// Components for manipulating sequences of characters -*- C++ -*- // Copyright (C) 1997-1999 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library is free // software; you can redistribute it and/or modify it under the // terms of the GNU General Public License as published by the // Free Software Foundation; either version 2, or (at your option) // any later version. // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // You should have received a copy of the GNU General Public License along // with this library; see the file COPYING. If not, write to the Free // Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, // USA. // As a special exception, you may use this file as part of a free software // library without restriction. Specifically, if other files instantiate // templates or use macros or inline functions from this file, or you compile // this file and link it with other files to produce an executable, this // file does not by itself cause the resulting executable to be covered by // the GNU General Public License. This exception does not however // invalidate any other reasons why the executable file might be covered by // the GNU General Public License. // // ISO C++ 14882: 21 Strings library // #ifndef _CPP_BITS_STRING_H #define _CPP_BITS_STRING_H 1 #include #include namespace std { // Documentation? What's that? // Nathan Myers . // // A string looks like this: // // [_Rep] // _M_length // [basic_string] _M_capacity // _M_dataplus _M_state // _M_p ----------------> unnamed array of char_type // Where the _M_p points to the first character in the string, and // you cast it to a pointer-to-_Rep and subtract 1 to get a // pointer to the header. // This approach has the enormous advantage that a string object // requires only one allocation. All the ugliness is confined // within a single pair of inline functions, which each compile to // a single "add" instruction: _Rep::_M_data(), and // string::_M_rep(); and the allocation function which gets a // block of raw bytes and with room enough and constructs a _Rep // object at the front. // The reason you want _M_data pointing to the character array and // not the _Rep is so that the debugger can see the string // contents. (Probably we should add a non-inline member to get // the _Rep for the debugger to use, so users can check the actual // string length.) // Note that the _Rep object is a POD so that you can have a // static "empty string" _Rep object already "constructed" before // static constructors have run. The reference-count encoding is // chosen so that a 0 indicates one reference, so you never try to // destroy the empty-string _Rep object. // All but the last paragraph is considered pretty conventional // for a C++ string implementation. // 21.3 Template class basic_string template class basic_string { // Types: public: typedef _Traits traits_type; typedef typename _Traits::char_type value_type; typedef _Alloc allocator_type; typedef typename _Alloc::size_type size_type; typedef typename _Alloc::difference_type difference_type; typedef typename _Alloc::reference reference; typedef typename _Alloc::const_reference const_reference; typedef typename _Alloc::pointer pointer; typedef typename _Alloc::const_pointer const_pointer; typedef __normal_iterator iterator; typedef __normal_iterator const_iterator; typedef reverse_iterator const_reverse_iterator; typedef reverse_iterator reverse_iterator; // Data Members: // NB: This is an unsigned type, and thus represents the maximum // size that the allocator can hold. static const size_type npos = static_cast(-1); private: // _Rep: string representation // Invariants: // 1. String really contains _M_length + 1 characters; last is set // to 0 only on call to c_str(). We avoid instantiating // _CharT() where the interface does not require it. // 2. _M_capacity >= _M_length // Allocated memory is always _M_capacity + (1 * sizeof(_CharT)). // 3. _M_state has three states: // -1: leaked, one reference, no ref-copies allowed, non-const. // 0: one reference, non-const. // n>0: n + 1 references, operations require a lock, const. // 4. All fields==0 is an empty string, given the extra storage // beyond-the-end for a null terminator; thus, the shared // empty string representation needs no constructor. struct _Rep { // Types: typedef typename _Alloc::rebind::other _Raw_bytes_alloc; // (Public) Data members: // The maximum number of individual char_type elements of an // individual string is determined by _S_max_size. This is the // value that will be returned by max_size(). (Whereas npos // is the maximum number of bytes the allocator can allocate.) // If one was to divvy up the theoretical largest size string, // with a terminating character and m _CharT elements, it'd // look like this: // npos = sizeof(_Rep) + (m * sizeof(_CharT)) + sizeof(_CharT) // Solving for m: // m = ((npos - sizeof(_Rep))/sizeof(CharT)) - 1 // In addition, this implementation quarters this ammount. static size_type _S_max_size; static _CharT _S_terminal; size_type _M_length; size_type _M_capacity; _Atomic_word _M_state; bool _M_is_leaked() const { return _M_state < 0; } bool _M_is_shared() const { return _M_state > 0; } void _M_set_leaked() { _M_state = -1; } void _M_set_sharable() { _M_state = 0; } _CharT* _M_refdata() throw() { return reinterpret_cast<_CharT*> (this + 1); } _CharT& operator[](size_t __s) throw() { return _M_refdata() [__s]; } _CharT* _M_grab(const _Alloc& __alloc1, const _Alloc& __alloc2) { return (!_M_is_leaked() && __alloc1 == __alloc2) ? _M_refcopy() : _M_clone(__alloc1); } // Create & Destroy static _Rep* _S_create(size_t, const _Alloc&); void _M_dispose(const _Alloc& __a) { if (__exchange_and_add(&_M_state, -1) <= 0) _M_destroy(__a); } // XXX MT void _M_destroy(const _Alloc&) throw(); _CharT* _M_refcopy() throw() { __atomic_add(&_M_state, 1); return _M_refdata(); } // XXX MT _CharT* _M_clone(const _Alloc&, size_type __res = 0); #if _GLIBCPP_ALLOC_CONTROL // These function pointers allow you to modify the allocation // policy used by the string classes. By default they expand by // powers of two, but this may be excessive for space-critical // applications. // Returns true if ALLOCATED is too much larger than LENGTH static bool (*_S_excess_slop) (size_t __length, size_t __allocated); inline static bool __default_excess(size_t, size_t); #else inline static bool _S_excess_slop(size_t, size_t); #endif }; // Use empty-base optimization: http://www.cantrip.org/emptyopt.html struct _Alloc_hider : _Alloc { _Alloc_hider(_CharT* __dat, const _Alloc& __a) : _Alloc(__a), _M_p(__dat) { } _CharT* _M_p; // The actual data. }; mutable _Alloc_hider _M_dataplus; _CharT* _M_data() const { return _M_dataplus._M_p; } _CharT* _M_data(_CharT* __p) { return (_M_dataplus._M_p = __p); } _Rep* _M_rep() const { return &((reinterpret_cast<_Rep*> (_M_data()))[-1]); } // For the internal use we have functions similar to `begin'/`end' // but they do not call _M_leak. iterator _M_ibegin() const { return iterator(_M_data()); } iterator _M_iend() const { return iterator(_M_data() + this->size()); } void _M_leak() // for use in begin() & non-const op[] { if (!_M_rep()->_M_is_leaked()) _M_leak_hard(); } iterator _M_check(size_type __pos) const { __OUTOFRANGE(__pos > this->size()); return _M_ibegin() + __pos; } // NB: _M_fold doesn't check for a bad __pos1 value. iterator _M_fold(size_type __pos, size_type __off) const { bool __testoff = __off < this->size() - __pos; size_type __newoff = __testoff ? __off : this->size() - __pos; return (_M_ibegin() + __pos + __newoff); } // _S_copy_chars is a separate template to permit specialization // to optimize for the common case of pointers as iterators. template static void _S_copy_chars(_CharT* __p, _Iterator __j1, _Iterator __j2) { for (; __j1 != __j2; ++__j1, ++__p) traits_type::assign(*__p, *__j1); //these types are off } static void _S_copy_chars(_CharT* __p, iterator __j1, iterator __j2) { _S_copy_chars(__p, __j1.base(), __j2.base()); } static void _S_copy_chars(_CharT* __p, const_iterator __j1, const_iterator __j2) { _S_copy_chars(__p, __j1.base(), __j2.base()); } static void _S_copy_chars(_CharT* __p, _CharT* __j1, _CharT* __j2) { traits_type::copy(__p, __j1, __j2 - __j1); } static void _S_copy_chars(_CharT* __p, const _CharT* __j1, const _CharT* __j2) { traits_type::copy(__p, __j1, __j2 - __j1); } void _M_mutate(size_type __pos, size_type __len1, size_type __len2); void _M_leak_hard(); // The following storage is init'd to 0 by the linker, resulting // (carefully) in an empty string with one