absl/container/internal/container_memory.h - third_party/github/abseil/abseil-cpp - Git at Google

 // Copyright 2018 The Abseil Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //      https://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #ifndef ABSL_CONTAINER_INTERNAL_CONTAINER_MEMORY_H_
 #define ABSL_CONTAINER_INTERNAL_CONTAINER_MEMORY_H_

 #include <cassert>
 #include <cstddef>
 #include <cstring>
 #include <memory>
 #include <new>
 #include <tuple>
 #include <type_traits>
 #include <utility>

 #include "absl/base/config.h"
 #include "absl/memory/memory.h"
 #include "absl/meta/type_traits.h"
 #include "absl/utility/utility.h"

 #ifdef ABSL_HAVE_ADDRESS_SANITIZER
 #include <sanitizer/asan_interface.h>
 #endif

 #ifdef ABSL_HAVE_MEMORY_SANITIZER
 #include <sanitizer/msan_interface.h>
 #endif

 namespace absl {
 ABSL_NAMESPACE_BEGIN
 namespace container_internal {

 template <size_t Alignment>
 struct alignas(Alignment) AlignedType {};

 // Allocates at least n bytes aligned to the specified alignment.
 // Alignment must be a power of 2. It must be positive.
 //
 // Note that many allocators don't honor alignment requirements above certain
 // threshold (usually either alignof(std::max_align_t) or alignof(void*)).
 // Allocate() doesn't apply alignment corrections. If the underlying allocator
 // returns insufficiently alignment pointer, that's what you are going to get.
 template <size_t Alignment, class Alloc>
 void* Allocate(Alloc* alloc, size_t n) {
   static_assert(Alignment > 0, "");
   assert(n && "n must be positive");
   using M = AlignedType<Alignment>;
   using A = typename absl::allocator_traits<Alloc>::template rebind_alloc<M>;
   using AT = typename absl::allocator_traits<Alloc>::template rebind_traits<M>;
   // On macOS, "mem_alloc" is a #define with one argument defined in
   // rpc/types.h, so we can't name the variable "mem_alloc" and initialize it
   // with the "foo(bar)" syntax.
   A my_mem_alloc(*alloc);
   void* p = AT::allocate(my_mem_alloc, (n + sizeof(M) - 1) / sizeof(M));
   assert(reinterpret_cast<uintptr_t>(p) % Alignment == 0 &&
          "allocator does not respect alignment");
   return p;
 }

 // Returns true if the destruction of the value with given Allocator will be
 // trivial.
 template <class Allocator, class ValueType>
 constexpr auto IsDestructionTrivial() {
   constexpr bool result =
       std::is_trivially_destructible<ValueType>::value &&
       std::is_same<typename absl::allocator_traits<
                        Allocator>::template rebind_alloc<char>,
                    std::allocator<char>>::value;
   return std::integral_constant<bool, result>();
 }

 // The pointer must have been previously obtained by calling
 // Allocate<Alignment>(alloc, n).
 template <size_t Alignment, class Alloc>
 void Deallocate(Alloc* alloc, void* p, size_t n) {
   static_assert(Alignment > 0, "");
   assert(n && "n must be positive");
   using M = AlignedType<Alignment>;
   using A = typename absl::allocator_traits<Alloc>::template rebind_alloc<M>;
   using AT = typename absl::allocator_traits<Alloc>::template rebind_traits<M>;
   // On macOS, "mem_alloc" is a #define with one argument defined in
   // rpc/types.h, so we can't name the variable "mem_alloc" and initialize it
   // with the "foo(bar)" syntax.
   A my_mem_alloc(*alloc);
   AT::deallocate(my_mem_alloc, static_cast<M*>(p),
                  (n + sizeof(M) - 1) / sizeof(M));
 }

 namespace memory_internal {

 // Constructs T into uninitialized storage pointed by `ptr` using the args
 // specified in the tuple.
 template <class Alloc, class T, class Tuple, size_t... I>
 void ConstructFromTupleImpl(Alloc* alloc, T* ptr, Tuple&& t,
                             absl::index_sequence<I...>) {
   absl::allocator_traits<Alloc>::construct(
       *alloc, ptr, std::get<I>(std::forward<Tuple>(t))...);
 }

 template <class T, class F>
 struct WithConstructedImplF {
   template <class... Args>
   decltype(std::declval<F>()(std::declval<T>())) operator()(
       Args&&... args) const {
     return std::forward<F>(f)(T(std::forward<Args>(args)...));
   }
   F&& f;
 };

 template <class T, class Tuple, size_t... Is, class F>
 decltype(std::declval<F>()(std::declval<T>())) WithConstructedImpl(
     Tuple&& t, absl::index_sequence<Is...>, F&& f) {
   return WithConstructedImplF<T, F>{std::forward<F>(f)}(
       std::get<Is>(std::forward<Tuple>(t))...);
 }

 template <class T, size_t... Is>
 auto TupleRefImpl(T&& t, absl::index_sequence<Is...>)
     -> decltype(std::forward_as_tuple(std::get<Is>(std::forward<T>(t))...)) {
   return std::forward_as_tuple(std::get<Is>(std::forward<T>(t))...);
 }

