// -*- C++ -*- //===---------------------------- deque -----------------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #ifndef _LIBCPP_DEQUE #define _LIBCPP_DEQUE /* deque synopsis namespace std { template > class deque { public: // types: typedef T value_type; typedef Allocator allocator_type; typedef typename allocator_type::reference reference; typedef typename allocator_type::const_reference const_reference; typedef implementation-defined iterator; typedef implementation-defined const_iterator; typedef typename allocator_type::size_type size_type; typedef typename allocator_type::difference_type difference_type; typedef typename allocator_type::pointer pointer; typedef typename allocator_type::const_pointer const_pointer; typedef std::reverse_iterator reverse_iterator; typedef std::reverse_iterator const_reverse_iterator; // construct/copy/destroy: deque(); explicit deque(const allocator_type& a); explicit deque(size_type n); deque(size_type n, const value_type& v); deque(size_type n, const value_type& v, const allocator_type& a); template deque(InputIterator f, InputIterator l); template deque(InputIterator f, InputIterator l, const allocator_type& a); deque(const deque& c); deque(deque&& c); deque(initializer_list il, const Allocator& a = allocator_type()); deque(const deque& c, const allocator_type& a); deque(deque&& c, const allocator_type& a); ~deque(); deque& operator=(const deque& c); deque& operator=(deque&& c); deque& operator=(initializer_list il); template void assign(InputIterator f, InputIterator l); void assign(size_type n, const value_type& v); void assign(initializer_list il); allocator_type get_allocator() const; // iterators: iterator begin(); const_iterator begin() const; iterator end(); const_iterator end() const; reverse_iterator rbegin(); const_reverse_iterator rbegin() const; reverse_iterator rend(); const_reverse_iterator rend() const; const_iterator cbegin() const; const_iterator cend() const; const_reverse_iterator crbegin() const; const_reverse_iterator crend() const; // capacity: size_type size() const; size_type max_size() const; void resize(size_type n); void resize(size_type n, const value_type& v); void shrink_to_fit(); bool empty() const; // element access: reference operator[](size_type i); const_reference operator[](size_type i) const; reference at(size_type i); const_reference at(size_type i) const; reference front(); const_reference front() const; reference back(); const_reference back() const; // modifiers: void push_front(const value_type& v); void push_front(value_type&& v); void push_back(const value_type& v); void push_back(value_type&& v); template void emplace_front(Args&&... args); template void emplace_back(Args&&... args); template iterator emplace(const_iterator p, Args&&... args); iterator insert(const_iterator p, const value_type& v); iterator insert(const_iterator p, value_type&& v); iterator insert(const_iterator p, size_type n, const value_type& v); template iterator insert (const_iterator p, InputIterator f, InputIterator l); iterator insert(const_iterator p, initializer_list il); void pop_front(); void pop_back(); iterator erase(const_iterator p); iterator erase(const_iterator f, const_iterator l); void swap(deque& c); void clear(); }; template bool operator==(const deque& x, const deque& y); template bool operator< (const deque& x, const deque& y); template bool operator!=(const deque& x, const deque& y); template bool operator> (const deque& x, const deque& y); template bool operator>=(const deque& x, const deque& y); template bool operator<=(const deque& x, const deque& y); // specialized algorithms: template void swap(deque& x, deque& y); } // std */ #pragma GCC system_header #include <__config> #include <__split_buffer> #include #include #include #include #include _LIBCPP_BEGIN_NAMESPACE_STD template class __deque_base; template class __deque_iterator; template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type* = 0); template _OutputIterator copy(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r); template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r); template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy_backward(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type* = 0); template _OutputIterator copy_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r); template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r); template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type* = 0); template _OutputIterator move(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r); template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r); template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move_backward(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type* = 0); template _OutputIterator move_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r); template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r); template class __deque_iterator { typedef _MapPointer __map_iterator; public: typedef _Pointer pointer; typedef _DiffType difference_type; private: __map_iterator __m_iter_; pointer __ptr_; static const difference_type __block_size = _BlockSize; public: typedef _ValueType value_type; typedef random_access_iterator_tag iterator_category; typedef _Reference reference; _LIBCPP_INLINE_VISIBILITY __deque_iterator() {} template _LIBCPP_INLINE_VISIBILITY __deque_iterator(const __deque_iterator& __it, typename enable_if::value>::type* = 0) : __m_iter_(__it.__m_iter_), __ptr_(__it.