	static bool USE_STORED_HASH_ON_REHASH(size_type bucket_count) {
	(void) bucket_count;
	if(STORE_HASH && sizeof(std::size_t) == sizeof(truncated_hash_type)) {
	return true;
	}
	else if(STORE_HASH && is_power_of_two_policy<GrowthPolicy>::value) {
	tsl_rh_assert(bucket_count > 0);
	return (bucket_count - 1) <= std::numeric_limits<truncated_hash_type>::max();
	}
	else {
	return false;
	}
	}

	using bucket_entry = tsl::detail_robin_hash::bucket_entry<value_type, STORE_HASH>;
	using distance_type = typename bucket_entry::distance_type;

	using buckets_allocator = typename std::allocator_traits<allocator_type>::template rebind_alloc<bucket_entry>;
	using buckets_container_type = std::vector<bucket_entry, buckets_allocator>;


	public:
	/**
	* The 'operator*()' and 'operator->()' methods return a const reference and const pointer respectively to the
	* stored value type.
	*
	* In case of a map, to get a mutable reference to the value associated to a key (the '.second' in the
	* stored pair), you have to call 'value()'.
	*
	* The main reason for this is that if we returned a `std::pair<Key, T>&` instead
	* of a `const std::pair<Key, T>&`, the user may modify the key which will put the map in a undefined state.
	*/
	template<bool IsConst>
	class robin_iterator {
	friend class robin_hash;

	private:
	using bucket_entry_ptr = typename std::conditional<IsConst,
	const bucket_entry*,
	bucket_entry*>::type;


	robin_iterator(bucket_entry_ptr bucket) noexcept: m_bucket(bucket) {
	}

	public:
	using iterator_category = std::forward_iterator_tag;
	using value_type = const typename robin_hash::value_type;
	using difference_type = std::ptrdiff_t;
	using reference = value_type&;
	using pointer = value_type*;


	robin_iterator() noexcept {
	}

	// Copy constructor from iterator to const_iterator.
	template<bool TIsConst = IsConst, typename std::enable_if<TIsConst>::type* = nullptr>
	robin_iterator(const robin_iterator<!TIsConst>& other) noexcept: m_bucket(other.m_bucket) {
	}

	robin_iterator(const robin_iterator& other) = default;
	robin_iterator(robin_iterator&& other) = default;
	robin_iterator& operator=(const robin_iterator& other) = default;
	robin_iterator& operator=(robin_iterator&& other) = default;

	const typename robin_hash::key_type& key() const {
	return KeySelect()(m_bucket->value());
	}

	template<class U = ValueSelect, typename std::enable_if<has_mapped_type<U>::value && IsConst>::type* = nullptr>
	const typename U::value_type& value() const {
	return U()(m_bucket->value());
	}

	template<class U = ValueSelect, typename std::enable_if<has_mapped_type<U>::value && !IsConst>::type* = nullptr>
	typename U::value_type& value() const {
	return U()(m_bucket->value());
	}

	reference operator*() const {
	return m_bucket->value();
	}

	pointer operator->() const {
	return std::addressof(m_bucket->value());
	}

	robin_iterator& operator++() {
	while(true) {
	if(m_bucket->last_bucket()) {
	++m_bucket;
	return *this;
	}

	++m_bucket;
	if(!m_bucket->empty()) {
	return *this;
	}
	}
	}

	robin_iterator operator++(int) {
	robin_iterator tmp(*this);
	++*this;

	return tmp;
	}

	friend bool operator==(const robin_iterator& lhs, const robin_iterator& rhs) {
	return lhs.m_bucket == rhs.m_bucket;
	}

	friend bool operator!=(const robin_iterator& lhs, const robin_iterator& rhs) {
	return !(lhs == rhs);
	}

	private:
	bucket_entry_ptr m_bucket;
	};


	public:
	#if defined(__cplusplus) && __cplusplus >= 201402L
	robin_hash(size_type bucket_count,
	const Hash& hash,
	const KeyEqual& equal,
	const Allocator& alloc,
	float min_load_factor = DEFAULT_MIN_LOAD_FACTOR,
	float max_load_factor = DEFAULT_MAX_LOAD_FACTOR):
	Hash(hash),
	KeyEqual(equal),
	GrowthPolicy(bucket_count),
	m_buckets_data(
	[&]() {
	if(bucket_count > max_bucket_count()) {
	TSL_RH_THROW_OR_TERMINATE(std::length_error,
	"The map exceeds its maximum bucket count.");
	}