 // Returns a tuple of references to the elements of the input tuple. T must be a
 // tuple.
 template <class T>
 auto TupleRef(T&& t) -> decltype(TupleRefImpl(
     std::forward<T>(t),
     absl::make_index_sequence<
         std::tuple_size<typename std::decay<T>::type>::value>())) {
   return TupleRefImpl(
       std::forward<T>(t),
       absl::make_index_sequence<
           std::tuple_size<typename std::decay<T>::type>::value>());
 }

 template <class F, class K, class V>
 decltype(std::declval<F>()(std::declval<const K&>(), std::piecewise_construct,
                            std::declval<std::tuple<K>>(), std::declval<V>()))
 DecomposePairImpl(F&& f, std::pair<std::tuple<K>, V> p) {
   const auto& key = std::get<0>(p.first);
   return std::forward<F>(f)(key, std::piecewise_construct, std::move(p.first),
                             std::move(p.second));
 }

 }  // namespace memory_internal

 // Constructs T into uninitialized storage pointed by `ptr` using the args
 // specified in the tuple.
 template <class Alloc, class T, class Tuple>
 void ConstructFromTuple(Alloc* alloc, T* ptr, Tuple&& t) {
   memory_internal::ConstructFromTupleImpl(
       alloc, ptr, std::forward<Tuple>(t),
       absl::make_index_sequence<
           std::tuple_size<typename std::decay<Tuple>::type>::value>());
 }

 // Constructs T using the args specified in the tuple and calls F with the
 // constructed value.
 template <class T, class Tuple, class F>
 decltype(std::declval<F>()(std::declval<T>())) WithConstructed(Tuple&& t,
                                                                F&& f) {
   return memory_internal::WithConstructedImpl<T>(
       std::forward<Tuple>(t),
       absl::make_index_sequence<
           std::tuple_size<typename std::decay<Tuple>::type>::value>(),
       std::forward<F>(f));
 }

 // Given arguments of an std::pair's constructor, PairArgs() returns a pair of
 // tuples with references to the passed arguments. The tuples contain
 // constructor arguments for the first and the second elements of the pair.
 //
 // The following two snippets are equivalent.
 //
 // 1. std::pair<F, S> p(args...);
 //
 // 2. auto a = PairArgs(args...);
 //    std::pair<F, S> p(std::piecewise_construct,
 //                      std::move(a.first), std::move(a.second));
 inline std::pair<std::tuple<>, std::tuple<>> PairArgs() { return {}; }
 template <class F, class S>
 std::pair<std::tuple<F&&>, std::tuple<S&&>> PairArgs(F&& f, S&& s) {
   return {std::piecewise_construct, std::forward_as_tuple(std::forward<F>(f)),
           std::forward_as_tuple(std::forward<S>(s))};
 }
 template <class F, class S>
 std::pair<std::tuple<const F&>, std::tuple<const S&>> PairArgs(
     const std::pair<F, S>& p) {
   return PairArgs(p.first, p.second);
 }
 template <class F, class S>
 std::pair<std::tuple<F&&>, std::tuple<S&&>> PairArgs(std::pair<F, S>&& p) {
   return PairArgs(std::forward<F>(p.first), std::forward<S>(p.second));
 }
 template <class F, class S>
 auto PairArgs(std::piecewise_construct_t, F&& f, S&& s)
     -> decltype(std::make_pair(memory_internal::TupleRef(std::forward<F>(f)),
                                memory_internal::TupleRef(std::forward<S>(s)))) {
   return std::make_pair(memory_internal::TupleRef(std::forward<F>(f)),
                         memory_internal::TupleRef(std::forward<S>(s)));
 }

 // A helper function for implementing apply() in map policies.
 template <class F, class... Args>
 auto DecomposePair(F&& f, Args&&... args)
     -> decltype(memory_internal::DecomposePairImpl(
         std::forward<F>(f), PairArgs(std::forward<Args>(args)...))) {
   return memory_internal::DecomposePairImpl(
       std::forward<F>(f), PairArgs(std::forward<Args>(args)...));
 }

 // A helper function for implementing apply() in set policies.
 template <class F, class Arg>
 decltype(std::declval<F>()(std::declval<const Arg&>(), std::declval<Arg>()))
 DecomposeValue(F&& f, Arg&& arg) {
   const auto& key = arg;
   return std::forward<F>(f)(key, std::forward<Arg>(arg));
 }

