// map standard header #ifndef _MAP_ #define _MAP_ #include #include #ifdef _MSC_VER #pragma pack(push,8) #endif /* _MSC_VER */ _STD_BEGIN // TEMPLATE CLASS map template, class _A = allocator<_Ty> > class map { public: typedef map<_K, _Ty, _Pr, _A> _Myt; typedef pair value_type; struct _Kfn : public unary_function { const _K& operator()(const value_type& _X) const {return (_X.first); } }; class value_compare : public binary_function { friend class map<_K, _Ty, _Pr, _A>; public: bool operator()(const value_type& _X, const value_type& _Y) const {return (comp(_X.first, _Y.first)); } _PROTECTED: value_compare(_Pr _Pred) : comp(_Pred) {} _Pr comp; }; typedef _K key_type; typedef _Ty referent_type; typedef _Pr key_compare; typedef _A allocator_type; typedef typename _A::reference _Tref; typedef _Tree<_K, value_type, _Kfn, _Pr, _A> _Imp; typedef typename _Imp::size_type size_type; typedef typename _Imp::difference_type difference_type; typedef typename _Imp::reference reference; typedef typename _Imp::const_reference const_reference; typedef typename _Imp::iterator iterator; typedef typename _Imp::const_iterator const_iterator; typedef typename _Imp::reverse_iterator reverse_iterator; typedef typename _Imp::const_reverse_iterator const_reverse_iterator; typedef pair _Pairib; typedef pair _Pairii; typedef pair _Paircc; explicit map(const _Pr& _Pred = _Pr(), const _A& _Al = _A()) : _Tr(_Pred, false, _Al) {} typedef const value_type *_It; map(_It _F, _It _L, const _Pr& _Pred = _Pr(), const _A& _Al = _A()) : _Tr(_Pred, false, _Al) {for (; _F != _L; ++_F) _Tr.insert(*_F); } _Myt& operator=(const _Myt& _X) {_Tr = _X._Tr; return (*this); } iterator begin() {return (_Tr.begin()); } const_iterator begin() const {return (_Tr.begin()); } iterator end() {return (_Tr.end()); } const_iterator end() const {return (_Tr.end()); } reverse_iterator rbegin() {return (_Tr.rbegin()); } const_reverse_iterator rbegin() const {return (_Tr.rbegin()); } reverse_iterator rend() {return (_Tr.rend()); } const_reverse_iterator rend() const {return (_Tr.rend()); } size_type size() const {return (_Tr.size()); } size_type max_size() const {return (_Tr.max_size()); } bool empty() const {return (_Tr.empty()); } _A get_allocator() const {return (_Tr.get_allocator()); } _Tref operator[](const key_type& _Kv) {iterator _P = insert(value_type(_Kv, _Ty())).first; return ((*_P).second); } _Pairib insert(const value_type& _X) {_Imp::_Pairib _Ans = _Tr.insert(_X); return (_Pairib(_Ans.first, _Ans.second)); } iterator insert(iterator _P, const value_type& _X) {return (_Tr.insert((_Imp::iterator&)_P, _X)); } void insert(_It _F, _It _L) {for (; _F != _L; ++_F) _Tr.insert(*_F); } iterator erase(iterator _P) {return (_Tr.erase((_Imp::iterator&)_P)); } iterator erase(iterator _F, iterator _L) {return (_Tr.erase((_Imp::iterator&)_F, (_Imp::iterator&)_L)); } size_type erase(const _K& _Kv) {return (_Tr.erase(_Kv)); } void clear() {_Tr.clear(); } void swap(_Myt& _X) {std::swap(_Tr, _X._Tr); } friend void swap(_Myt& _X, _Myt& _Y) {_X.swap(_Y); } key_compare key_comp() const {return (_Tr.key_comp()); } value_compare value_comp() const {return (value_compare(_Tr.key_comp())); } iterator find(const _K& _Kv) {return (_Tr.find(_Kv)); } const_iterator find(const _K& _Kv) const {return (_Tr.find(_Kv)); } size_type count(const _K& _Kv) const {return (_Tr.count(_Kv)); } iterator lower_bound(const _K& _Kv) {return (_Tr.lower_bound(_Kv)); } const_iterator lower_bound(const _K& _Kv) const {return (_Tr.lower_bound(_Kv)); } iterator upper_bound(const _K& _Kv) {return (_Tr.upper_bound(_Kv)); } const_iterator upper_bound(const _K& _Kv) const {return (_Tr.upper_bound(_Kv)); } _Pairii equal_range(const _K& _Kv) {return (_Tr.equal_range(_Kv)); } _Paircc equal_range(const _K& _Kv) const {return (_Tr.equal_range(_Kv)); } protected: _Imp _Tr; }; // map TEMPLATE OPERATORS template inline bool operator==(const map<_K, _Ty, _Pr, _A>& _X, const map<_K, _Ty, _Pr, _A>& _Y) {return (_X.size() == _Y.size() && equal(_X.begin(), _X.end(), _Y.begin())); } template inline bool operator!=(const map<_K, _Ty, _Pr, _A>& _X, const map<_K, _Ty, _Pr, _A>& _Y) {return (!(_X == _Y)); } template inline bool operator<(const map<_K, _Ty, _Pr, _A>& _X, const map<_K, _Ty, _Pr, _A>& _Y) {return (lexicographical_compare(_X.begin(), _X.end(), _Y.begin(), _Y.end())); } template inline bool operator>(const map<_K, _Ty, _Pr, _A>& _X, const map<_K, _Ty, _Pr, _A>& _Y) {return (_Y < _X); } template inline bool operator<=(const map<_K, _Ty, _Pr, _A>& _X, const map<_K, _Ty, _Pr, _A>& _Y) {return (!(_Y < _X)); } template inline bool operator>=(const map<_K, _Ty, _Pr, _A>& _X, const map<_K, _Ty, _Pr, _A>& _Y) {return (!(_X < _Y)); } // TEMPLATE CLASS multimap template, class _A = allocator<_Ty> > class multimap { public: typedef multimap<_K, _Ty, _Pr, _A> _Myt; typedef pair value_type; struct _Kfn : public unary_function { const _K& operator()(const value_type& _X) const {return (_X.first); } }; class value_compare : public binary_function { friend class map<_K, _Ty, _Pr, _A>; public: bool operator()(const value_type& _X, const value_type& _Y) const {return (comp(_X.first, _Y.first)); } _PROTECTED: value_compare(_Pr _Pred) : comp(_Pred) {} _Pr comp; }; typedef _K key_type; typedef _Ty referent_type; typedef _Pr key_compare; typedef _A allocator_type; typedef _Tree<_K, value_type, _Kfn, _Pr, _A> _Imp; typedef typename _Imp::size_type size_type; typedef typename _Imp::difference_type difference_type; typedef typename _Imp::reference reference; typedef typename _Imp::const_reference const_reference; typedef typename _Imp::iterator iterator; typedef typename _Imp::const_iterator const_iterator; typedef typename _Imp::reverse_iterator reverse_iterator; typedef typename _Imp::const_reverse_iterator const_reverse_iterator; typedef pair _Pairii; typedef pair _Paircc; explicit multimap(const _Pr& _Pred = _Pr(), const _A& _Al = _A()) : _Tr(_Pred, true, _Al) {} typedef const value_type *_It; multimap(_It _F, _It _L, const _Pr& _Pred = _Pr(), const _A& _Al = _A()) : _Tr(_Pred, true, _Al) {for (; _F != _L; ++_F) _Tr.insert(*_F); } _Myt& operator=(const _Myt& _X) {_Tr = _X._Tr; return (*this); } iterator begin() {return (_Tr.begin()); } const_iterator begin() const {return (_Tr.begin()); } iterator end() {return (_Tr.end()); } const_iterator end() const {return (_Tr.end()); } reverse_iterator rbegin() {return (_Tr.rbegin()); } const_reverse_iterator rbegin() const {return (_Tr.rbegin()); } reverse_iterator rend() {return (_Tr.rend()); } const_reverse_iterator rend() const {return (_Tr.rend()); } size_type size() const {return (_Tr.size()); } size_type