STL/stl/inc/map

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C++

// map standard header
// Copyright (c) Microsoft Corporation.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
#pragma once
#ifndef _MAP_
#define _MAP_
#include <yvals_core.h>
#if _STL_COMPILER_PREPROCESSOR
#include <tuple>
#include <xtree>
#if _HAS_CXX17
#include <xpolymorphic_allocator.h>
#endif // _HAS_CXX17
#pragma pack(push, _CRT_PACKING)
#pragma warning(push, _STL_WARNING_LEVEL)
#pragma warning(disable : _STL_DISABLED_WARNINGS)
_STL_DISABLE_CLANG_WARNINGS
#pragma push_macro("new")
#undef new
_STD_BEGIN
// CLASS TEMPLATE _Tmap_traits
template <class _Kty, // key type
class _Ty, // mapped type
class _Pr, // comparator predicate type
class _Alloc, // actual allocator type (should be value allocator)
bool _Mfl> // true if multiple equivalent keys are permitted
class _Tmap_traits { // traits required to make _Tree behave like a map
public:
using key_type = _Kty;
using value_type = pair<const _Kty, _Ty>;
using key_compare = _Pr;
using allocator_type = _Alloc;
#if _HAS_CXX17
using node_type = _Node_handle<_Tree_node<value_type, typename allocator_traits<_Alloc>::void_pointer>, _Alloc,
_Node_handle_map_base, _Kty, _Ty>;
#endif // _HAS_CXX17
static constexpr bool _Multi = _Mfl;
template <class... _Args>
using _In_place_key_extractor = _In_place_key_extract_map<_Kty, _Args...>;
class value_compare {
public:
_CXX17_DEPRECATE_ADAPTOR_TYPEDEFS typedef value_type _FIRST_ARGUMENT_TYPE_NAME;
_CXX17_DEPRECATE_ADAPTOR_TYPEDEFS typedef value_type _SECOND_ARGUMENT_TYPE_NAME;
_CXX17_DEPRECATE_ADAPTOR_TYPEDEFS typedef bool _RESULT_TYPE_NAME;
_NODISCARD bool operator()(const value_type& _Left, const value_type& _Right) const {
// test if _Left precedes _Right by comparing just keys
return comp(_Left.first, _Right.first);
}
protected:
friend _Tree<_Tmap_traits>;
value_compare(key_compare _Pred) : comp(_Pred) {}
key_compare comp; // the comparator predicate for keys
};
template <class _Ty1, class _Ty2>
static const _Kty& _Kfn(const pair<_Ty1, _Ty2>& _Val) { // extract key from element value
return _Val.first;
}
};
// CLASS TEMPLATE map
template <class _Kty, class _Ty, class _Pr = less<_Kty>, class _Alloc = allocator<pair<const _Kty, _Ty>>>
class map : public _Tree<_Tmap_traits<_Kty, _Ty, _Pr, _Alloc, false>> {
// ordered red-black tree of {key, mapped} values, unique keys
public:
static_assert(!_ENFORCE_MATCHING_ALLOCATORS || is_same_v<pair<const _Kty, _Ty>, typename _Alloc::value_type>,
_MISMATCHED_ALLOCATOR_MESSAGE("map<Key, Value, Compare, Allocator>", "pair<const Key, Value>"));
using _Mybase = _Tree<_Tmap_traits<_Kty, _Ty, _Pr, _Alloc, false>>;
using _Nodeptr = typename _Mybase::_Nodeptr;
using key_type = _Kty;
using mapped_type = _Ty;
using key_compare = _Pr;
using value_compare = typename _Mybase::value_compare;
using value_type = pair<const _Kty, _Ty>;
using allocator_type = typename _Mybase::allocator_type;
using size_type = typename _Mybase::size_type;
using difference_type = typename _Mybase::difference_type;
using pointer = typename _Mybase::pointer;
using const_pointer = typename _Mybase::const_pointer;
using reference = value_type&;
using const_reference = const value_type&;
using iterator = typename _Mybase::iterator;
using const_iterator = typename _Mybase::const_iterator;
using reverse_iterator = typename _Mybase::reverse_iterator;
using const_reverse_iterator = typename _Mybase::const_reverse_iterator;