	return bucket_count;
	}(), alloc
	),
	m_buckets(m_buckets_data.empty()?static_empty_bucket_ptr():m_buckets_data.data()),
	m_bucket_count(bucket_count),
	m_nb_elements(0),
	m_grow_on_next_insert(false),
	m_try_shrink_on_next_insert(false)
	{
	if(m_bucket_count > 0) {
	tsl_rh_assert(!m_buckets_data.empty());
	m_buckets_data.back().set_as_last_bucket();
	}

	this->min_load_factor(min_load_factor);
	this->max_load_factor(max_load_factor);
	}
	#else
	/**
	* C++11 doesn't support the creation of a std::vector with a custom allocator and 'count' default-inserted elements.
	* The needed contructor `explicit vector(size_type count, const Allocator& alloc = Allocator());` is only
	* available in C++14 and later. We thus must resize after using the `vector(const Allocator& alloc)` constructor.
	*
	* We can't use `vector(size_type count, const T& value, const Allocator& alloc)` as it requires the
	* value T to be copyable.
	*/
	robin_hash(size_type bucket_count,
	const Hash& hash,
	const KeyEqual& equal,
	const Allocator& alloc,
	float min_load_factor = DEFAULT_MIN_LOAD_FACTOR,
	float max_load_factor = DEFAULT_MAX_LOAD_FACTOR):
	Hash(hash),
	KeyEqual(equal),
	GrowthPolicy(bucket_count),
	m_buckets_data(alloc),
	m_buckets(static_empty_bucket_ptr()),
	m_bucket_count(bucket_count),
	m_nb_elements(0),
	m_grow_on_next_insert(false),
	m_try_shrink_on_next_insert(false)
	{
	if(bucket_count > max_bucket_count()) {
	TSL_RH_THROW_OR_TERMINATE(std::length_error, "The map exceeds its maximum bucket count.");
	}

	if(m_bucket_count > 0) {
	m_buckets_data.resize(m_bucket_count);
	m_buckets = m_buckets_data.data();

	tsl_rh_assert(!m_buckets_data.empty());
	m_buckets_data.back().set_as_last_bucket();
	}

	this->min_load_factor(min_load_factor);
	this->max_load_factor(max_load_factor);
	}
	#endif

	robin_hash(const robin_hash& other): Hash(other),
	KeyEqual(other),
	GrowthPolicy(other),
	m_buckets_data(other.m_buckets_data),
	m_buckets(m_buckets_data.empty()?static_empty_bucket_ptr():m_buckets_data.data()),
	m_bucket_count(other.m_bucket_count),
	m_nb_elements(other.m_nb_elements),
	m_load_threshold(other.m_load_threshold),
	m_min_load_factor(other.m_min_load_factor),
	m_max_load_factor(other.m_max_load_factor),
	m_grow_on_next_insert(other.m_grow_on_next_insert),
	m_try_shrink_on_next_insert(other.m_try_shrink_on_next_insert)
	{
	}

	robin_hash(robin_hash&& other) noexcept(std::is_nothrow_move_constructible<Hash>::value &&
	std::is_nothrow_move_constructible<KeyEqual>::value &&
	std::is_nothrow_move_constructible<GrowthPolicy>::value &&
	std::is_nothrow_move_constructible<buckets_container_type>::value)
	: Hash(std::move(static_cast<Hash&>(other))),
	KeyEqual(std::move(static_cast<KeyEqual&>(other))),
	GrowthPolicy(std::move(static_cast<GrowthPolicy&>(other))),
	m_buckets_data(std::move(other.m_buckets_data)),
	m_buckets(m_buckets_data.empty()?static_empty_bucket_ptr():m_buckets_data.data()),
	m_bucket_count(other.m_bucket_count),
	m_nb_elements(other.m_nb_elements),
	m_load_threshold(other.m_load_threshold),
	m_min_load_factor(other.m_min_load_factor),
	m_max_load_factor(other.m_max_load_factor),
	m_grow_on_next_insert(other.m_grow_on_next_insert),
	m_try_shrink_on_next_insert(other.m_try_shrink_on_next_insert)
	{
	other.clear_and_shrink();
	}

	robin_hash& operator=(const robin_hash& other) {
	if(&other != this) {
	Hash::operator=(other);
	KeyEqual::operator=(other);
	GrowthPolicy::operator=(other);

