rtc_base/containers/flat_map.h - src/ - Git at Google

 /*
  *  Copyright (c) 2021 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 // This implementation is borrowed from Chromium.

 #ifndef RTC_BASE_CONTAINERS_FLAT_MAP_H_
 #define RTC_BASE_CONTAINERS_FLAT_MAP_H_

 #include <functional>
 #include <tuple>
 #include <utility>
 #include <vector>

 #include "rtc_base/checks.h"
 #include "rtc_base/containers/flat_tree.h"  // IWYU pragma: export

 namespace webrtc {

 namespace flat_containers_internal {

 // An implementation of the flat_tree GetKeyFromValue template parameter that
 // extracts the key as the first element of a pair.
 struct GetFirst {
   template <class Key, class Mapped>
   constexpr const Key& operator()(const std::pair<Key, Mapped>& p) const {
     return p.first;
   }
 };

 }  // namespace flat_containers_internal

 // flat_map is a container with a std::map-like interface that stores its
 // contents in a sorted container, by default a vector.
 //
 // Its implementation mostly tracks the corresponding standardization proposal
 // https://wg21.link/P0429, except that the storage of keys and values is not
 // split.
 //
 // PROS
 //
 //  - Good memory locality.
 //  - Low overhead, especially for smaller maps.
 //  - Performance is good for more workloads than you might expect (see
 //    //base/containers/README.md in Chromium repository)
 //  - Supports C++14 map interface.
 //
 // CONS
 //
 //  - Inserts and removals are O(n).
 //
 // IMPORTANT NOTES
 //
 //  - Iterators are invalidated across mutations. This means that the following
 //    line of code has undefined behavior since adding a new element could
 //    resize the container, invalidating all iterators:
 //      container["new element"] = it.second;
 //  - If possible, construct a flat_map in one operation by inserting into
 //    a container and moving that container into the flat_map constructor.
 //
 // QUICK REFERENCE
 //
 // Most of the core functionality is inherited from flat_tree. Please see
 // flat_tree.h for more details for most of these functions. As a quick
 // reference, the functions available are:
 //
 // Constructors (inputs need not be sorted):
 //   flat_map(const flat_map&);
 //   flat_map(flat_map&&);
 //   flat_map(InputIterator first, InputIterator last,
 //            const Compare& compare = Compare());
 //   flat_map(const container_type& items,
 //            const Compare& compare = Compare());
 //   flat_map(container_type&& items,
 //            const Compare& compare = Compare()); // Re-use storage.
 //   flat_map(std::initializer_list<value_type> ilist,
 //            const Compare& comp = Compare());
 //
 // Constructors (inputs need to be sorted):
 //   flat_map(sorted_unique_t,
 //            InputIterator first, InputIterator last,
 //            const Compare& compare = Compare());
 //   flat_map(sorted_unique_t,
 //            const container_type& items,
 //            const Compare& compare = Compare());
 //   flat_map(sorted_unique_t,
 //            container_type&& items,
 //            const Compare& compare = Compare());  // Re-use storage.
 //   flat_map(sorted_unique_t,
 //            std::initializer_list<value_type> ilist,
 //            const Compare& comp = Compare());
 //
 // Assignment functions:
 //   flat_map& operator=(const flat_map&);
 //   flat_map& operator=(flat_map&&);
 //   flat_map& operator=(initializer_list<value_type>);
 //
 // Memory management functions:
 //   void   reserve(size_t);
 //   size_t capacity() const;
 //   void   shrink_to_fit();
 //
 // Size management functions:
 //   void   clear();
 //   size_t size() const;
 //   size_t max_size() const;
 //   bool   empty() const;
 //
 // Iterator functions:
 //   iterator               begin();
 //   const_iterator         begin() const;
 //   const_iterator         cbegin() const;
 //   iterator               end();
 //   const_iterator         end() const;
 //   const_iterator         cend() const;
 //   reverse_iterator       rbegin();
 //   const reverse_iterator rbegin() const;
 //   const_reverse_iterator crbegin() const;
 //   reverse_iterator       rend();
 //   const_reverse_iterator rend() const;
 //   const_reverse_iterator crend() const;
 //
 // Insert and accessor functions:
 //   mapped_type&         operator[](const key_type&);
 //   mapped_type&         operator[](key_type&&);
 //   mapped_type&         at(const K&);
 //   const mapped_type&   at(const K&) const;
 //   pair<iterator, bool> insert(const value_type&);
 //   pair<iterator, bool> insert(value_type&&);
 //   iterator             insert(const_iterator hint, const value_type&);
 //   iterator             insert(const_iterator hint, value_type&&);
 //   void                 insert(InputIterator first, InputIterator last);
 //   pair<iterator, bool> insert_or_assign(K&&, M&&);
 //   iterator             insert_or_assign(const_iterator hint, K&&, M&&);
 //   pair<iterator, bool> emplace(Args&&...);
 //   iterator             emplace_hint(const_iterator, Args&&...);
 //   pair<iterator, bool> try_emplace(K&&, Args&&...);
 //   iterator             try_emplace(const_iterator hint, K&&, Args&&...);