max_size() const {return (_Tr.max_size()); } bool empty() const {return (_Tr.empty()); } _A get_allocator() const {return (_Tr.get_allocator()); } iterator insert(const value_type& _X) {return (_Tr.insert(_X).first); } iterator insert(iterator _P, const value_type& _X) {return (_Tr.insert((_Imp::iterator&)_P, _X)); } void insert(_It _F, _It _L) {for (; _F != _L; ++_F) _Tr.insert(*_F); } iterator erase(iterator _P) {return (_Tr.erase((_Imp::iterator&)_P)); } iterator erase(iterator _F, iterator _L) {return (_Tr.erase((_Imp::iterator&)_F, (_Imp::iterator&)_L)); } size_type erase(const _K& _Kv = _K()) {return (_Tr.erase(_Kv)); } void clear() {_Tr.clear(); } void swap(_Myt& _X) {std::swap(_Tr, _X._Tr); } friend void swap(_Myt& _X, _Myt& _Y) {_X.swap(_Y); } key_compare key_comp() const {return (_Tr.key_comp()); } value_compare value_comp() const {return (value_compare(_Tr.key_comp())); } iterator find(const _K& _Kv) {return (_Tr.find(_Kv)); } const_iterator find(const _K& _Kv) const {return (_Tr.find(_Kv)); } size_type count(const _K& _Kv) const {return (_Tr.count(_Kv)); } iterator lower_bound(const _K& _Kv) {return (_Tr.lower_bound(_Kv)); } const_iterator lower_bound(const _K& _Kv) const {return (_Tr.lower_bound(_Kv)); } iterator upper_bound(const _K& _Kv) {return (_Tr.upper_bound(_Kv)); } const_iterator upper_bound(const _K& _Kv) const {return (_Tr.upper_bound(_Kv)); } _Pairii equal_range(const _K& _Kv) {return (_Tr.equal_range(_Kv)); } _Paircc equal_range(const _K& _Kv) const {return (_Tr.equal_range(_Kv)); } protected: _Imp _Tr; }; // multimap TEMPLATE OPERATORS template inline bool operator==(const multimap<_K, _Ty, _Pr, _A>& _X, const multimap<_K, _Ty, _Pr, _A>& _Y) {return (_X.size() == _Y.size() && equal(_X.begin(), _X.end(), _Y.begin())); } template inline bool operator!=(const multimap<_K, _Ty, _Pr, _A>& _X, const multimap<_K, _Ty, _Pr, _A>& _Y) {return (!(_X == _Y)); } template inline bool operator<(const multimap<_K, _Ty, _Pr, _A>& _X, const multimap<_K, _Ty, _Pr, _A>& _Y) {return (lexicographical_compare(_X.begin(), _X.end(), _Y.begin(), _Y.end())); } template inline bool operator>(const multimap<_K, _Ty, _Pr, _A>& _X, const multimap<_K, _Ty, _Pr, _A>& _Y) {return (_Y < _X); } template inline bool operator<=(const multimap<_K, _Ty, _Pr, _A>& _X, const multimap<_K, _Ty, _Pr, _A>& _Y) {return (!(_Y < _X)); } template inline bool operator>=(const multimap<_K, _Ty, _Pr, _A>& _X, const multimap<_K, _Ty, _Pr, _A>& _Y) {return (!(_X < _Y)); } _STD_END #ifdef _MSC_VER #pragma pack(pop) #endif /* _MSC_VER */ #endif /* _MAP_ */ /* * Copyright (c) 1995 by P.J. Plauger. ALL RIGHTS RESERVED. * Consult your license regarding permissions and restrictions. */ /* * This file is derived from software bearing the following * restrictions: * * Copyright (c) 1994 * Hewlett-Packard Company * * Permission to use, copy, modify, distribute and sell this * software and its documentation for any purpose is hereby * granted without fee, provided that the above copyright notice * appear in all copies and that both that copyright notice and * this permission notice appear in supporting documentation. * Hewlett-Packard Company makes no representations about the * suitability of this software for any purpose. It is provided * "as is" without express or implied warranty. */