using _Alnode = typename _Mybase::_Alnode;
using _Alnode_traits = typename _Mybase::_Alnode_traits;
#if _HAS_CXX17
using insert_return_type = _Insert_return_type<iterator, typename _Mybase::node_type>;
#endif // _HAS_CXX17
map() : _Mybase(key_compare()) {}
explicit map(const allocator_type& _Al) : _Mybase(key_compare(), _Al) {}
map(const map& _Right) : _Mybase(_Right, _Alnode_traits::select_on_container_copy_construction(_Right._Getal())) {}
map(const map& _Right, const allocator_type& _Al) : _Mybase(_Right, _Al) {}
explicit map(const key_compare& _Pred) : _Mybase(_Pred) {}
map(const key_compare& _Pred, const allocator_type& _Al) : _Mybase(_Pred, _Al) {}
template <class _Iter>
map(_Iter _First, _Iter _Last) : _Mybase(key_compare()) {
insert(_First, _Last);
}
template <class _Iter>
map(_Iter _First, _Iter _Last, const key_compare& _Pred) : _Mybase(_Pred) {
insert(_First, _Last);
}
template <class _Iter>
map(_Iter _First, _Iter _Last, const allocator_type& _Al) : _Mybase(key_compare(), _Al) {
insert(_First, _Last);
}
template <class _Iter>
map(_Iter _First, _Iter _Last, const key_compare& _Pred, const allocator_type& _Al) : _Mybase(_Pred, _Al) {
insert(_First, _Last);
}
map& operator=(const map& _Right) {
_Mybase::operator=(_Right);
return *this;
}
map(map&& _Right) : _Mybase(_STD move(_Right)) {}
map(map&& _Right, const allocator_type& _Al) : _Mybase(_STD move(_Right), _Al) {}
map& operator=(map&& _Right) noexcept(_Alnode_traits::is_always_equal::value&& is_nothrow_move_assignable_v<_Pr>) {
_Mybase::operator=(_STD move(_Right));
return *this;
}
mapped_type& operator[](key_type&& _Keyval) { // find element matching _Keyval or insert value-initialized value
return _Try_emplace(_STD move(_Keyval)).first->_Myval.second;
}
void swap(map& _Right) noexcept(noexcept(_Mybase::swap(_Right))) {
_Mybase::swap(_Right);
}
using _Mybase::insert;
template <class _Valty, enable_if_t<is_constructible_v<value_type, _Valty>, int> = 0>
pair<iterator, bool> insert(_Valty&& _Val) {
return this->emplace(_STD forward<_Valty>(_Val));
}
template <class _Valty, enable_if_t<is_constructible_v<value_type, _Valty>, int> = 0>
iterator insert(const_iterator _Where, _Valty&& _Val) {
return this->emplace_hint(_Where, _STD forward<_Valty>(_Val));
}
private:
template <class _Keyty, class... _Mappedty>
pair<_Nodeptr, bool> _Try_emplace(_Keyty&& _Keyval, _Mappedty&&... _Mapval) {
const auto _Loc = _Mybase::_Find_lower_bound(_Keyval);
if (_Mybase::_Lower_bound_duplicate(_Loc._Bound, _Keyval)) {
return {_Loc._Bound, false};
}
_Mybase::_Check_grow_by_1();
const auto _Scary = _Mybase::_Get_scary();
const auto _Inserted = _Tree_temp_node<_Alnode>(_Mybase::_Getal(), _Scary->_Myhead, piecewise_construct,
_STD forward_as_tuple(_STD forward<_Keyty>(_Keyval)),
_STD forward_as_tuple(_STD forward<_Mappedty>(_Mapval)...))
._Release();
// nothrow hereafter
return {_Scary->_Insert_node(_Loc._Location, _Inserted), true};
}
template <class _Keyty, class... _Mappedty>
_Nodeptr _Try_emplace_hint(const _Nodeptr _Hint, _Keyty&& _Keyval, _Mappedty&&... _Mapval) {
const auto _Loc = _Mybase::_Find_hint(_Hint, _Keyval);
if (_Loc._Duplicate) {
return _Loc._Location._Parent;
}
_Mybase::_Check_grow_by_1();
const auto _Scary = _Mybase::_Get_scary();
const auto _Inserted = _Tree_temp_node<_Alnode>(_Mybase::_Getal(), _Scary->_Myhead, piecewise_construct,
_STD forward_as_tuple(_STD forward<_Keyty>(_Keyval)),
_STD forward_as_tuple(_STD forward<_Mappedty>(_Mapval)...))