 // Underlying type functions:
 //   container_type       extract() &&;
 //   void                 replace(container_type&&);
 //
 // Erase functions:
 //   iterator erase(iterator);
 //   iterator erase(const_iterator);
 //   iterator erase(const_iterator first, const_iterator& last);
 //   template <class K> size_t erase(const K& key);
 //
 // Comparators (see std::map documentation).
 //   key_compare   key_comp() const;
 //   value_compare value_comp() const;
 //
 // Search functions:
 //   template <typename K> size_t                   count(const K&) const;
 //   template <typename K> iterator                 find(const K&);
 //   template <typename K> const_iterator           find(const K&) const;
 //   template <typename K> bool                     contains(const K&) const;
 //   template <typename K> pair<iterator, iterator> equal_range(const K&);
 //   template <typename K> iterator                 lower_bound(const K&);
 //   template <typename K> const_iterator           lower_bound(const K&) const;
 //   template <typename K> iterator                 upper_bound(const K&);
 //   template <typename K> const_iterator           upper_bound(const K&) const;
 //
 // General functions:
 //   void swap(flat_map&);
 //
 // Non-member operators:
 //   bool operator==(const flat_map&, const flat_map);
 //   bool operator!=(const flat_map&, const flat_map);
 //   bool operator<(const flat_map&, const flat_map);
 //   bool operator>(const flat_map&, const flat_map);
 //   bool operator>=(const flat_map&, const flat_map);
 //   bool operator<=(const flat_map&, const flat_map);
 //
 template <class Key,
           class Mapped,
           class Compare = std::less<>,
           class Container = std::vector<std::pair<Key, Mapped>>>
 class flat_map : public ::webrtc::flat_containers_internal::flat_tree<
                      Key,
                      flat_containers_internal::GetFirst,
                      Compare,
                      Container> {
  private:
   using tree = typename ::webrtc::flat_containers_internal::
       flat_tree<Key, flat_containers_internal::GetFirst, Compare, Container>;

  public:
   using key_type = typename tree::key_type;
   using mapped_type = Mapped;
   using value_type = typename tree::value_type;
   using reference = typename Container::reference;
   using const_reference = typename Container::const_reference;
   using size_type = typename Container::size_type;
   using difference_type = typename Container::difference_type;
   using iterator = typename tree::iterator;
   using const_iterator = typename tree::const_iterator;
   using reverse_iterator = typename tree::reverse_iterator;
   using const_reverse_iterator = typename tree::const_reverse_iterator;
   using container_type = typename tree::container_type;

   // --------------------------------------------------------------------------
   // Lifetime and assignments.
   //
   // Note: we explicitly bring operator= in because otherwise
   //   flat_map<...> x;
   //   x = {...};
   // Would first create a flat_map and then move assign it. This most likely
   // would be optimized away but still affects our debug builds.

   using tree::tree;
   using tree::operator=;

   // Out-of-bound calls to at() will CHECK.
   template <class K>
   mapped_type& at(const K& key);
   template <class K>
   const mapped_type& at(const K& key) const;

   // --------------------------------------------------------------------------
   // Map-specific insert operations.
   //
   // Normal insert() functions are inherited from flat_tree.
   //
   // Assume that every operation invalidates iterators and references.
   // Insertion of one element can take O(size).

   mapped_type& operator[](const key_type& key);
   mapped_type& operator[](key_type&& key);

   template <class K, class M>
   std::pair<iterator, bool> insert_or_assign(K&& key, M&& obj);
   template <class K, class M>
   iterator insert_or_assign(const_iterator hint, K&& key, M&& obj);

   template <class K, class... Args>
   std::enable_if_t<std::is_constructible<key_type, K&&>::value,
                    std::pair<iterator, bool>>
   try_emplace(K&& key, Args&&... args);

   template <class K, class... Args>
   std::enable_if_t<std::is_constructible<key_type, K&&>::value, iterator>
   try_emplace(const_iterator hint, K&& key, Args&&... args);