reference. static size_type _S_empty_rep_storage[ (sizeof(_Rep) + sizeof(_CharT) + sizeof(size_type)-1)/sizeof(size_type)]; static _Rep& _S_empty_rep() { return *reinterpret_cast<_Rep*> (&_S_empty_rep_storage); } public: // Construct/copy/destroy: // NB: We overload ctors in some cases instead of using default // arguments, per 17.4.4.4 para. 2 item 2. inline basic_string(); explicit basic_string(const _Alloc& __a); // NB: per LWG issue 42, semantics different from IS: basic_string(const basic_string& __str); basic_string(const basic_string& __str, size_type __pos, size_type __n = npos); basic_string(const basic_string& __str, size_type __pos, size_type __n, const _Alloc& __a); basic_string(const _CharT* __s, size_type __n, const _Alloc& __a = _Alloc()); basic_string(const _CharT* __s, const _Alloc& __a = _Alloc()); basic_string(size_type __n, _CharT __c, const _Alloc& __a = _Alloc()); template basic_string(_InputIterator __begin, _InputIterator __end, const _Alloc& __a = _Alloc()); ~basic_string() { _M_rep()->_M_dispose(this->get_allocator()); } basic_string& operator=(const basic_string& __str) { return this->assign(__str); } basic_string& operator=(const _CharT* __s) { return this->assign(__s); } basic_string& operator=(_CharT __c) { return this->assign(1, __c); } // Iterators: iterator begin() { _M_leak(); return iterator(_M_data()); } const_iterator begin() const { return const_iterator(_M_data()); } iterator end() { _M_leak(); return iterator(_M_data() + this->size()); } const_iterator end() const { return const_iterator(_M_data() + this->size()); } reverse_iterator rbegin() { return reverse_iterator(this->end()); } const_reverse_iterator rbegin() const { return const_reverse_iterator(this->end()); } reverse_iterator rend() { return reverse_iterator(this->begin()); } const_reverse_iterator rend() const { return const_reverse_iterator(this->begin()); } public: // Capacity: size_type size() const { return _M_rep()->_M_length; } size_type length() const { return _M_rep()->_M_length; } size_type max_size() const { return _Rep::_S_max_size; } void resize(size_type __n, _CharT __c); void resize(size_type __n) { this->resize(__n, _CharT()); } size_type capacity() const { return _M_rep()->_M_capacity; } void reserve(size_type __res_arg = 0); void clear() { _M_mutate(0, this->size(), 0); } bool empty() const { return this->size() == 0; } // Element access: const_reference operator[] (size_type __pos) const { return _M_data()[__pos]; } reference operator[](size_type __pos) { _M_leak(); return _M_data()[__pos]; } const_reference at(size_type __n) const { __OUTOFRANGE(__n >= this->size()); return _M_data()[__n]; } reference at(size_type __n) { __OUTOFRANGE(__n >= size()); _M_leak(); return _M_data()[__n]; } // Modifiers: basic_string& operator+=(const basic_string& __str) { return this->append(__str); } basic_string& operator+=(const _CharT* __s) { return this->append(__s); } basic_string& operator+=(_CharT __c) { return this->append(size_type(1), __c); } basic_string& append(const basic_string& __str); basic_string& append(const basic_string& __str, size_type __pos, size_type __n); basic_string& append(const _CharT* __s, size_type __n); basic_string& append(const _CharT* __s) { return this->append(__s, traits_type::length(__s)); } basic_string& append(size_type __n, _CharT __c); template basic_string& append(_InputIterator __first, _InputIterator __last) { return this->replace(_M_iend(), _M_iend(), __first, __last); } void push_back(_CharT __c) { this->replace(_M_iend(), _M_iend(), 1, __c); } basic_string& assign(const basic_string& __str); basic_string& assign(const basic_string& __str, size_type __pos, size_type __n) { return this->assign(__str._M_check(__pos), __str._M_fold(__pos, __n)); } basic_string& assign(const _CharT* __s, size_type __n) { return this->assign(__s, __s + __n); } basic_string& assign(const _CharT* __s) { return this->assign(__s, __s + traits_type::length(__s)); } basic_string& assign(size_type __n, _CharT __c) { return this->replace(_M_ibegin(), _M_iend(), __n, __c); } template basic_string& assign(_InputIterator __first, _InputIterator __last) { return this->replace(_M_ibegin(), _M_iend(), __first, __last); } void insert(iterator __p, size_type __n, _CharT __c) { this->replace(__p, __p, __n, __c); } template