	m_buckets_data = other.m_buckets_data;
	m_buckets = m_buckets_data.empty()?static_empty_bucket_ptr():
	m_buckets_data.data();
	m_bucket_count = other.m_bucket_count;
	m_nb_elements = other.m_nb_elements;

	m_load_threshold = other.m_load_threshold;
	m_min_load_factor = other.m_min_load_factor;
	m_max_load_factor = other.m_max_load_factor;

	m_grow_on_next_insert = other.m_grow_on_next_insert;
	m_try_shrink_on_next_insert = other.m_try_shrink_on_next_insert;
	}

	return *this;
	}

	robin_hash& operator=(robin_hash&& other) {
	other.swap(*this);
	other.clear();

	return *this;
	}

	allocator_type get_allocator() const {
	return m_buckets_data.get_allocator();
	}


	/*
	* Iterators
	*/
	iterator begin() noexcept {
	std::size_t i = 0;
	while(i < m_bucket_count && m_buckets[i].empty()) {
	i++;
	}

	return iterator(m_buckets + i);
	}

	const_iterator begin() const noexcept {
	return cbegin();
	}

	const_iterator cbegin() const noexcept {
	std::size_t i = 0;
	while(i < m_bucket_count && m_buckets[i].empty()) {
	i++;
	}

	return const_iterator(m_buckets + i);
	}

	iterator end() noexcept {
	return iterator(m_buckets + m_bucket_count);
	}

	const_iterator end() const noexcept {
	return cend();
	}

	const_iterator cend() const noexcept {
	return const_iterator(m_buckets + m_bucket_count);
	}


	/*
	* Capacity
	*/
	bool empty() const noexcept {
	return m_nb_elements == 0;
	}

	size_type size() const noexcept {
	return m_nb_elements;
	}

	size_type max_size() const noexcept {
	return m_buckets_data.max_size();
	}

	/*
	* Modifiers
	*/
	void clear() noexcept {
	if(m_min_load_factor > 0.0f) {
	clear_and_shrink();
	}
	else {
	for(auto& bucket: m_buckets_data) {
	bucket.clear();
	}

	m_nb_elements = 0;
	m_grow_on_next_insert = false;
	}
	}



	template<typename P>
	std::pair<iterator, bool> insert(P&& value) {
	return insert_impl(KeySelect()(value), std::forward<P>(value));
	}

	template<typename P>
	iterator insert_hint(const_iterator hint, P&& value) {
	if(hint != cend() && compare_keys(KeySelect()(*hint), KeySelect()(value))) {
	return mutable_iterator(hint);
	}

	return insert(std::forward<P>(value)).first;
	}

	template<class InputIt>
	void insert(InputIt first, InputIt last) {
	if(std::is_base_of<std::forward_iterator_tag,
	typename std::iterator_traits<InputIt>::iterator_category>::value)
	{
	const auto nb_elements_insert = std::distance(first, last);
	const size_type nb_free_buckets = m_load_threshold - size();
	tsl_rh_assert(m_load_threshold >= size());

	if(nb_elements_insert > 0 && nb_free_buckets < size_type(nb_elements_insert)) {
	reserve(size() + size_type(nb_elements_insert));
	}
	}

	for(; first != last; ++first) {
	insert(*first);
	}
	}



	template<class K, class M>
	std::pair<iterator, bool> insert_or_assign(K&& key, M&& obj) {
	auto it = try_emplace(std::forward<K>(key), std::forward<M>(obj));
	if(!it.second) {
	it.first.value() = std::forward<M>(obj);
	}

	return it;
	}

	template<class K, class M>
	iterator insert_or_assign(const_iterator hint, K&& key, M&& obj) {
	if(hint != cend() && compare_keys(KeySelect()(*hint), key)) {
	auto it = mutable_iterator(hint);
	it.value() = std::forward<M>(obj);

	return it;
	}

	return insert_or_assign(std::forward<K>(key), std::forward<M>(obj)).first;
	}


	template<class... Args>
	std::pair<iterator, bool> emplace(Args&&... args) {
	return insert(value_type(std::forward<Args>(args)...));
	}

	template<class... Args>
	iterator emplace_hint(const_iterator hint, Args&&... args) {
	return insert_hint(hint, value_type(std::forward<Args>(args)...));
	}