   // --------------------------------------------------------------------------
   // General operations.
   //
   // Assume that swap invalidates iterators and references.

   void swap(flat_map& other) noexcept;

   friend void swap(flat_map& lhs, flat_map& rhs) noexcept { lhs.swap(rhs); }
 };

 // ----------------------------------------------------------------------------
 // Lookups.

 template <class Key, class Mapped, class Compare, class Container>
 template <class K>
 auto flat_map<Key, Mapped, Compare, Container>::at(const K& key)
     -> mapped_type& {
   iterator found = tree::find(key);
   RTC_CHECK(found != tree::end());
   return found->second;
 }

 template <class Key, class Mapped, class Compare, class Container>
 template <class K>
 auto flat_map<Key, Mapped, Compare, Container>::at(const K& key) const
     -> const mapped_type& {
   const_iterator found = tree::find(key);
   RTC_CHECK(found != tree::cend());
   return found->second;
 }

 // ----------------------------------------------------------------------------
 // Insert operations.

 template <class Key, class Mapped, class Compare, class Container>
 auto flat_map<Key, Mapped, Compare, Container>::operator[](const key_type& key)
     -> mapped_type& {
   iterator found = tree::lower_bound(key);
   if (found == tree::end() || tree::key_comp()(key, found->first))
     found = tree::unsafe_emplace(found, key, mapped_type());
   return found->second;
 }

 template <class Key, class Mapped, class Compare, class Container>
 auto flat_map<Key, Mapped, Compare, Container>::operator[](key_type&& key)
     -> mapped_type& {
   iterator found = tree::lower_bound(key);
   if (found == tree::end() || tree::key_comp()(key, found->first))
     found = tree::unsafe_emplace(found, std::move(key), mapped_type());
   return found->second;
 }

 template <class Key, class Mapped, class Compare, class Container>
 template <class K, class M>
 auto flat_map<Key, Mapped, Compare, Container>::insert_or_assign(K&& key,
                                                                  M&& obj)
     -> std::pair<iterator, bool> {
   auto result =
       tree::emplace_key_args(key, std::forward<K>(key), std::forward<M>(obj));
   if (!result.second)
     result.first->second = std::forward<M>(obj);
   return result;
 }

 template <class Key, class Mapped, class Compare, class Container>
 template <class K, class M>
 auto flat_map<Key, Mapped, Compare, Container>::insert_or_assign(
     const_iterator hint,
     K&& key,
     M&& obj) -> iterator {
   auto result = tree::emplace_hint_key_args(hint, key, std::forward<K>(key),
                                             std::forward<M>(obj));
   if (!result.second)
     result.first->second = std::forward<M>(obj);
   return result.first;
 }

 template <class Key, class Mapped, class Compare, class Container>
 template <class K, class... Args>
 auto flat_map<Key, Mapped, Compare, Container>::try_emplace(K&& key,
                                                             Args&&... args)
     -> std::enable_if_t<std::is_constructible<key_type, K&&>::value,
                         std::pair<iterator, bool>> {
   return tree::emplace_key_args(
       key, std::piecewise_construct,
       std::forward_as_tuple(std::forward<K>(key)),
       std::forward_as_tuple(std::forward<Args>(args)...));
 }

 template <class Key, class Mapped, class Compare, class Container>
 template <class K, class... Args>
 auto flat_map<Key, Mapped, Compare, Container>::try_emplace(const_iterator hint,
                                                             K&& key,
                                                             Args&&... args)
     -> std::enable_if_t<std::is_constructible<key_type, K&&>::value, iterator> {
   return tree::emplace_hint_key_args(
              hint, key, std::piecewise_construct,
              std::forward_as_tuple(std::forward<K>(key)),
              std::forward_as_tuple(std::forward<Args>(args)...))
       .first;
 }

 // ----------------------------------------------------------------------------
 // General operations.

 template <class Key, class Mapped, class Compare, class Container>
 void flat_map<Key, Mapped, Compare, Container>::swap(flat_map& other) noexcept {
   tree::swap(other);
 }

 // Erases all elements that match predicate. It has O(size) complexity.
 //
 //  flat_map<int, Timestamp> last_times;
 //  ...
 //  EraseIf(last_times,
 //          [&](const auto& element) { return now - element.second > kLimit; });

 // NOLINTNEXTLINE(misc-unused-using-decls)
 using ::webrtc::flat_containers_internal::EraseIf;

 }  // namespace webrtc

 #endif  // RTC_BASE_CONTAINERS_FLAT_MAP_H_
	/*
	* Copyright (c) 2021 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	// This implementation is borrowed from Chromium.