 // Helper functions for asan and msan.
 inline void SanitizerPoisonMemoryRegion(const void* m, size_t s) {
 #ifdef ABSL_HAVE_ADDRESS_SANITIZER
   ASAN_POISON_MEMORY_REGION(m, s);
 #endif
 #ifdef ABSL_HAVE_MEMORY_SANITIZER
   __msan_poison(m, s);
 #endif
   (void)m;
   (void)s;
 }

 inline void SanitizerUnpoisonMemoryRegion(const void* m, size_t s) {
 #ifdef ABSL_HAVE_ADDRESS_SANITIZER
   ASAN_UNPOISON_MEMORY_REGION(m, s);
 #endif
 #ifdef ABSL_HAVE_MEMORY_SANITIZER
   __msan_unpoison(m, s);
 #endif
   (void)m;
   (void)s;
 }

 template <typename T>
 inline void SanitizerPoisonObject(const T* object) {
   SanitizerPoisonMemoryRegion(object, sizeof(T));
 }

 template <typename T>
 inline void SanitizerUnpoisonObject(const T* object) {
   SanitizerUnpoisonMemoryRegion(object, sizeof(T));
 }

 namespace memory_internal {

 // If Pair is a standard-layout type, OffsetOf<Pair>::kFirst and
 // OffsetOf<Pair>::kSecond are equivalent to offsetof(Pair, first) and
 // offsetof(Pair, second) respectively. Otherwise they are -1.
 //
 // The purpose of OffsetOf is to avoid calling offsetof() on non-standard-layout
 // type, which is non-portable.
 template <class Pair, class = std::true_type>
 struct OffsetOf {
   static constexpr size_t kFirst = static_cast<size_t>(-1);
   static constexpr size_t kSecond = static_cast<size_t>(-1);
 };

 template <class Pair>
 struct OffsetOf<Pair, typename std::is_standard_layout<Pair>::type> {
   static constexpr size_t kFirst = offsetof(Pair, first);
   static constexpr size_t kSecond = offsetof(Pair, second);
 };

 template <class K, class V>
 struct IsLayoutCompatible {
  private:
   struct Pair {
     K first;
     V second;
   };

   // Is P layout-compatible with Pair?
   template <class P>
   static constexpr bool LayoutCompatible() {
     return std::is_standard_layout<P>() && sizeof(P) == sizeof(Pair) &&
            alignof(P) == alignof(Pair) &&
            memory_internal::OffsetOf<P>::kFirst ==
                memory_internal::OffsetOf<Pair>::kFirst &&
            memory_internal::OffsetOf<P>::kSecond ==
                memory_internal::OffsetOf<Pair>::kSecond;
   }

  public:
   // Whether pair<const K, V> and pair<K, V> are layout-compatible. If they are,
   // then it is safe to store them in a union and read from either.
   static constexpr bool value = std::is_standard_layout<K>() &&
                                 std::is_standard_layout<Pair>() &&
                                 memory_internal::OffsetOf<Pair>::kFirst == 0 &&
                                 LayoutCompatible<std::pair<K, V>>() &&
                                 LayoutCompatible<std::pair<const K, V>>();
 };

 }  // namespace memory_internal

 // The internal storage type for key-value containers like flat_hash_map.
 //
 // It is convenient for the value_type of a flat_hash_map<K, V> to be
 // pair<const K, V>; the "const K" prevents accidental modification of the key
 // when dealing with the reference returned from find() and similar methods.
 // However, this creates other problems; we want to be able to emplace(K, V)
 // efficiently with move operations, and similarly be able to move a
 // pair<K, V> in insert().
 //
 // The solution is this union, which aliases the const and non-const versions
 // of the pair. This also allows flat_hash_map<const K, V> to work, even though
 // that has the same efficiency issues with move in emplace() and insert() -
 // but people do it anyway.
 //
 // If kMutableKeys is false, only the value member can be accessed.
 //
 // If kMutableKeys is true, key can be accessed through all slots while value
 // and mutable_value must be accessed only via INITIALIZED slots. Slots are
 // created and destroyed via mutable_value so that the key can be moved later.
 //
 // Accessing one of the union fields while the other is active is safe as
 // long as they are layout-compatible, which is guaranteed by the definition of
 // kMutableKeys. For C++11, the relevant section of the standard is
 // https://timsong-cpp.github.io/cppwp/n3337/class.mem#19 (9.2.19)
 template <class K, class V>
 union map_slot_type {
   map_slot_type() {}
   ~map_slot_type() = delete;
   using value_type = std::pair<const K, V>;
   using mutable_value_type =
       std::pair<absl::remove_const_t<K>, absl::remove_const_t<V>>;

   value_type value;
   mutable_value_type mutable_value;
   absl::remove_const_t<K> key;
 };

 template <class K, class V>
 struct map_slot_policy {
   using slot_type = map_slot_type<K, V>;
   using value_type = std::pair<const K, V>;
   using mutable_value_type =
       std::pair<absl::remove_const_t<K>, absl::remove_const_t<V>>;

  private:
   static void emplace(slot_type* slot) {
     // The construction of union doesn't do anything at runtime but it allows us
     // to access its members without violating aliasing rules.
     new (slot) slot_type;
   }
   // If pair<const K, V> and pair<K, V> are layout-compatible, we can accept one
   // or the other via slot_type. We are also free to access the key via
   // slot_type::key in this case.
   using kMutableKeys = memory_internal::IsLayoutCompatible<K, V>;

  public:
   static value_type& element(slot_type* slot) { return slot->value; }
   static const value_type& element(const slot_type* slot) {
     return slot->value;
   }