._Release();
// nothrow hereafter
return _Scary->_Insert_node(_Loc._Location, _Inserted);
}
public:
template <class... _Mappedty>
pair<iterator, bool> try_emplace(const key_type& _Keyval, _Mappedty&&... _Mapval) {
const auto _Result = _Try_emplace(_Keyval, _STD forward<_Mappedty>(_Mapval)...);
return {iterator(_Result.first, _Mybase::_Get_scary()), _Result.second};
}
template <class... _Mappedty>
iterator try_emplace(const const_iterator _Hint, const key_type& _Keyval, _Mappedty&&... _Mapval) {
return iterator(
_Try_emplace_hint(_Hint._Ptr, _Keyval, _STD forward<_Mappedty>(_Mapval)...), _Mybase::_Get_scary());
}
template <class... _Mappedty>
pair<iterator, bool> try_emplace(key_type&& _Keyval, _Mappedty&&... _Mapval) {
const auto _Result = _Try_emplace(_STD move(_Keyval), _STD forward<_Mappedty>(_Mapval)...);
return {iterator(_Result.first, _Mybase::_Get_scary()), _Result.second};
}
template <class... _Mappedty>
iterator try_emplace(const const_iterator _Hint, key_type&& _Keyval, _Mappedty&&... _Mapval) {
return iterator(_Try_emplace_hint(_Hint._Ptr, _STD move(_Keyval), _STD forward<_Mappedty>(_Mapval)...),
_Mybase::_Get_scary());
}
private:
template <class _Keyty, class _Mappedty>
pair<_Nodeptr, bool> _Insert_or_assign(_Keyty&& _Keyval, _Mappedty&& _Mapval) {
const auto _Loc = _Mybase::_Find_lower_bound(_Keyval);
if (_Mybase::_Lower_bound_duplicate(_Loc._Bound, _Keyval)) {
_Loc._Bound->_Myval.second = _STD forward<_Mappedty>(_Mapval);
return {_Loc._Bound, false};
}
_Mybase::_Check_grow_by_1();
const auto _Scary = _Mybase::_Get_scary();
const auto _Inserted = _Tree_temp_node<_Alnode>(
_Mybase::_Getal(), _Scary->_Myhead, _STD forward<_Keyty>(_Keyval), _STD forward<_Mappedty>(_Mapval))
._Release();
// nothrow hereafter
return {_Scary->_Insert_node(_Loc._Location, _Inserted), true};
}
template <class _Keyty, class _Mappedty>
_Nodeptr _Insert_or_assign_hint(const _Nodeptr _Hint, _Keyty&& _Keyval, _Mappedty&& _Mapval) {
const auto _Loc = _Mybase::_Find_hint(_Hint, _Keyval);
if (_Loc._Duplicate) {
_Loc._Location._Parent->_Myval.second = _STD forward<_Mappedty>(_Mapval);
return _Loc._Location._Parent;
}
_Mybase::_Check_grow_by_1();
const auto _Scary = _Mybase::_Get_scary();
const auto _Inserted = _Tree_temp_node<_Alnode>(
_Mybase::_Getal(), _Scary->_Myhead, _STD forward<_Keyty>(_Keyval), _STD forward<_Mappedty>(_Mapval))
._Release();
// nothrow hereafter
return _Scary->_Insert_node(_Loc._Location, _Inserted);
}
public:
template <class _Mappedty>
pair<iterator, bool> insert_or_assign(const key_type& _Keyval, _Mappedty&& _Mapval) {
const auto _Result = _Insert_or_assign(_Keyval, _STD forward<_Mappedty>(_Mapval));
return {iterator(_Result.first, _Mybase::_Get_scary()), _Result.second};
}
template <class _Mappedty>
iterator insert_or_assign(const const_iterator _Hint, const key_type& _Keyval, _Mappedty&& _Mapval) {
return iterator(
_Insert_or_assign_hint(_Hint._Ptr, _Keyval, _STD forward<_Mappedty>(_Mapval)), _Mybase::_Get_scary());
}
template <class _Mappedty>
pair<iterator, bool> insert_or_assign(key_type&& _Keyval, _Mappedty&& _Mapval) {
const auto _Result = _Insert_or_assign(_STD move(_Keyval), _STD forward<_Mappedty>(_Mapval));