	#ifndef RTC_BASE_CONTAINERS_FLAT_MAP_H_
	#define RTC_BASE_CONTAINERS_FLAT_MAP_H_

	#include <functional>
	#include <tuple>
	#include <utility>
	#include <vector>

	#include "rtc_base/checks.h"
	#include "rtc_base/containers/flat_tree.h" // IWYU pragma: export

	namespace webrtc {

	namespace flat_containers_internal {

	// An implementation of the flat_tree GetKeyFromValue template parameter that
	// extracts the key as the first element of a pair.
	struct GetFirst {
	template <class Key, class Mapped>
	constexpr const Key& operator()(const std::pair<Key, Mapped>& p) const {
	return p.first;
	}
	};

	} // namespace flat_containers_internal

	// flat_map is a container with a std::map-like interface that stores its
	// contents in a sorted container, by default a vector.
	//
	// Its implementation mostly tracks the corresponding standardization proposal
	// https://wg21.link/P0429, except that the storage of keys and values is not
	// split.
	//
	// PROS
	//
	// - Good memory locality.
	// - Low overhead, especially for smaller maps.
	// - Performance is good for more workloads than you might expect (see
	// //base/containers/README.md in Chromium repository)
	// - Supports C++14 map interface.
	//
	// CONS
	//
	// - Inserts and removals are O(n).
	//
	// IMPORTANT NOTES
	//
	// - Iterators are invalidated across mutations. This means that the following
	// line of code has undefined behavior since adding a new element could
	// resize the container, invalidating all iterators:
	// container["new element"] = it.second;
	// - If possible, construct a flat_map in one operation by inserting into
	// a container and moving that container into the flat_map constructor.
	//
	// QUICK REFERENCE
	//
	// Most of the core functionality is inherited from flat_tree. Please see
	// flat_tree.h for more details for most of these functions. As a quick
	// reference, the functions available are:
	//
	// Constructors (inputs need not be sorted):
	// flat_map(const flat_map&);
	// flat_map(flat_map&&);
	// flat_map(InputIterator first, InputIterator last,
	// const Compare& compare = Compare());
	// flat_map(const container_type& items,
	// const Compare& compare = Compare());
	// flat_map(container_type&& items,
	// const Compare& compare = Compare()); // Re-use storage.
	// flat_map(std::initializer_list<value_type> ilist,
	// const Compare& comp = Compare());
	//
	// Constructors (inputs need to be sorted):
	// flat_map(sorted_unique_t,
	// InputIterator first, InputIterator last,
	// const Compare& compare = Compare());
	// flat_map(sorted_unique_t,
	// const container_type& items,
	// const Compare& compare = Compare());
	// flat_map(sorted_unique_t,
	// container_type&& items,
	// const Compare& compare = Compare()); // Re-use storage.
	// flat_map(sorted_unique_t,
	// std::initializer_list<value_type> ilist,
	// const Compare& comp = Compare());
	//
	// Assignment functions:
	// flat_map& operator=(const flat_map&);
	// flat_map& operator=(flat_map&&);
	// flat_map& operator=(initializer_list<value_type>);
	//
	// Memory management functions:
	// void reserve(size_t);
	// size_t capacity() const;
	// void shrink_to_fit();
	//
	// Size management functions:
	// void clear();
	// size_t size() const;
	// size_t max_size() const;
	// bool empty() const;
	//
	// Iterator functions:
	// iterator begin();
	// const_iterator begin() const;
	// const_iterator cbegin() const;
	// iterator end();
	// const_iterator end() const;
	// const_iterator cend() const;
	// reverse_iterator rbegin();
	// const reverse_iterator rbegin() const;
	// const_reverse_iterator crbegin() const;
	// reverse_iterator rend();
	// const_reverse_iterator rend() const;
	// const_reverse_iterator crend() const;
	//
	// Insert and accessor functions:
	// mapped_type& operator[](const key_type&);
	// mapped_type& operator[](key_type&&);
	// mapped_type& at(const K&);
	// const mapped_type& at(const K&) const;
	// pair<iterator, bool> insert(const value_type&);
	// pair<iterator, bool> insert(value_type&&);
	// iterator insert(const_iterator hint, const value_type&);
	// iterator insert(const_iterator hint, value_type&&);
	// void insert(InputIterator first, InputIterator last);
	// pair<iterator, bool> insert_or_assign(K&&, M&&);
	// iterator insert_or_assign(const_iterator hint, K&&, M&&);
	// pair<iterator, bool> emplace(Args&&...);
	// iterator emplace_hint(const_iterator, Args&&...);
	// pair<iterator, bool> try_emplace(K&&, Args&&...);
	// iterator try_emplace(const_iterator hint, K&&, Args&&...);