   // When C++17 is available, we can use std::launder to provide mutable
   // access to the key for use in node handle.
 #if defined(__cpp_lib_launder) && __cpp_lib_launder >= 201606
   static K& mutable_key(slot_type* slot) {
     // Still check for kMutableKeys so that we can avoid calling std::launder
     // unless necessary because it can interfere with optimizations.
     return kMutableKeys::value ? slot->key
                                : *std::launder(const_cast<K*>(
                                      std::addressof(slot->value.first)));
   }
 #else  // !(defined(__cpp_lib_launder) && __cpp_lib_launder >= 201606)
   static const K& mutable_key(slot_type* slot) { return key(slot); }
 #endif

   static const K& key(const slot_type* slot) {
     return kMutableKeys::value ? slot->key : slot->value.first;
   }

   template <class Allocator, class... Args>
   static void construct(Allocator* alloc, slot_type* slot, Args&&... args) {
     emplace(slot);
     if (kMutableKeys::value) {
       absl::allocator_traits<Allocator>::construct(*alloc, &slot->mutable_value,
                                                    std::forward<Args>(args)...);
     } else {
       absl::allocator_traits<Allocator>::construct(*alloc, &slot->value,
                                                    std::forward<Args>(args)...);
     }
   }

   // Construct this slot by moving from another slot.
   template <class Allocator>
   static void construct(Allocator* alloc, slot_type* slot, slot_type* other) {
     emplace(slot);
     if (kMutableKeys::value) {
       absl::allocator_traits<Allocator>::construct(
           *alloc, &slot->mutable_value, std::move(other->mutable_value));
     } else {
       absl::allocator_traits<Allocator>::construct(*alloc, &slot->value,
                                                    std::move(other->value));
     }
   }

   // Construct this slot by copying from another slot.
   template <class Allocator>
   static void construct(Allocator* alloc, slot_type* slot,
                         const slot_type* other) {
     emplace(slot);
     absl::allocator_traits<Allocator>::construct(*alloc, &slot->value,
                                                  other->value);
   }

   template <class Allocator>
   static auto destroy(Allocator* alloc, slot_type* slot) {
     if (kMutableKeys::value) {
       absl::allocator_traits<Allocator>::destroy(*alloc, &slot->mutable_value);
     } else {
       absl::allocator_traits<Allocator>::destroy(*alloc, &slot->value);
     }
     return IsDestructionTrivial<Allocator, value_type>();
   }

   template <class Allocator>
   static auto transfer(Allocator* alloc, slot_type* new_slot,
                        slot_type* old_slot) {
     auto is_relocatable =
         typename absl::is_trivially_relocatable<value_type>::type();

     emplace(new_slot);
 #if defined(__cpp_lib_launder) && __cpp_lib_launder >= 201606
     if (is_relocatable) {
       // TODO(b/247130232,b/251814870): remove casts after fixing warnings.
       std::memcpy(static_cast<void*>(std::launder(&new_slot->value)),
                   static_cast<const void*>(&old_slot->value),
                   sizeof(value_type));
       return is_relocatable;
     }
 #endif

     if (kMutableKeys::value) {
       absl::allocator_traits<Allocator>::construct(
           *alloc, &new_slot->mutable_value, std::move(old_slot->mutable_value));
     } else {
       absl::allocator_traits<Allocator>::construct(*alloc, &new_slot->value,
                                                    std::move(old_slot->value));
     }
     destroy(alloc, old_slot);
     return is_relocatable;
   }
 };

 // Type erased function for computing hash of the slot.
 using HashSlotFn = size_t (*)(const void* hash_fn, void* slot);

 // Type erased function to apply `Fn` to data inside of the `slot`.
 // The data is expected to have type `T`.
 template <class Fn, class T>
 size_t TypeErasedApplyToSlotFn(const void* fn, void* slot) {
   const auto* f = static_cast<const Fn*>(fn);
   return (*f)(*static_cast<const T*>(slot));
 }

 // Type erased function to apply `Fn` to data inside of the `*slot_ptr`.
 // The data is expected to have type `T`.
 template <class Fn, class T>
 size_t TypeErasedDerefAndApplyToSlotFn(const void* fn, void* slot_ptr) {
   const auto* f = static_cast<const Fn*>(fn);
   const T* slot = *static_cast<const T**>(slot_ptr);
   return (*f)(*slot);
 }