return {iterator(_Result.first, _Mybase::_Get_scary()), _Result.second};
}
template <class _Mappedty>
iterator insert_or_assign(const const_iterator _Hint, key_type&& _Keyval, _Mappedty&& _Mapval) {
return iterator(_Insert_or_assign_hint(_Hint._Ptr, _STD move(_Keyval), _STD forward<_Mappedty>(_Mapval)),
_Mybase::_Get_scary());
}
map(initializer_list<value_type> _Ilist) : _Mybase(key_compare()) {
insert(_Ilist);
}
map(initializer_list<value_type> _Ilist, const key_compare& _Pred) : _Mybase(_Pred) {
insert(_Ilist);
}
map(initializer_list<value_type> _Ilist, const allocator_type& _Al) : _Mybase(key_compare(), _Al) {
insert(_Ilist);
}
map(initializer_list<value_type> _Ilist, const key_compare& _Pred, const allocator_type& _Al)
: _Mybase(_Pred, _Al) {
insert(_Ilist);
}
map& operator=(initializer_list<value_type> _Ilist) {
_Mybase::clear();
insert(_Ilist);
return *this;
}
mapped_type& operator[](const key_type& _Keyval) {
return _Try_emplace(_Keyval).first->_Myval.second;
}
_NODISCARD mapped_type& at(const key_type& _Keyval) {
const auto _Loc = _Mybase::_Find_lower_bound(_Keyval);
if (!_Mybase::_Lower_bound_duplicate(_Loc._Bound, _Keyval)) {
_Xout_of_range("invalid map<K, T> key");
}
return _Loc._Bound->_Myval.second;
}
_NODISCARD const mapped_type& at(const key_type& _Keyval) const {
const auto _Loc = _Mybase::_Find_lower_bound(_Keyval);
if (!_Mybase::_Lower_bound_duplicate(_Loc._Bound, _Keyval)) {
_Xout_of_range("invalid map<K, T> key");
}
return _Loc._Bound->_Myval.second;
}
using _Mybase::_Unchecked_begin;
using _Mybase::_Unchecked_end;
};
#if _HAS_CXX17
template <class _Iter, class _Pr = less<_Guide_key_t<_Iter>>, class _Alloc = allocator<_Guide_pair_t<_Iter>>,
enable_if_t<conjunction_v<_Is_iterator<_Iter>, negation<_Is_allocator<_Pr>>, _Is_allocator<_Alloc>>, int> = 0>
map(_Iter, _Iter, _Pr = _Pr(), _Alloc = _Alloc()) -> map<_Guide_key_t<_Iter>, _Guide_val_t<_Iter>, _Pr, _Alloc>;
template <class _Kty, class _Ty, class _Pr = less<_Kty>, class _Alloc = allocator<pair<const _Kty, _Ty>>,
enable_if_t<conjunction_v<negation<_Is_allocator<_Pr>>, _Is_allocator<_Alloc>>, int> = 0>
map(initializer_list<pair<_Kty, _Ty>>, _Pr = _Pr(), _Alloc = _Alloc()) -> map<_Kty, _Ty, _Pr, _Alloc>;
template <class _Iter, class _Alloc, enable_if_t<conjunction_v<_Is_iterator<_Iter>, _Is_allocator<_Alloc>>, int> = 0>
map(_Iter, _Iter, _Alloc) -> map<_Guide_key_t<_Iter>, _Guide_val_t<_Iter>, less<_Guide_key_t<_Iter>>, _Alloc>;
template <class _Kty, class _Ty, class _Alloc, enable_if_t<_Is_allocator<_Alloc>::value, int> = 0>
map(initializer_list<pair<_Kty, _Ty>>, _Alloc) -> map<_Kty, _Ty, less<_Kty>, _Alloc>;
#endif // _HAS_CXX17
template <class _Kty, class _Ty, class _Pr, class _Alloc>
void swap(map<_Kty, _Ty, _Pr, _Alloc>& _Left, map<_Kty, _Ty, _Pr, _Alloc>& _Right) noexcept(
noexcept(_Left.swap(_Right))) {
_Left.swap(_Right);
}
#if _HAS_CXX20
template <class _Kty, class _Ty, class _Keylt, class _Alloc, class _Pr>
typename map<_Kty, _Ty, _Keylt, _Alloc>::size_type erase_if(map<_Kty, _Ty, _Keylt, _Alloc>& _Cont, _Pr _Pred) {
return _Erase_nodes_if(_Cont, _Pass_fn(_Pred));