	// Underlying type functions:
	// container_type extract() &&;
	// void replace(container_type&&);
	//
	// Erase functions:
	// iterator erase(iterator);
	// iterator erase(const_iterator);
	// iterator erase(const_iterator first, const_iterator& last);
	// template <class K> size_t erase(const K& key);
	//
	// Comparators (see std::map documentation).
	// key_compare key_comp() const;
	// value_compare value_comp() const;
	//
	// Search functions:
	// template <typename K> size_t count(const K&) const;
	// template <typename K> iterator find(const K&);
	// template <typename K> const_iterator find(const K&) const;
	// template <typename K> bool contains(const K&) const;
	// template <typename K> pair<iterator, iterator> equal_range(const K&);
	// template <typename K> iterator lower_bound(const K&);
	// template <typename K> const_iterator lower_bound(const K&) const;
	// template <typename K> iterator upper_bound(const K&);
	// template <typename K> const_iterator upper_bound(const K&) const;
	//
	// General functions:
	// void swap(flat_map&);
	//
	// Non-member operators:
	// bool operator==(const flat_map&, const flat_map);
	// bool operator!=(const flat_map&, const flat_map);
	// bool operator<(const flat_map&, const flat_map);
	// bool operator>(const flat_map&, const flat_map);
	// bool operator>=(const flat_map&, const flat_map);
	// bool operator<=(const flat_map&, const flat_map);
	//
	template <class Key,
	class Mapped,
	class Compare = std::less<>,
	class Container = std::vector<std::pair<Key, Mapped>>>
	class flat_map : public ::webrtc::flat_containers_internal::flat_tree<
	Key,
	flat_containers_internal::GetFirst,
	Compare,
	Container> {
	private:
	using tree = typename ::webrtc::flat_containers_internal::
	flat_tree<Key, flat_containers_internal::GetFirst, Compare, Container>;

	public:
	using key_type = typename tree::key_type;
	using mapped_type = Mapped;
	using value_type = typename tree::value_type;
	using reference = typename Container::reference;
	using const_reference = typename Container::const_reference;
	using size_type = typename Container::size_type;
	using difference_type = typename Container::difference_type;
	using iterator = typename tree::iterator;
	using const_iterator = typename tree::const_iterator;
	using reverse_iterator = typename tree::reverse_iterator;
	using const_reverse_iterator = typename tree::const_reverse_iterator;
	using container_type = typename tree::container_type;

	// --------------------------------------------------------------------------
	// Lifetime and assignments.
	//
	// Note: we explicitly bring operator= in because otherwise
	// flat_map<...> x;
	// x = {...};
	// Would first create a flat_map and then move assign it. This most likely
	// would be optimized away but still affects our debug builds.

	using tree::tree;
	using tree::operator=;

	// Out-of-bound calls to at() will CHECK.
	template <class K>
	mapped_type& at(const K& key);
	template <class K>
	const mapped_type& at(const K& key) const;

	// --------------------------------------------------------------------------
	// Map-specific insert operations.
	//
	// Normal insert() functions are inherited from flat_tree.
	//
	// Assume that every operation invalidates iterators and references.
	// Insertion of one element can take O(size).

	mapped_type& operator[](const key_type& key);
	mapped_type& operator[](key_type&& key);

	template <class K, class M>
	std::pair<iterator, bool> insert_or_assign(K&& key, M&& obj);
	template <class K, class M>
	iterator insert_or_assign(const_iterator hint, K&& key, M&& obj);

	template <class K, class... Args>
	std::enable_if_t<std::is_constructible<key_type, K&&>::value,
	std::pair<iterator, bool>>
	try_emplace(K&& key, Args&&... args);

	template <class K, class... Args>
	std::enable_if_t<std::is_constructible<key_type, K&&>::value, iterator>
	try_emplace(const_iterator hint, K&& key, Args&&... args);