	template<class K, class... Args>
	std::pair<iterator, bool> try_emplace(K&& key, Args&&... args) {
	return insert_impl(key, std::piecewise_construct,
	std::forward_as_tuple(std::forward<K>(key)),
	std::forward_as_tuple(std::forward<Args>(args)...));
	}

	template<class K, class... Args>
	iterator try_emplace_hint(const_iterator hint, K&& key, Args&&... args) {
	if(hint != cend() && compare_keys(KeySelect()(*hint), key)) {
	return mutable_iterator(hint);
	}

	return try_emplace(std::forward<K>(key), std::forward<Args>(args)...).first;
	}

	/**
	* Here to avoid `template<class K> size_type erase(const K& key)` being used when
	* we use an `iterator` instead of a `const_iterator`.
	*/
	iterator erase(iterator pos) {
	erase_from_bucket(pos);

	/**
	* Erase bucket used a backward shift after clearing the bucket.
	* Check if there is a new value in the bucket, if not get the next non-empty.
	*/
	if(pos.m_bucket->empty()) {
	++pos;
	}

	m_try_shrink_on_next_insert = true;

	return pos;
	}

	iterator erase(const_iterator pos) {
	return erase(mutable_iterator(pos));
	}

	iterator erase(const_iterator first, const_iterator last) {
	if(first == last) {
	return mutable_iterator(first);
	}

	auto first_mutable = mutable_iterator(first);
	auto last_mutable = mutable_iterator(last);
	for(auto it = first_mutable.m_bucket; it != last_mutable.m_bucket; ++it) {
	if(!it->empty()) {
	it->clear();
	m_nb_elements--;
	}
	}

	if(last_mutable == end()) {
	m_try_shrink_on_next_insert = true;
	return end();
	}


	/*
	* Backward shift on the values which come after the deleted values.
	* We try to move the values closer to their ideal bucket.
	*/
	std::size_t icloser_bucket = static_cast<std::size_t>(first_mutable.m_bucket - m_buckets);
	std::size_t ito_move_closer_value = static_cast<std::size_t>(last_mutable.m_bucket - m_buckets);
	tsl_rh_assert(ito_move_closer_value > icloser_bucket);

	const std::size_t ireturn_bucket = ito_move_closer_value -
	std::min(ito_move_closer_value - icloser_bucket,
	std::size_t(m_buckets[ito_move_closer_value].dist_from_ideal_bucket()));

	while(ito_move_closer_value < m_bucket_count && m_buckets[ito_move_closer_value].dist_from_ideal_bucket() > 0) {
	icloser_bucket = ito_move_closer_value -
	std::min(ito_move_closer_value - icloser_bucket,
	std::size_t(m_buckets[ito_move_closer_value].dist_from_ideal_bucket()));


	tsl_rh_assert(m_buckets[icloser_bucket].empty());
	const distance_type new_distance = distance_type(m_buckets[ito_move_closer_value].dist_from_ideal_bucket() -
	(ito_move_closer_value - icloser_bucket));
	m_buckets[icloser_bucket].set_value_of_empty_bucket(new_distance,
	m_buckets[ito_move_closer_value].truncated_hash(),
	std::move(m_buckets[ito_move_closer_value].value()));
	m_buckets[ito_move_closer_value].clear();


	++icloser_bucket;
	++ito_move_closer_value;
	}

	m_try_shrink_on_next_insert = true;

	return iterator(m_buckets + ireturn_bucket);
	}


	template<class K>
	size_type erase(const K& key) {
	return erase(key, hash_key(key));
	}

	template<class K>
	size_type erase(const K& key, std::size_t hash) {
	auto it = find(key, hash);
	if(it != end()) {
	erase_from_bucket(it);
	m_try_shrink_on_next_insert = true;

	return 1;
	}
	else {
	return 0;
	}
	}





	void swap(robin_hash& other) {
	using std::swap;

	swap(static_cast<Hash&>(*this), static_cast<Hash&>(other));
	swap(static_cast<KeyEqual&>(*this), static_cast<KeyEqual&>(other));
	swap(static_cast<GrowthPolicy&>(*this), static_cast<GrowthPolicy&>(other));
	swap(m_buckets_data, other.m_buckets_data);
	swap(m_buckets, other.m_buckets);
	swap(m_bucket_count, other.m_bucket_count);
	swap(m_nb_elements, other.m_nb_elements);
	swap(m_load_threshold, other.m_load_threshold);
	swap(m_min_load_factor, other.m_min_load_factor);
	swap(m_max_load_factor, other.m_max_load_factor);
	swap(m_grow_on_next_insert, other.m_grow_on_next_insert);
	swap(m_try_shrink_on_next_insert, other.m_try_shrink_on_next_insert);
	}