__ptr_) {} _LIBCPP_INLINE_VISIBILITY reference operator*() const {return *__ptr_;} _LIBCPP_INLINE_VISIBILITY pointer operator->() const {return __ptr_;} _LIBCPP_INLINE_VISIBILITY __deque_iterator& operator++() { if (++__ptr_ - *__m_iter_ == __block_size) { ++__m_iter_; __ptr_ = *__m_iter_; } return *this; } _LIBCPP_INLINE_VISIBILITY __deque_iterator operator++(int) { __deque_iterator __tmp = *this; ++(*this); return __tmp; } _LIBCPP_INLINE_VISIBILITY __deque_iterator& operator--() { if (__ptr_ == *__m_iter_) { --__m_iter_; __ptr_ = *__m_iter_ + __block_size; } --__ptr_; return *this; } _LIBCPP_INLINE_VISIBILITY __deque_iterator operator--(int) { __deque_iterator __tmp = *this; --(*this); return __tmp; } _LIBCPP_INLINE_VISIBILITY __deque_iterator& operator+=(difference_type __n) { if (__n != 0) { __n += __ptr_ - *__m_iter_; if (__n > 0) { __m_iter_ += __n / __block_size; __ptr_ = *__m_iter_ + __n % __block_size; } else // (__n < 0) { difference_type __z = __block_size - 1 - __n; __m_iter_ -= __z / __block_size; __ptr_ = *__m_iter_ + (__block_size - 1 - __z % __block_size); } } return *this; } _LIBCPP_INLINE_VISIBILITY __deque_iterator& operator-=(difference_type __n) { return *this += -__n; } _LIBCPP_INLINE_VISIBILITY __deque_iterator operator+(difference_type __n) const { __deque_iterator __t(*this); __t += __n; return __t; } _LIBCPP_INLINE_VISIBILITY __deque_iterator operator-(difference_type __n) const { __deque_iterator __t(*this); __t -= __n; return __t; } _LIBCPP_INLINE_VISIBILITY friend __deque_iterator operator+(difference_type __n, const __deque_iterator& __it) {return __it + __n;} _LIBCPP_INLINE_VISIBILITY friend difference_type operator-(const __deque_iterator& __x, const __deque_iterator& __y) { if (__x != __y) return (__x.__m_iter_ - __y.__m_iter_) * __block_size + (__x.__ptr_ - *__x.__m_iter_) - (__y.__ptr_ - *__y.__m_iter_); return 0; } _LIBCPP_INLINE_VISIBILITY reference operator[](difference_type __n) const {return *(*this + __n);} _LIBCPP_INLINE_VISIBILITY friend bool operator==(const __deque_iterator& __x, const __deque_iterator& __y) {return __x.__ptr_ == __y.__ptr_;} _LIBCPP_INLINE_VISIBILITY friend bool operator!=(const __deque_iterator& __x, const __deque_iterator& __y) {return !(__x == __y);} _LIBCPP_INLINE_VISIBILITY friend bool operator<(const __deque_iterator& __x, const __deque_iterator& __y) {return __x.__m_iter_ < __y.__m_iter_ || (__x.__m_iter_ == __y.__m_iter_ && __x.__ptr_ < __y.__ptr_);} _LIBCPP_INLINE_VISIBILITY friend bool operator>(const __deque_iterator& __x, const __deque_iterator& __y) {return __y < __x;} _LIBCPP_INLINE_VISIBILITY friend bool operator<=(const __deque_iterator& __x, const __deque_iterator& __y) {return !(__y < __x);} _LIBCPP_INLINE_VISIBILITY friend bool operator>=(const __deque_iterator& __x, const __deque_iterator& __y) {return !(__x < __y);} private: _LIBCPP_INLINE_VISIBILITY __deque_iterator(__map_iterator __m, pointer __p) : __m_iter_(__m), __ptr_(__p) {} template friend class __deque_base; template friend class deque; template friend class __deque_iterator; template friend __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type*); template friend _OutputIterator copy(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r); template friend __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r); template friend __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy_backward(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type*); template friend _OutputIterator copy_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r); template friend __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r); template friend __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type*); template friend _OutputIterator move(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r); template friend __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r); template friend __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move_backward(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type*); template friend _OutputIterator move_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r); template friend __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r); }; // copy template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type*) { typedef typename __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2>::difference_type difference_type; typedef typename __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2>::pointer pointer; while (__f != __l) { pointer __rb = __r.__ptr_; pointer __re = *__r.__m_iter_ + _B2; difference_type __bs = __re - __rb; difference_type __n = __l - __f; _RAIter __m = __l; if (__n > __bs) { __n = __bs; __m = __f + __n; } _STD::copy(__f, __m, __rb); __f = __m; __r += __n; } return __r; } template _OutputIterator copy(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r) { typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::difference_type difference_type; typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::pointer pointer; difference_type __n = __l - __f; while (__n > 0) { pointer __fb = __f.__ptr_; pointer __fe = *__f.__m_iter_ + _B1; difference_type __bs = __fe - __fb; if (__bs > __n) { __bs = __n; __fe = __fb + __bs; } __r = _STD::copy(__fb, __fe, __r); __n -= __bs; __f += __bs; } return __r; } template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r) { typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::difference_type difference_type; typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::pointer pointer; difference_type __n = __l - __f; while (__n > 0) { pointer __fb = __f.__ptr_; pointer __fe = *__f.