}
#endif // _HAS_CXX20
// CLASS TEMPLATE multimap
template <class _Kty, class _Ty, class _Pr = less<_Kty>, class _Alloc = allocator<pair<const _Kty, _Ty>>>
class multimap : public _Tree<_Tmap_traits<_Kty, _Ty, _Pr, _Alloc, true>> {
// ordered red-black tree of {key, mapped} values, non-unique keys
public:
static_assert(!_ENFORCE_MATCHING_ALLOCATORS || is_same_v<pair<const _Kty, _Ty>, typename _Alloc::value_type>,
_MISMATCHED_ALLOCATOR_MESSAGE("multimap<Key, Value, Compare, Allocator>", "pair<const Key, Value>"));
using _Mybase = _Tree<_Tmap_traits<_Kty, _Ty, _Pr, _Alloc, true>>;
using key_type = _Kty;
using mapped_type = _Ty;
using key_compare = _Pr;
using value_compare = typename _Mybase::value_compare;
using value_type = pair<const _Kty, _Ty>;
using allocator_type = typename _Mybase::allocator_type;
using size_type = typename _Mybase::size_type;
using difference_type = typename _Mybase::difference_type;
using pointer = typename _Mybase::pointer;
using const_pointer = typename _Mybase::const_pointer;
using reference = value_type&;
using const_reference = const value_type&;
using iterator = typename _Mybase::iterator;
using const_iterator = typename _Mybase::const_iterator;
using reverse_iterator = typename _Mybase::reverse_iterator;
using const_reverse_iterator = typename _Mybase::const_reverse_iterator;
using _Alnode = typename _Mybase::_Alnode;
using _Alnode_traits = typename _Mybase::_Alnode_traits;
multimap() : _Mybase(key_compare()) {}
explicit multimap(const allocator_type& _Al) : _Mybase(key_compare(), _Al) {}
multimap(const multimap& _Right)
: _Mybase(_Right, _Alnode_traits::select_on_container_copy_construction(_Right._Getal())) {}
multimap(const multimap& _Right, const allocator_type& _Al) : _Mybase(_Right, _Al) {}
explicit multimap(const key_compare& _Pred) : _Mybase(_Pred) {}
multimap(const key_compare& _Pred, const allocator_type& _Al) : _Mybase(_Pred, _Al) {}
template <class _Iter>
multimap(_Iter _First, _Iter _Last) : _Mybase(key_compare()) {
insert(_First, _Last);
}
template <class _Iter>
multimap(_Iter _First, _Iter _Last, const key_compare& _Pred) : _Mybase(_Pred) {
insert(_First, _Last);
}
template <class _Iter>
multimap(_Iter _First, _Iter _Last, const allocator_type& _Al) : _Mybase(key_compare(), _Al) {
insert(_First, _Last);
}
template <class _Iter>
multimap(_Iter _First, _Iter _Last, const key_compare& _Pred, const allocator_type& _Al) : _Mybase(_Pred, _Al) {
insert(_First, _Last);
}
multimap& operator=(const multimap& _Right) {
_Mybase::operator=(_Right);
return *this;
}
multimap(multimap&& _Right) : _Mybase(_STD move(_Right)) {}
multimap(multimap&& _Right, const allocator_type& _Al) : _Mybase(_STD move(_Right), _Al) {}
multimap& operator=(multimap&& _Right) noexcept(
_Alnode_traits::is_always_equal::value&& is_nothrow_move_assignable_v<_Pr>) {
_Mybase::operator=(_STD move(_Right));
return *this;
}
template <class... _Valty>
iterator emplace(_Valty&&... _Val) {
return _Mybase::emplace(_STD forward<_Valty>(_Val)...).first;
}
void swap(multimap& _Right) noexcept(noexcept(_Mybase::swap(_Right))) {
_Mybase::swap(_Right);
}
using _Mybase::insert;