 }  // namespace container_internal
 ABSL_NAMESPACE_END
 }  // namespace absl

 #endif  // ABSL_CONTAINER_INTERNAL_CONTAINER_MEMORY_H_
	// Copyright 2018 The Abseil Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// https://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#ifndef ABSL_CONTAINER_INTERNAL_CONTAINER_MEMORY_H_
	#define ABSL_CONTAINER_INTERNAL_CONTAINER_MEMORY_H_

	#include <cassert>
	#include <cstddef>
	#include <cstring>
	#include <memory>
	#include <new>
	#include <tuple>
	#include <type_traits>
	#include <utility>

	#include "absl/base/config.h"
	#include "absl/memory/memory.h"
	#include "absl/meta/type_traits.h"
	#include "absl/utility/utility.h"

	#ifdef ABSL_HAVE_ADDRESS_SANITIZER
	#include <sanitizer/asan_interface.h>
	#endif

	#ifdef ABSL_HAVE_MEMORY_SANITIZER
	#include <sanitizer/msan_interface.h>
	#endif

	namespace absl {
	ABSL_NAMESPACE_BEGIN
	namespace container_internal {

	template <size_t Alignment>
	struct alignas(Alignment) AlignedType {};

	// Allocates at least n bytes aligned to the specified alignment.
	// Alignment must be a power of 2. It must be positive.
	//
	// Note that many allocators don't honor alignment requirements above certain
	// threshold (usually either alignof(std::max_align_t) or alignof(void*)).
	// Allocate() doesn't apply alignment corrections. If the underlying allocator
	// returns insufficiently alignment pointer, that's what you are going to get.
	template <size_t Alignment, class Alloc>
	void* Allocate(Alloc* alloc, size_t n) {
	static_assert(Alignment > 0, "");
	assert(n && "n must be positive");
	using M = AlignedType<Alignment>;
	using A = typename absl::allocator_traits<Alloc>::template rebind_alloc<M>;
	using AT = typename absl::allocator_traits<Alloc>::template rebind_traits<M>;
	// On macOS, "mem_alloc" is a #define with one argument defined in
	// rpc/types.h, so we can't name the variable "mem_alloc" and initialize it
	// with the "foo(bar)" syntax.
	A my_mem_alloc(*alloc);
	void* p = AT::allocate(my_mem_alloc, (n + sizeof(M) - 1) / sizeof(M));
	assert(reinterpret_cast<uintptr_t>(p) % Alignment == 0 &&
	"allocator does not respect alignment");
	return p;
	}

	// Returns true if the destruction of the value with given Allocator will be
	// trivial.
	template <class Allocator, class ValueType>
	constexpr auto IsDestructionTrivial() {
	constexpr bool result =
	std::is_trivially_destructible<ValueType>::value &&
	std::is_same<typename absl::allocator_traits<
	Allocator>::template rebind_alloc<char>,
	std::allocator<char>>::value;
	return std::integral_constant<bool, result>();
	}

	// The pointer must have been previously obtained by calling
	// Allocate<Alignment>(alloc, n).
	template <size_t Alignment, class Alloc>
	void Deallocate(Alloc* alloc, void* p, size_t n) {
	static_assert(Alignment > 0, "");
	assert(n && "n must be positive");
	using M = AlignedType<Alignment>;
	using A = typename absl::allocator_traits<Alloc>::template rebind_alloc<M>;
	using AT = typename absl::allocator_traits<Alloc>::template rebind_traits<M>;
	// On macOS, "mem_alloc" is a #define with one argument defined in
	// rpc/types.h, so we can't name the variable "mem_alloc" and initialize it
	// with the "foo(bar)" syntax.
	A my_mem_alloc(*alloc);
	AT::deallocate(my_mem_alloc, static_cast<M*>(p),
	(n + sizeof(M) - 1) / sizeof(M));
	}

	namespace memory_internal {

	// Constructs T into uninitialized storage pointed by `ptr` using the args
	// specified in the tuple.
	template <class Alloc, class T, class Tuple, size_t... I>
	void ConstructFromTupleImpl(Alloc* alloc, T* ptr, Tuple&& t,
	absl::index_sequence<I...>) {
	absl::allocator_traits<Alloc>::construct(
	*alloc, ptr, std::get<I>(std::forward<Tuple>(t))...);
	}

	template <class T, class F>
	struct WithConstructedImplF {
	template <class... Args>
	decltype(std::declval<F>()(std::declval<T>())) operator()(
	Args&&... args) const {
	return std::forward<F>(f)(T(std::forward<Args>(args)...));
	}
	F&& f;
	};

	template <class T, class Tuple, size_t... Is, class F>
	decltype(std::declval<F>()(std::declval<T>())) WithConstructedImpl(
	Tuple&& t, absl::index_sequence<Is...>, F&& f) {
	return WithConstructedImplF<T, F>{std::forward<F>(f)}(
	std::get<Is>(std::forward<Tuple>(t))...);
	}

	template <class T, size_t... Is>
	auto TupleRefImpl(T&& t, absl::index_sequence<Is...>)
	-> decltype(std::forward_as_tuple(std::get<Is>(std::forward<T>(t))...)) {
	return std::forward_as_tuple(std::get<Is>(std::forward<T>(t))...);
	}