	/*
	* Lookup
	*/
	template<class K, class U = ValueSelect, typename std::enable_if<has_mapped_type<U>::value>::type* = nullptr>
	typename U::value_type& at(const K& key) {
	return at(key, hash_key(key));
	}

	template<class K, class U = ValueSelect, typename std::enable_if<has_mapped_type<U>::value>::type* = nullptr>
	typename U::value_type& at(const K& key, std::size_t hash) {
	return const_cast<typename U::value_type&>(static_cast<const robin_hash*>(this)->at(key, hash));
	}


	template<class K, class U = ValueSelect, typename std::enable_if<has_mapped_type<U>::value>::type* = nullptr>
	const typename U::value_type& at(const K& key) const {
	return at(key, hash_key(key));
	}

	template<class K, class U = ValueSelect, typename std::enable_if<has_mapped_type<U>::value>::type* = nullptr>
	const typename U::value_type& at(const K& key, std::size_t hash) const {
	auto it = find(key, hash);
	if(it != cend()) {
	return it.value();
	}
	else {
	TSL_RH_THROW_OR_TERMINATE(std::out_of_range, "Couldn't find key.");
	}
	}

	template<class K, class U = ValueSelect, typename std::enable_if<has_mapped_type<U>::value>::type* = nullptr>
	typename U::value_type& operator[](K&& key) {
	return try_emplace(std::forward<K>(key)).first.value();
	}


	template<class K>
	size_type count(const K& key) const {
	return count(key, hash_key(key));
	}

	template<class K>
	size_type count(const K& key, std::size_t hash) const {
	if(find(key, hash) != cend()) {
	return 1;
	}
	else {
	return 0;
	}
	}


	template<class K>
	iterator find(const K& key) {
	return find_impl(key, hash_key(key));
	}

	template<class K>
	iterator find(const K& key, std::size_t hash) {
	return find_impl(key, hash);
	}


	template<class K>
	const_iterator find(const K& key) const {
	return find_impl(key, hash_key(key));
	}

	template<class K>
	const_iterator find(const K& key, std::size_t hash) const {
	return find_impl(key, hash);
	}


	template<class K>
	bool contains(const K& key) const {
	return contains(key, hash_key(key));
	}

	template<class K>
	bool contains(const K& key, std::size_t hash) const {
	return count(key, hash) != 0;
	}


	template<class K>
	std::pair<iterator, iterator> equal_range(const K& key) {
	return equal_range(key, hash_key(key));
	}

	template<class K>
	std::pair<iterator, iterator> equal_range(const K& key, std::size_t hash) {
	iterator it = find(key, hash);
	return std::make_pair(it, (it == end())?it:std::next(it));
	}


	template<class K>
	std::pair<const_iterator, const_iterator> equal_range(const K& key) const {
	return equal_range(key, hash_key(key));
	}

	template<class K>
	std::pair<const_iterator, const_iterator> equal_range(const K& key, std::size_t hash) const {
	const_iterator it = find(key, hash);
	return std::make_pair(it, (it == cend())?it:std::next(it));
	}

	/*
	* Bucket interface
	*/
	size_type bucket_count() const {
	return m_bucket_count;
	}

	size_type max_bucket_count() const {
	return std::min(GrowthPolicy::max_bucket_count(), m_buckets_data.max_size());
	}

	/*
	* Hash policy
	*/
	float load_factor() const {
	if(bucket_count() == 0) {
	return 0;
	}

	return float(m_nb_elements)/float(bucket_count());
	}

	float min_load_factor() const {
	return m_min_load_factor;
	}

	float max_load_factor() const {
	return m_max_load_factor;
	}

	void min_load_factor(float ml) {
	m_min_load_factor = clamp(ml, float(MINIMUM_MIN_LOAD_FACTOR),
	float(MAXIMUM_MIN_LOAD_FACTOR));
	}

	void max_load_factor(float ml) {
	m_max_load_factor = clamp(ml, float(MINIMUM_MAX_LOAD_FACTOR),
	float(MAXIMUM_MAX_LOAD_FACTOR));
	m_load_threshold = size_type(float(bucket_count())*m_max_load_factor);
	}

	void rehash(size_type count) {
	count = std::max(count, size_type(std::ceil(float(size())/max_load_factor())));
	rehash_impl(count);
	}

	void reserve(size_type count) {
	rehash(size_type(std::ceil(float(count)/max_load_factor())));
	}