void insert(iterator __p, _InputIterator __beg, _InputIterator __end) { this->replace(__p, __p, __beg, __end); } basic_string& insert(size_type __pos1, const basic_string& __str) { iterator __p = _M_check(__pos1); this->replace(__p, __p, __str._M_ibegin(), __str._M_iend()); return *this; } basic_string& insert(size_type __pos1, const basic_string& __str, size_type __pos2, size_type __n) { iterator __p = _M_check(__pos1); this->replace(__p, __p, __str._M_check(__pos2), __str._M_fold(__pos2, __n)); return *this; } basic_string& insert(size_type __pos, const _CharT* __s, size_type __n) { iterator __p = _M_check(__pos); this->replace(__p, __p, __s, __s + __n); return *this; } basic_string& insert(size_type __pos, const _CharT* __s) { return this->insert(__pos, __s, traits_type::length(__s)); } basic_string& insert(size_type __pos, size_type __n, _CharT __c) { this->insert(_M_check(__pos), __n, __c); return *this; } iterator insert(iterator __p, _CharT __c = _CharT()) { size_type __pos = __p - _M_ibegin(); this->insert(_M_check(__pos), size_type(1), __c); _M_rep()->_M_set_leaked(); return this->_M_ibegin() + __pos; } basic_string& erase(size_type __pos = 0, size_type __n = npos) { return this->replace(_M_check(__pos), _M_fold(__pos, __n), _M_data(), _M_data()); } iterator erase(iterator __position) { size_type __i = __position - _M_ibegin(); this->replace(__position, __position + 1, _M_data(), _M_data()); _M_rep()->_M_set_leaked(); return _M_ibegin() + __i; } iterator erase(iterator __first, iterator __last) { size_type __i = __first - _M_ibegin(); this->replace(__first, __last, _M_data(), _M_data()); _M_rep()->_M_set_leaked(); return _M_ibegin() + __i; } basic_string& replace(size_type __pos, size_type __n, const basic_string& __str) { return this->replace(_M_check(__pos), _M_fold(__pos, __n), __str.begin(), __str.end()); } basic_string& replace(size_type __pos1, size_type __n1, const basic_string& __str, size_type __pos2, size_type __n2); basic_string& replace(size_type __pos, size_type __n1, const _CharT* __s, size_type __n2) { return this->replace(_M_check(__pos), _M_fold(__pos, __n1), __s, __s + __n2); } basic_string& replace(size_type __pos, size_type __n1, const _CharT* __s) { return this->replace(_M_check(__pos), _M_fold(__pos, __n1), __s, __s + traits_type::length(__s)); } basic_string& replace(size_type __pos, size_type __n1, size_type __n2, _CharT __c) { return this->replace(_M_check(__pos), _M_fold(__pos, __n1), __n2, __c); } basic_string& replace(iterator __i1, iterator __i2, const basic_string& __str) { return this->replace(__i1, __i2, __str.begin(), __str.end()); } basic_string& replace(iterator __i1, iterator __i2, const _CharT* __s, size_type __n) { return this->replace(__i1, __i2, __s, __s + __n); } basic_string& replace(iterator __i1, iterator __i2, const _CharT* __s) { return this->replace(__i1, __i2, __s, __s + traits_type::length(__s)); } basic_string& replace(iterator __i1, iterator __i2, size_type __n, _CharT __c); template basic_string& replace(iterator __i1, iterator __i2, _InputIterator __j1, _InputIterator __j2) { return _M_replace(__i1, __i2, __j1, __j2, typename iterator_traits<_InputIterator>::iterator_category()); } private: template basic_string& _M_replace(iterator __i1, iterator __i2, _InputIterator __j1, _InputIterator __j2, input_iterator_tag); template basic_string& _M_replace(iterator __i1, iterator __i2, _FwdIterator __j1, _FwdIterator __j2, forward_iterator_tag); // _S_construct_aux is used to implement the 21.3.1 para 15 which // requires special behaviour if _InIter is an integral type template static _CharT* _S_construct_aux(_InIter __beg, _InIter __end, const _Alloc& __a, __false_type) { typedef typename iterator_traits<_InIter>::iterator_category _Tag; return _S_construct(__beg, __end, __a, _Tag()); } template static _CharT* _S_construct_aux(_InIter __beg, _InIter __end, const _Alloc& __a, __true_type) { return _S_construct(static_cast(__beg), static_cast(__end), __a); } template static _CharT* _S_construct(_InIter __beg, _InIter __end, const _Alloc& __a) { typedef typename _Is_integer<_InIter>::_Integral _Integral; return _S_construct_aux(__beg, __end, __a, _Integral()); } // For Input Iterators, used in istreambuf_iterators, etc. template static _CharT* _S_construct(_InIter __beg, _InIter __end, const _Alloc& __a, input_iterator_tag); // For forward_iterators up to random_access_iterators, used for // string::iterator, _CharT*, etc. template static _CharT* _S_construct(_FwdIter __end, _FwdIter __beg, const _Alloc& __a, forward_iterator_tag); static _CharT* _S_construct(size_type __req, _CharT __c, const _Alloc& __a); public: size_type copy(_CharT* __s, size_type __n, size_type __pos = 0) const; void swap(basic_string<_CharT, _Traits, _Alloc>& __s); // String operations: const _CharT* c_str() const { // MT: This assumes concurrent writes are OK. size_type __n = this->size(); traits_type::assign(_M_data()[__n], _Rep::_S_terminal); return _M_data(); } const _CharT* data() const { return _M_data(); } allocator_type get_allocator() const { return _M_dataplus; } size_type find(const _CharT* __s, size_type __pos, size_type __n) const; size_type find(const basic_string& __str, size_type __pos = 0) const { return this->find(__str.data(), __pos, __str.size()); } size_type find(const _CharT* __s, size_type __pos = 0) const { return this->find(__s, __pos, traits_type::length(__s)); } size_type find(_CharT __c, size_type __pos = 0) const; size_type rfind(const basic_string& __str, size_type __pos = npos) const { return this->rfind(__str.data(), __pos, __str.size()); } size_type rfind(const _CharT* __s, size_type __pos, size_type __n) const; size_type rfind(const _CharT* __s, size_type __pos = npos) const { return this->rfind(__s, __pos, traits_type::length(__s)); } size_type rfind(_CharT __c, size_type __pos = npos) const; size_type find_first_of(const basic_string& __str, size_type __pos = 0) const { return this->find_first_of(__str.data(), __pos, __str.size()); } size_type find_first_of(const _CharT* __s, size_type __pos, size_type __n) const; size_type find_first_of(const _CharT* __s, size_type __pos = 0) const { return this->find_first_of(__s, __pos, traits_type::length(__s)); } size_type find_first_of(_CharT __c, size_type __pos = 0) const { return this->find(__c, __pos); } size_type find_last_of(const basic_string& __str, size_type __pos = npos) const { return this->find_last_of(__str.data(), __pos, __str.size()); } size_type find_last_of(const _CharT* __s, size_type __pos, size_type __n) const; size_type find_last_of(const _CharT* __s, size_type __pos = npos) const { return this->find_last_of(__s, __pos, traits_type::length(__s)); } size_type find_last_of(_CharT __c, size_type __pos = npos) const { return this->rfind(__c, __pos); } size_type find_first_not_of(const basic_string& __str, size_type __pos = 0) const { return this->find_first_not_of(__str.data(), __pos, __str.size()); } size_type find_first_not_of(const _CharT* __s, size_type __pos, size_type __n) const; size_type find_first_not_of(const _CharT* __s, size_type __pos = 0) const { return this->find_first_not_of(__s, __pos, traits_type::length(__s)); } size_type find_first_not_of(_CharT __c, size_type __pos = 0) const; size_type find_last_not_of(const basic_string& __str, size_type __pos = npos) const { return this->find_last_not_of(__str.data(), __pos, __str.size()); } size_type find_last_not_of(const _CharT* __s, size_type __pos, size_type __n) const; size_type find_last_not_of(const _CharT* __s, size_type __pos = npos) const { return this->find_last_not_of(__s, __pos, traits_type::length(__s)); } size_type find_last_not_of(_CharT __c, size_type __pos = npos) const; basic_string substr(size_type __pos = 0, size_type __n = npos) const { __OUTOFRANGE(__pos > this->size()); return basic_string(*this, __pos, __n); } int compare(const basic_string& __str) const { size_type __size = this->size(); size_type __osize = __str.size(); size_type __len = min(__size, __osize); int __r = traits_type::compare(_M_data(), __str.data(), __len); if (!