	// Returns a tuple of references to the elements of the input tuple. T must be a
	// tuple.
	template <class T>
	auto TupleRef(T&& t) -> decltype(TupleRefImpl(
	std::forward<T>(t),
	absl::make_index_sequence<
	std::tuple_size<typename std::decay<T>::type>::value>())) {
	return TupleRefImpl(
	std::forward<T>(t),
	absl::make_index_sequence<
	std::tuple_size<typename std::decay<T>::type>::value>());
	}

	template <class F, class K, class V>
	decltype(std::declval<F>()(std::declval<const K&>(), std::piecewise_construct,
	std::declval<std::tuple<K>>(), std::declval<V>()))
	DecomposePairImpl(F&& f, std::pair<std::tuple<K>, V> p) {
	const auto& key = std::get<0>(p.first);
	return std::forward<F>(f)(key, std::piecewise_construct, std::move(p.first),
	std::move(p.second));
	}

	} // namespace memory_internal

	// Constructs T into uninitialized storage pointed by `ptr` using the args
	// specified in the tuple.
	template <class Alloc, class T, class Tuple>
	void ConstructFromTuple(Alloc* alloc, T* ptr, Tuple&& t) {
	memory_internal::ConstructFromTupleImpl(
	alloc, ptr, std::forward<Tuple>(t),
	absl::make_index_sequence<
	std::tuple_size<typename std::decay<Tuple>::type>::value>());
	}

	// Constructs T using the args specified in the tuple and calls F with the
	// constructed value.
	template <class T, class Tuple, class F>
	decltype(std::declval<F>()(std::declval<T>())) WithConstructed(Tuple&& t,
	F&& f) {
	return memory_internal::WithConstructedImpl<T>(
	std::forward<Tuple>(t),
	absl::make_index_sequence<
	std::tuple_size<typename std::decay<Tuple>::type>::value>(),
	std::forward<F>(f));
	}

	// Given arguments of an std::pair's constructor, PairArgs() returns a pair of
	// tuples with references to the passed arguments. The tuples contain
	// constructor arguments for the first and the second elements of the pair.
	//
	// The following two snippets are equivalent.
	//
	// 1. std::pair<F, S> p(args...);
	//
	// 2. auto a = PairArgs(args...);
	// std::pair<F, S> p(std::piecewise_construct,
	// std::move(a.first), std::move(a.second));
	inline std::pair<std::tuple<>, std::tuple<>> PairArgs() { return {}; }
	template <class F, class S>
	std::pair<std::tuple<F&&>, std::tuple<S&&>> PairArgs(F&& f, S&& s) {
	return {std::piecewise_construct, std::forward_as_tuple(std::forward<F>(f)),
	std::forward_as_tuple(std::forward<S>(s))};
	}
	template <class F, class S>
	std::pair<std::tuple<const F&>, std::tuple<const S&>> PairArgs(
	const std::pair<F, S>& p) {
	return PairArgs(p.first, p.second);
	}
	template <class F, class S>
	std::pair<std::tuple<F&&>, std::tuple<S&&>> PairArgs(std::pair<F, S>&& p) {
	return PairArgs(std::forward<F>(p.first), std::forward<S>(p.second));
	}
	template <class F, class S>
	auto PairArgs(std::piecewise_construct_t, F&& f, S&& s)
	-> decltype(std::make_pair(memory_internal::TupleRef(std::forward<F>(f)),
	memory_internal::TupleRef(std::forward<S>(s)))) {
	return std::make_pair(memory_internal::TupleRef(std::forward<F>(f)),
	memory_internal::TupleRef(std::forward<S>(s)));
	}

	// A helper function for implementing apply() in map policies.
	template <class F, class... Args>
	auto DecomposePair(F&& f, Args&&... args)
	-> decltype(memory_internal::DecomposePairImpl(
	std::forward<F>(f), PairArgs(std::forward<Args>(args)...))) {
	return memory_internal::DecomposePairImpl(
	std::forward<F>(f), PairArgs(std::forward<Args>(args)...));
	}

	// A helper function for implementing apply() in set policies.
	template <class F, class Arg>
	decltype(std::declval<F>()(std::declval<const Arg&>(), std::declval<Arg>()))
	DecomposeValue(F&& f, Arg&& arg) {
	const auto& key = arg;
	return std::forward<F>(f)(key, std::forward<Arg>(arg));
	}