	/*
	* Observers
	*/
	hasher hash_function() const {
	return static_cast<const Hash&>(*this);
	}

	key_equal key_eq() const {
	return static_cast<const KeyEqual&>(*this);
	}


	/*
	* Other
	*/
	iterator mutable_iterator(const_iterator pos) {
	return iterator(const_cast<bucket_entry*>(pos.m_bucket));
	}

	private:
	template<class K>
	std::size_t hash_key(const K& key) const {
	return Hash::operator()(key);
	}

	template<class K1, class K2>
	bool compare_keys(const K1& key1, const K2& key2) const {
	return KeyEqual::operator()(key1, key2);
	}

	std::size_t bucket_for_hash(std::size_t hash) const {
	const std::size_t bucket = GrowthPolicy::bucket_for_hash(hash);
	tsl_rh_assert(bucket < m_bucket_count \|\| (bucket == 0 && m_bucket_count == 0));

	return bucket;
	}

	template<class U = GrowthPolicy, typename std::enable_if<is_power_of_two_policy<U>::value>::type* = nullptr>
	std::size_t next_bucket(std::size_t index) const noexcept {
	tsl_rh_assert(index < bucket_count());

	return (index + 1) & this->m_mask;
	}

	template<class U = GrowthPolicy, typename std::enable_if<!is_power_of_two_policy<U>::value>::type* = nullptr>
	std::size_t next_bucket(std::size_t index) const noexcept {
	tsl_rh_assert(index < bucket_count());

	index++;
	return (index != bucket_count())?index:0;
	}



	template<class K>
	iterator find_impl(const K& key, std::size_t hash) {
	return mutable_iterator(static_cast<const robin_hash*>(this)->find(key, hash));
	}

	template<class K>
	const_iterator find_impl(const K& key, std::size_t hash) const {
	std::size_t ibucket = bucket_for_hash(hash);
	distance_type dist_from_ideal_bucket = 0;

	while(dist_from_ideal_bucket <= m_buckets[ibucket].dist_from_ideal_bucket()) {
	if(TSL_RH_LIKELY((!USE_STORED_HASH_ON_LOOKUP \|\| m_buckets[ibucket].bucket_hash_equal(hash)) &&
	compare_keys(KeySelect()(m_buckets[ibucket].value()), key)))
	{
	return const_iterator(m_buckets + ibucket);
	}

	ibucket = next_bucket(ibucket);
	dist_from_ideal_bucket++;
	}

	return cend();
	}

	void erase_from_bucket(iterator pos) {
	pos.m_bucket->clear();
	m_nb_elements--;

	/**
	* Backward shift, swap the empty bucket, previous_ibucket, with the values on its right, ibucket,
	* until we cross another empty bucket or if the other bucket has a distance_from_ideal_bucket == 0.
	*
	* We try to move the values closer to their ideal bucket.
	*/
	std::size_t previous_ibucket = static_cast<std::size_t>(pos.m_bucket - m_buckets);
	std::size_t ibucket = next_bucket(previous_ibucket);

	while(m_buckets[ibucket].dist_from_ideal_bucket() > 0) {
	tsl_rh_assert(m_buckets[previous_ibucket].empty());

	const distance_type new_distance = distance_type(m_buckets[ibucket].dist_from_ideal_bucket() - 1);
	m_buckets[previous_ibucket].set_value_of_empty_bucket(new_distance, m_buckets[ibucket].truncated_hash(),
	std::move(m_buckets[ibucket].value()));
	m_buckets[ibucket].clear();

	previous_ibucket = ibucket;
	ibucket = next_bucket(ibucket);
	}
	}

	template<class K, class... Args>
	std::pair<iterator, bool> insert_impl(const K& key, Args&&... value_type_args) {
	const std::size_t hash = hash_key(key);

	std::size_t ibucket = bucket_for_hash(hash);
	distance_type dist_from_ideal_bucket = 0;

	while(dist_from_ideal_bucket <= m_buckets[ibucket].dist_from_ideal_bucket()) {
	if((!USE_STORED_HASH_ON_LOOKUP \|\| m_buckets[ibucket].bucket_hash_equal(hash)) &&
	compare_keys(KeySelect()(m_buckets[ibucket].value()), key))
	{
	return std::make_pair(iterator(m_buckets + ibucket), false);
	}