	// --------------------------------------------------------------------------
	// General operations.
	//
	// Assume that swap invalidates iterators and references.

	void swap(flat_map& other) noexcept;

	friend void swap(flat_map& lhs, flat_map& rhs) noexcept { lhs.swap(rhs); }
	};

	// ----------------------------------------------------------------------------
	// Lookups.

	template <class Key, class Mapped, class Compare, class Container>
	template <class K>
	auto flat_map<Key, Mapped, Compare, Container>::at(const K& key)
	-> mapped_type& {
	iterator found = tree::find(key);
	RTC_CHECK(found != tree::end());
	return found->second;
	}

	template <class Key, class Mapped, class Compare, class Container>
	template <class K>
	auto flat_map<Key, Mapped, Compare, Container>::at(const K& key) const
	-> const mapped_type& {
	const_iterator found = tree::find(key);
	RTC_CHECK(found != tree::cend());
	return found->second;
	}

	// ----------------------------------------------------------------------------
	// Insert operations.

	template <class Key, class Mapped, class Compare, class Container>
	auto flat_map<Key, Mapped, Compare, Container>::operator[](const key_type& key)
	-> mapped_type& {
	iterator found = tree::lower_bound(key);
	if (found == tree::end() \|\| tree::key_comp()(key, found->first))
	found = tree::unsafe_emplace(found, key, mapped_type());
	return found->second;
	}

	template <class Key, class Mapped, class Compare, class Container>
	auto flat_map<Key, Mapped, Compare, Container>::operator[](key_type&& key)
	-> mapped_type& {
	iterator found = tree::lower_bound(key);
	if (found == tree::end() \|\| tree::key_comp()(key, found->first))
	found = tree::unsafe_emplace(found, std::move(key), mapped_type());
	return found->second;
	}

	template <class Key, class Mapped, class Compare, class Container>
	template <class K, class M>
	auto flat_map<Key, Mapped, Compare, Container>::insert_or_assign(K&& key,
	M&& obj)
	-> std::pair<iterator, bool> {
	auto result =
	tree::emplace_key_args(key, std::forward<K>(key), std::forward<M>(obj));
	if (!result.second)
	result.first->second = std::forward<M>(obj);
	return result;
	}

	template <class Key, class Mapped, class Compare, class Container>
	template <class K, class M>
	auto flat_map<Key, Mapped, Compare, Container>::insert_or_assign(
	const_iterator hint,
	K&& key,
	M&& obj) -> iterator {
	auto result = tree::emplace_hint_key_args(hint, key, std::forward<K>(key),
	std::forward<M>(obj));
	if (!result.second)
	result.first->second = std::forward<M>(obj);
	return result.first;
	}

	template <class Key, class Mapped, class Compare, class Container>
	template <class K, class... Args>
	auto flat_map<Key, Mapped, Compare, Container>::try_emplace(K&& key,
	Args&&... args)
	-> std::enable_if_t<std::is_constructible<key_type, K&&>::value,
	std::pair<iterator, bool>> {
	return tree::emplace_key_args(
	key, std::piecewise_construct,
	std::forward_as_tuple(std::forward<K>(key)),
	std::forward_as_tuple(std::forward<Args>(args)...));
	}

	template <class Key, class Mapped, class Compare, class Container>
	template <class K, class... Args>
	auto flat_map<Key, Mapped, Compare, Container>::try_emplace(const_iterator hint,
	K&& key,
	Args&&... args)
	-> std::enable_if_t<std::is_constructible<key_type, K&&>::value, iterator> {
	return tree::emplace_hint_key_args(
	hint, key, std::piecewise_construct,
	std::forward_as_tuple(std::forward<K>(key)),
	std::forward_as_tuple(std::forward<Args>(args)...))
	.first;
	}

	// ----------------------------------------------------------------------------
	// General operations.

	template <class Key, class Mapped, class Compare, class Container>
	void flat_map<Key, Mapped, Compare, Container>::swap(flat_map& other) noexcept {
	tree::swap(other);
	}

	// Erases all elements that match predicate. It has O(size) complexity.
	//
	// flat_map<int, Timestamp> last_times;
	// ...
	// EraseIf(last_times,
	// [&](const auto& element) { return now - element.second > kLimit; });

	// NOLINTNEXTLINE(misc-unused-using-decls)
	using ::webrtc::flat_containers_internal::EraseIf;

	} // namespace webrtc

	#endif // RTC_BASE_CONTAINERS_FLAT_MAP_H_