	// Helper functions for asan and msan.
	inline void SanitizerPoisonMemoryRegion(const void* m, size_t s) {
	#ifdef ABSL_HAVE_ADDRESS_SANITIZER
	ASAN_POISON_MEMORY_REGION(m, s);
	#endif
	#ifdef ABSL_HAVE_MEMORY_SANITIZER
	__msan_poison(m, s);
	#endif
	(void)m;
	(void)s;
	}

	inline void SanitizerUnpoisonMemoryRegion(const void* m, size_t s) {
	#ifdef ABSL_HAVE_ADDRESS_SANITIZER
	ASAN_UNPOISON_MEMORY_REGION(m, s);
	#endif
	#ifdef ABSL_HAVE_MEMORY_SANITIZER
	__msan_unpoison(m, s);
	#endif
	(void)m;
	(void)s;
	}

	template <typename T>
	inline void SanitizerPoisonObject(const T* object) {
	SanitizerPoisonMemoryRegion(object, sizeof(T));
	}

	template <typename T>
	inline void SanitizerUnpoisonObject(const T* object) {
	SanitizerUnpoisonMemoryRegion(object, sizeof(T));
	}

	namespace memory_internal {

	// If Pair is a standard-layout type, OffsetOf<Pair>::kFirst and
	// OffsetOf<Pair>::kSecond are equivalent to offsetof(Pair, first) and
	// offsetof(Pair, second) respectively. Otherwise they are -1.
	//
	// The purpose of OffsetOf is to avoid calling offsetof() on non-standard-layout
	// type, which is non-portable.
	template <class Pair, class = std::true_type>
	struct OffsetOf {
	static constexpr size_t kFirst = static_cast<size_t>(-1);
	static constexpr size_t kSecond = static_cast<size_t>(-1);
	};

	template <class Pair>
	struct OffsetOf<Pair, typename std::is_standard_layout<Pair>::type> {
	static constexpr size_t kFirst = offsetof(Pair, first);
	static constexpr size_t kSecond = offsetof(Pair, second);
	};

	template <class K, class V>
	struct IsLayoutCompatible {
	private:
	struct Pair {
	K first;
	V second;
	};

	// Is P layout-compatible with Pair?
	template <class P>
	static constexpr bool LayoutCompatible() {
	return std::is_standard_layout<P>() && sizeof(P) == sizeof(Pair) &&
	alignof(P) == alignof(Pair) &&
	memory_internal::OffsetOf<P>::kFirst ==
	memory_internal::OffsetOf<Pair>::kFirst &&
	memory_internal::OffsetOf<P>::kSecond ==
	memory_internal::OffsetOf<Pair>::kSecond;
	}

	public:
	// Whether pair<const K, V> and pair<K, V> are layout-compatible. If they are,
	// then it is safe to store them in a union and read from either.
	static constexpr bool value = std::is_standard_layout<K>() &&
	std::is_standard_layout<Pair>() &&
	memory_internal::OffsetOf<Pair>::kFirst == 0 &&
	LayoutCompatible<std::pair<K, V>>() &&
	LayoutCompatible<std::pair<const K, V>>();
	};

	} // namespace memory_internal

	// The internal storage type for key-value containers like flat_hash_map.
	//
	// It is convenient for the value_type of a flat_hash_map<K, V> to be
	// pair<const K, V>; the "const K" prevents accidental modification of the key
	// when dealing with the reference returned from find() and similar methods.
	// However, this creates other problems; we want to be able to emplace(K, V)
	// efficiently with move operations, and similarly be able to move a
	// pair<K, V> in insert().
	//
	// The solution is this union, which aliases the const and non-const versions
	// of the pair. This also allows flat_hash_map<const K, V> to work, even though
	// that has the same efficiency issues with move in emplace() and insert() -
	// but people do it anyway.
	//
	// If kMutableKeys is false, only the value member can be accessed.
	//
	// If kMutableKeys is true, key can be accessed through all slots while value
	// and mutable_value must be accessed only via INITIALIZED slots. Slots are
	// created and destroyed via mutable_value so that the key can be moved later.
	//
	// Accessing one of the union fields while the other is active is safe as
	// long as they are layout-compatible, which is guaranteed by the definition of
	// kMutableKeys. For C++11, the relevant section of the standard is
	// https://timsong-cpp.github.io/cppwp/n3337/class.mem#19 (9.2.19)
	template <class K, class V>
	union map_slot_type {
	map_slot_type() {}
	~map_slot_type() = delete;
	using value_type = std::pair<const K, V>;
	using mutable_value_type =
	std::pair<absl::remove_const_t<K>, absl::remove_const_t<V>>;

	value_type value;
	mutable_value_type mutable_value;
	absl::remove_const_t<K> key;
	};

	template <class K, class V>
	struct map_slot_policy {
	using slot_type = map_slot_type<K, V>;
	using value_type = std::pair<const K, V>;
	using mutable_value_type =
	std::pair<absl::remove_const_t<K>, absl::remove_const_t<V>>;

	private:
	static void emplace(slot_type* slot) {
	// The construction of union doesn't do anything at runtime but it allows us
	// to access its members without violating aliasing rules.
	new (slot) slot_type;
	}
	// If pair<const K, V> and pair<K, V> are layout-compatible, we can accept one
	// or the other via slot_type. We are also free to access the key via
	// slot_type::key in this case.
	using kMutableKeys = memory_internal::IsLayoutCompatible<K, V>;

	public:
	static value_type& element(slot_type* slot) { return slot->value; }
	static const value_type& element(const slot_type* slot) {
	return slot->value;
	}