	ibucket = next_bucket(ibucket);
	dist_from_ideal_bucket++;
	}

	if(rehash_on_extreme_load()) {
	ibucket = bucket_for_hash(hash);
	dist_from_ideal_bucket = 0;

	while(dist_from_ideal_bucket <= m_buckets[ibucket].dist_from_ideal_bucket()) {
	ibucket = next_bucket(ibucket);
	dist_from_ideal_bucket++;
	}
	}


	if(m_buckets[ibucket].empty()) {
	m_buckets[ibucket].set_value_of_empty_bucket(dist_from_ideal_bucket, bucket_entry::truncate_hash(hash),
	std::forward<Args>(value_type_args)...);
	}
	else {
	insert_value(ibucket, dist_from_ideal_bucket, bucket_entry::truncate_hash(hash),
	std::forward<Args>(value_type_args)...);
	}


	m_nb_elements++;
	/*
	* The value will be inserted in ibucket in any case, either because it was
	* empty or by stealing the bucket (robin hood).
	*/
	return std::make_pair(iterator(m_buckets + ibucket), true);
	}


	template<class... Args>
	void insert_value(std::size_t ibucket, distance_type dist_from_ideal_bucket,
	truncated_hash_type hash, Args&&... value_type_args)
	{
	value_type value(std::forward<Args>(value_type_args)...);
	insert_value_impl(ibucket, dist_from_ideal_bucket, hash, value);
	}

	void insert_value(std::size_t ibucket, distance_type dist_from_ideal_bucket,
	truncated_hash_type hash, value_type&& value)
	{
	insert_value_impl(ibucket, dist_from_ideal_bucket, hash, value);
	}

	/*
	* We don't use `value_type&& value` as last argument due to a bug in MSVC when `value_type` is a pointer,
	* The compiler is not able to see the difference between `std::string` and `std::string&&` resulting in
	* a compilation error.
	*
	* The `value` will be in a moved state at the end of the function.
	*/
	void insert_value_impl(std::size_t ibucket, distance_type dist_from_ideal_bucket,
	truncated_hash_type hash, value_type& value)
	{
	m_buckets[ibucket].swap_with_value_in_bucket(dist_from_ideal_bucket, hash, value);
	ibucket = next_bucket(ibucket);
	dist_from_ideal_bucket++;

	while(!m_buckets[ibucket].empty()) {
	if(dist_from_ideal_bucket > m_buckets[ibucket].dist_from_ideal_bucket()) {
	if(dist_from_ideal_bucket >= bucket_entry::DIST_FROM_IDEAL_BUCKET_LIMIT) {
	/**
	* The number of probes is really high, rehash the map on the next insert.
	* Difficult to do now as rehash may throw an exception.
	*/
	m_grow_on_next_insert = true;
	}

	m_buckets[ibucket].swap_with_value_in_bucket(dist_from_ideal_bucket, hash, value);
	}

	ibucket = next_bucket(ibucket);
	dist_from_ideal_bucket++;
	}

	m_buckets[ibucket].set_value_of_empty_bucket(dist_from_ideal_bucket, hash, std::move(value));
	}


	void rehash_impl(size_type count) {
	robin_hash new_table(count, static_cast<Hash&>(this), static_cast<KeyEqual&>(this),
	get_allocator(), m_min_load_factor, m_max_load_factor);

	const bool use_stored_hash = USE_STORED_HASH_ON_REHASH(new_table.bucket_count());
	for(auto& bucket: m_buckets_data) {
	if(bucket.empty()) {
	continue;
	}

	const std::size_t hash = use_stored_hash?bucket.truncated_hash():
	new_table.hash_key(KeySelect()(bucket.value()));

	new_table.insert_value_on_rehash(new_table.bucket_for_hash(hash), 0,
	bucket_entry::truncate_hash(hash), std::move(bucket.value()));
	}

	new_table.m_nb_elements = m_nb_elements;
	new_table.swap(*this);
	}

	void clear_and_shrink() noexcept {
	GrowthPolicy::clear();
	m_buckets_data.clear();
	m_buckets = static_empty_bucket_ptr();
	m_bucket_count = 0;
	m_nb_elements = 0;
	m_load_threshold = 0;
	m_grow_on_next_insert = false;
	m_try_shrink_on_next_insert = false;
	}