__r) __r = __size - __osize; return __r; } int compare(size_type __pos, size_type __n, const basic_string& __str) const; int compare(size_type __pos1, size_type __n1, const basic_string& __str, size_type __pos2, size_type __n2) const; int compare(const _CharT* __s) const; int compare(size_type __pos, size_type __n1, const _CharT* __s, size_type __n2 = npos) const; private: static const _CharT* _S_find (const _CharT* __beg, const _CharT* __end, _CharT __c); }; template inline basic_string<_CharT, _Traits, _Alloc>:: basic_string() : _M_dataplus(_S_empty_rep()._M_refcopy(), _Alloc()) { } // operator+ template basic_string<_CharT, _Traits, _Alloc> operator+(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { basic_string<_CharT, _Traits, _Alloc> __str(__lhs); __str.append(__rhs); return __str; } template basic_string<_CharT,_Traits,_Alloc> operator+(const _CharT* __lhs, const basic_string<_CharT,_Traits,_Alloc>& __rhs); template basic_string<_CharT,_Traits,_Alloc> operator+(_CharT __lhs, const basic_string<_CharT,_Traits,_Alloc>& __rhs); template inline basic_string<_CharT, _Traits, _Alloc> operator+(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const _CharT* __rhs) { basic_string<_CharT, _Traits, _Alloc> __str(__lhs); __str.append(__rhs); return __str; } template inline basic_string<_CharT, _Traits, _Alloc> operator+(const basic_string<_CharT, _Traits, _Alloc>& __lhs, _CharT __rhs) { typedef basic_string<_CharT, _Traits, _Alloc> __string_type; typedef typename __string_type::size_type __size_type; __string_type __str(__lhs); __str.append(__size_type(1), __rhs); return __str; } // operator == template inline bool operator==(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __lhs.compare(__rhs) == 0; } template inline bool operator==(const _CharT* __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __rhs.compare(__lhs) == 0; } template inline bool operator==(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const _CharT* __rhs) { return __lhs.compare(__rhs) == 0; } // operator != template inline bool operator!=(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __rhs.compare(__lhs) != 0; } template inline bool operator!=(const _CharT* __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __rhs.compare(__lhs) != 0; } template inline bool operator!=(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const _CharT* __rhs) { return __lhs.compare(__rhs) != 0; } // operator < template inline bool operator<(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __lhs.compare(__rhs) < 0; } template inline bool operator<(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const _CharT* __rhs) { return __lhs.compare(__rhs) < 0; } template inline bool operator<(const _CharT* __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __rhs.compare(__lhs) > 0; } // operator > template inline bool operator>(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __lhs.compare(__rhs) > 0; } template inline bool operator>(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const _CharT* __rhs) { return __lhs.compare(__rhs) > 0; } template inline bool operator>(const _CharT* __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __rhs.compare(__lhs) < 0; } // operator <= template inline bool operator<=(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __lhs.compare(__rhs) <= 0; } template inline bool operator<=(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const _CharT* __rhs) { return __lhs.compare(__rhs) <= 0; } template inline bool operator<=(const _CharT* __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __rhs.compare(__lhs) >= 0; } // operator >= template inline bool operator>=(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __lhs.compare(__rhs) >= 0; } template inline bool operator>=(const basic_string<_CharT, _Traits, _Alloc>& __lhs, const _CharT* __rhs) { return __lhs.compare(__rhs) >= 0; } template inline bool operator>=(const _CharT* __lhs, const basic_string<_CharT, _Traits, _Alloc>& __rhs) { return __rhs.compare(__lhs) <= 0; } template inline void swap(basic_string<_CharT, _Traits, _Alloc>& __lhs, basic_string<_CharT, _Traits, _Alloc>& __rhs) { __lhs.swap(__rhs); } template basic_istream<_CharT, _Traits>& operator>>(basic_istream<_CharT, _Traits>& __is, basic_string<_CharT, _Traits, _Alloc>& __str); template basic_ostream<_CharT, _Traits>& operator<<(basic_ostream<_CharT, _Traits>& __os, const basic_string<_CharT, _Traits, _Alloc>& __str); template basic_istream<_CharT,_Traits>& getline(basic_istream<_CharT, _Traits>& __is, basic_string<_CharT, _Traits, _Alloc>& __str, _CharT __delim); template inline basic_istream<_CharT,_Traits>& getline(basic_istream<_CharT, _Traits>& __is, basic_string<_CharT, _Traits, _Alloc>& __str); } // namespace std #endif /* _CPP_BITS_STRING_H */