	// When C++17 is available, we can use std::launder to provide mutable
	// access to the key for use in node handle.
	#if defined(__cpp_lib_launder) && __cpp_lib_launder >= 201606
	static K& mutable_key(slot_type* slot) {
	// Still check for kMutableKeys so that we can avoid calling std::launder
	// unless necessary because it can interfere with optimizations.
	return kMutableKeys::value ? slot->key
	: std::launder(const_cast<K>(
	std::addressof(slot->value.first)));
	}
	#else // !(defined(__cpp_lib_launder) && __cpp_lib_launder >= 201606)
	static const K& mutable_key(slot_type* slot) { return key(slot); }
	#endif

	static const K& key(const slot_type* slot) {
	return kMutableKeys::value ? slot->key : slot->value.first;
	}

	template <class Allocator, class... Args>
	static void construct(Allocator* alloc, slot_type* slot, Args&&... args) {
	emplace(slot);
	if (kMutableKeys::value) {
	absl::allocator_traits<Allocator>::construct(*alloc, &slot->mutable_value,
	std::forward<Args>(args)...);
	} else {
	absl::allocator_traits<Allocator>::construct(*alloc, &slot->value,
	std::forward<Args>(args)...);
	}
	}

	// Construct this slot by moving from another slot.
	template <class Allocator>
	static void construct(Allocator* alloc, slot_type* slot, slot_type* other) {
	emplace(slot);
	if (kMutableKeys::value) {
	absl::allocator_traits<Allocator>::construct(
	*alloc, &slot->mutable_value, std::move(other->mutable_value));
	} else {
	absl::allocator_traits<Allocator>::construct(*alloc, &slot->value,
	std::move(other->value));
	}
	}

	// Construct this slot by copying from another slot.
	template <class Allocator>
	static void construct(Allocator* alloc, slot_type* slot,
	const slot_type* other) {
	emplace(slot);
	absl::allocator_traits<Allocator>::construct(*alloc, &slot->value,
	other->value);
	}

	template <class Allocator>
	static auto destroy(Allocator* alloc, slot_type* slot) {
	if (kMutableKeys::value) {
	absl::allocator_traits<Allocator>::destroy(*alloc, &slot->mutable_value);
	} else {
	absl::allocator_traits<Allocator>::destroy(*alloc, &slot->value);
	}
	return IsDestructionTrivial<Allocator, value_type>();
	}

	template <class Allocator>
	static auto transfer(Allocator* alloc, slot_type* new_slot,
	slot_type* old_slot) {
	auto is_relocatable =
	typename absl::is_trivially_relocatable<value_type>::type();

	emplace(new_slot);
	#if defined(__cpp_lib_launder) && __cpp_lib_launder >= 201606
	if (is_relocatable) {
	// TODO(b/247130232,b/251814870): remove casts after fixing warnings.
	std::memcpy(static_cast<void*>(std::launder(&new_slot->value)),
	static_cast<const void*>(&old_slot->value),
	sizeof(value_type));
	return is_relocatable;
	}
	#endif

	if (kMutableKeys::value) {
	absl::allocator_traits<Allocator>::construct(
	*alloc, &new_slot->mutable_value, std::move(old_slot->mutable_value));
	} else {
	absl::allocator_traits<Allocator>::construct(*alloc, &new_slot->value,
	std::move(old_slot->value));
	}
	destroy(alloc, old_slot);
	return is_relocatable;
	}
	};

	// Type erased function for computing hash of the slot.
	using HashSlotFn = size_t ()(const void hash_fn, void* slot);

	// Type erased function to apply `Fn` to data inside of the `slot`.
	// The data is expected to have type `T`.
	template <class Fn, class T>
	size_t TypeErasedApplyToSlotFn(const void* fn, void* slot) {
	const auto* f = static_cast<const Fn*>(fn);
	return (f)(static_cast<const T*>(slot));
	}

	// Type erased function to apply `Fn` to data inside of the `*slot_ptr`.
	// The data is expected to have type `T`.
	template <class Fn, class T>
	size_t TypeErasedDerefAndApplyToSlotFn(const void* fn, void* slot_ptr) {
	const auto* f = static_cast<const Fn*>(fn);
	const T* slot = static_cast<const T*>(slot_ptr);
	return (f)(slot);
	}

	} // namespace container_internal
	ABSL_NAMESPACE_END
	} // namespace absl

	#endif // ABSL_CONTAINER_INTERNAL_CONTAINER_MEMORY_H_