	void insert_value_on_rehash(std::size_t ibucket, distance_type dist_from_ideal_bucket,
	truncated_hash_type hash, value_type&& value)
	{
	while(true) {
	if(dist_from_ideal_bucket > m_buckets[ibucket].dist_from_ideal_bucket()) {
	if(m_buckets[ibucket].empty()) {
	m_buckets[ibucket].set_value_of_empty_bucket(dist_from_ideal_bucket, hash, std::move(value));
	return;
	}
	else {
	m_buckets[ibucket].swap_with_value_in_bucket(dist_from_ideal_bucket, hash, value);
	}
	}

	dist_from_ideal_bucket++;
	ibucket = next_bucket(ibucket);
	}
	}



	/**
	* Grow the table if m_grow_on_next_insert is true or we reached the max_load_factor.
	* Shrink the table if m_try_shrink_on_next_insert is true (an erase occurred) and
	* we're below the min_load_factor.
	*
	* Return true if the table has been rehashed.
	*/
	bool rehash_on_extreme_load() {
	if(m_grow_on_next_insert \|\| size() >= m_load_threshold) {
	rehash_impl(GrowthPolicy::next_bucket_count());
	m_grow_on_next_insert = false;

	return true;
	}

	if(m_try_shrink_on_next_insert) {
	m_try_shrink_on_next_insert = false;
	if(m_min_load_factor != 0.0f && load_factor() < m_min_load_factor) {
	reserve(size() + 1);

	return true;
	}
	}

	return false;
	}


	public:
	static const size_type DEFAULT_INIT_BUCKETS_SIZE = 0;

	static constexpr float DEFAULT_MAX_LOAD_FACTOR = 0.5f;
	static constexpr float MINIMUM_MAX_LOAD_FACTOR = 0.2f;
	static constexpr float MAXIMUM_MAX_LOAD_FACTOR = 0.95f;

	static constexpr float DEFAULT_MIN_LOAD_FACTOR = 0.0f;
	static constexpr float MINIMUM_MIN_LOAD_FACTOR = 0.0f;
	static constexpr float MAXIMUM_MIN_LOAD_FACTOR = 0.15f;

	static_assert(MINIMUM_MAX_LOAD_FACTOR < MAXIMUM_MAX_LOAD_FACTOR,
	"MINIMUM_MAX_LOAD_FACTOR should be < MAXIMUM_MAX_LOAD_FACTOR");
	static_assert(MINIMUM_MIN_LOAD_FACTOR < MAXIMUM_MIN_LOAD_FACTOR,
	"MINIMUM_MIN_LOAD_FACTOR should be < MAXIMUM_MIN_LOAD_FACTOR");
	static_assert(MAXIMUM_MIN_LOAD_FACTOR < MINIMUM_MAX_LOAD_FACTOR,
	"MAXIMUM_MIN_LOAD_FACTOR should be < MINIMUM_MAX_LOAD_FACTOR");

	private:
	/**
	* Return an always valid pointer to an static empty bucket_entry with last_bucket() == true.
	*/
	bucket_entry* static_empty_bucket_ptr() noexcept {
	static bucket_entry empty_bucket(true);
	return &empty_bucket;
	}

	private:
	buckets_container_type m_buckets_data;

	/**
	* Points to m_buckets_data.data() if !m_buckets_data.empty() otherwise points to static_empty_bucket_ptr.
	* This variable is useful to avoid the cost of checking if m_buckets_data is empty when trying
	* to find an element.
	*
	* TODO Remove m_buckets_data and only use a pointer instead of a pointer+vector to save some space in the robin_hash object.
	* Manage the Allocator manually.
	*/
	bucket_entry* m_buckets;

	/**
	* Used a lot in find, avoid the call to m_buckets_data.size() which is a bit slower.
	*/
	size_type m_bucket_count;

	size_type m_nb_elements;

	size_type m_load_threshold;

	float m_min_load_factor;
	float m_max_load_factor;

	bool m_grow_on_next_insert;

	/**
	* We can't shrink down the map on erase operations as the erase methods need to return the next iterator.
	* Shrinking the map would invalidate all the iterators and we could not return the next iterator in a meaningful way,
	* On erase, we thus just indicate on erase that we should try to shrink the hash table on the next insert
	* if we go below the min_load_factor.
	*/
	bool m_try_shrink_on_next_insert;
	};

	}

	}

	#endif