template <class _Valty, enable_if_t<is_constructible_v<value_type, _Valty>, int> = 0>
iterator insert(_Valty&& _Val) {
return this->emplace(_STD forward<_Valty>(_Val));
}
template <class _Valty, enable_if_t<is_constructible_v<value_type, _Valty>, int> = 0>
iterator insert(const_iterator _Where, _Valty&& _Val) {
return this->emplace_hint(_Where, _STD forward<_Valty>(_Val));
}
multimap(initializer_list<value_type> _Ilist) : _Mybase(key_compare()) {
insert(_Ilist);
}
multimap(initializer_list<value_type> _Ilist, const key_compare& _Pred) : _Mybase(_Pred) {
insert(_Ilist);
}
multimap(initializer_list<value_type> _Ilist, const allocator_type& _Al) : _Mybase(key_compare(), _Al) {
insert(_Ilist);
}
multimap(initializer_list<value_type> _Ilist, const key_compare& _Pred, const allocator_type& _Al)
: _Mybase(_Pred, _Al) {
insert(_Ilist);
}
multimap& operator=(initializer_list<value_type> _Ilist) {
_Mybase::clear();
insert(_Ilist);
return *this;
}
using _Mybase::_Unchecked_begin;
using _Mybase::_Unchecked_end;
};
#if _HAS_CXX17
template <class _Iter, class _Pr = less<_Guide_key_t<_Iter>>, class _Alloc = allocator<_Guide_pair_t<_Iter>>,
enable_if_t<conjunction_v<_Is_iterator<_Iter>, negation<_Is_allocator<_Pr>>, _Is_allocator<_Alloc>>, int> = 0>
multimap(_Iter, _Iter, _Pr = _Pr(), _Alloc = _Alloc())
-> multimap<_Guide_key_t<_Iter>, _Guide_val_t<_Iter>, _Pr, _Alloc>;
template <class _Kty, class _Ty, class _Pr = less<_Kty>, class _Alloc = allocator<pair<const _Kty, _Ty>>,
enable_if_t<conjunction_v<negation<_Is_allocator<_Pr>>, _Is_allocator<_Alloc>>, int> = 0>
multimap(initializer_list<pair<_Kty, _Ty>>, _Pr = _Pr(), _Alloc = _Alloc()) -> multimap<_Kty, _Ty, _Pr, _Alloc>;
template <class _Iter, class _Alloc, enable_if_t<conjunction_v<_Is_iterator<_Iter>, _Is_allocator<_Alloc>>, int> = 0>
multimap(_Iter, _Iter, _Alloc) -> multimap<_Guide_key_t<_Iter>, _Guide_val_t<_Iter>, less<_Guide_key_t<_Iter>>, _Alloc>;
template <class _Kty, class _Ty, class _Alloc, enable_if_t<_Is_allocator<_Alloc>::value, int> = 0>
multimap(initializer_list<pair<_Kty, _Ty>>, _Alloc) -> multimap<_Kty, _Ty, less<_Kty>, _Alloc>;
#endif // _HAS_CXX17
template <class _Kty, class _Ty, class _Pr, class _Alloc>
void swap(multimap<_Kty, _Ty, _Pr, _Alloc>& _Left, multimap<_Kty, _Ty, _Pr, _Alloc>& _Right) noexcept(
noexcept(_Left.swap(_Right))) {
_Left.swap(_Right);
}
#if _HAS_CXX20
template <class _Kty, class _Ty, class _Keylt, class _Alloc, class _Pr>
typename multimap<_Kty, _Ty, _Keylt, _Alloc>::size_type erase_if(
multimap<_Kty, _Ty, _Keylt, _Alloc>& _Cont, _Pr _Pred) {
return _Erase_nodes_if(_Cont, _Pass_fn(_Pred));
}
#endif // _HAS_CXX20
#if _HAS_CXX17
namespace pmr {
template <class _Kty, class _Ty, class _Pr = less<_Kty>>
using map = _STD map<_Kty, _Ty, _Pr, polymorphic_allocator<pair<const _Kty, _Ty>>>;
template <class _Kty, class _Ty, class _Pr = less<_Kty>>
using multimap = _STD multimap<_Kty, _Ty, _Pr, polymorphic_allocator<pair<const _Kty, _Ty>>>;
} // namespace pmr
#endif // _HAS_CXX17
_STD_END
#pragma pop_macro("new")
_STL_RESTORE_CLANG_WARNINGS
#pragma warning(pop)
#pragma pack(pop)
#endif // _STL_COMPILER_PREPROCESSOR
#endif // _MAP_