__m_iter_ + _B1; difference_type __bs = __fe - __fb; if (__bs > __n) { __bs = __n; __fe = __fb + __bs; } __r = _STD::copy(__fb, __fe, __r); __n -= __bs; __f += __bs; } return __r; } // copy_backward template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy_backward(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type*) { typedef typename __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2>::difference_type difference_type; typedef typename __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2>::pointer pointer; while (__f != __l) { __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __rp = prev(__r); pointer __rb = *__rp.__m_iter_; pointer __re = __rp.__ptr_ + 1; difference_type __bs = __re - __rb; difference_type __n = __l - __f; _RAIter __m = __f; if (__n > __bs) { __n = __bs; __m = __l - __n; } _STD::copy_backward(__m, __l, __re); __l = __m; __r -= __n; } return __r; } template _OutputIterator copy_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r) { typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::difference_type difference_type; typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::pointer pointer; difference_type __n = __l - __f; while (__n > 0) { --__l; pointer __lb = *__l.__m_iter_; pointer __le = __l.__ptr_ + 1; difference_type __bs = __le - __lb; if (__bs > __n) { __bs = __n; __lb = __le - __bs; } __r = _STD::copy_backward(__lb, __le, __r); __n -= __bs; __l -= __bs - 1; } return __r; } template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> copy_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r) { typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::difference_type difference_type; typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::pointer pointer; difference_type __n = __l - __f; while (__n > 0) { --__l; pointer __lb = *__l.__m_iter_; pointer __le = __l.__ptr_ + 1; difference_type __bs = __le - __lb; if (__bs > __n) { __bs = __n; __lb = __le - __bs; } __r = _STD::copy_backward(__lb, __le, __r); __n -= __bs; __l -= __bs - 1; } return __r; } // move template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type*) { typedef typename __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2>::difference_type difference_type; typedef typename __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2>::pointer pointer; while (__f != __l) { pointer __rb = __r.__ptr_; pointer __re = *__r.__m_iter_ + _B2; difference_type __bs = __re - __rb; difference_type __n = __l - __f; _RAIter __m = __l; if (__n > __bs) { __n = __bs; __m = __f + __n; } _STD::move(__f, __m, __rb); __f = __m; __r += __n; } return __r; } template _OutputIterator move(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r) { typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::difference_type difference_type; typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::pointer pointer; difference_type __n = __l - __f; while (__n > 0) { pointer __fb = __f.__ptr_; pointer __fe = *__f.__m_iter_ + _B1; difference_type __bs = __fe - __fb; if (__bs > __n) { __bs = __n; __fe = __fb + __bs; } __r = _STD::move(__fb, __fe, __r); __n -= __bs; __f += __bs; } return __r; } template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r) { typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::difference_type difference_type; typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::pointer pointer; difference_type __n = __l - __f; while (__n > 0) { pointer __fb = __f.__ptr_; pointer __fe = *__f.__m_iter_ + _B1; difference_type __bs = __fe - __fb; if (__bs > __n) { __bs = __n; __fe = __fb + __bs; } __r = _STD::move(__fb, __fe, __r); __n -= __bs; __f += __bs; } return __r; } // move_backward template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move_backward(_RAIter __f, _RAIter __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type*) { typedef typename __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2>::difference_type difference_type; typedef typename __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2>::pointer pointer; while (__f != __l) { __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __rp = prev(__r); pointer __rb = *__rp.__m_iter_; pointer __re = __rp.__ptr_ + 1; difference_type __bs = __re - __rb; difference_type __n = __l - __f; _RAIter __m = __f; if (__n > __bs) { __n = __bs; __m = __l - __n; } _STD::move_backward(__m, __l, __re); __l = __m; __r -= __n; } return __r; } template _OutputIterator move_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, _OutputIterator __r) { typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::difference_type difference_type; typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::pointer pointer; difference_type __n = __l - __f; while (__n > 0) { --__l; pointer __lb = *__l.__m_iter_; pointer __le = __l.__ptr_ + 1; difference_type __bs = __le - __lb; if (__bs > __n) { __bs = __n; __lb = __le - __bs; } __r = _STD::move_backward(__lb, __le, __r); __n -= __bs; __l -= __bs - 1; } return __r; } template __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> move_backward(__deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __f, __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1> __l, __deque_iterator<_V2, _P2, _R2, _M2, _D2, _B2> __r) { typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::difference_type difference_type; typedef typename __deque_iterator<_V1, _P1, _R1, _M1, _D1, _B1>::pointer pointer; difference_type __n = __l - __f; while (__n > 0) { --__l; pointer __lb = *__l.__m_iter_; pointer __le = __l.__ptr_ + 1; difference_type __bs = __le - __lb; if (__bs > __n) { __bs = __n; __lb = __le - __bs; } __r = _STD::move_backward(__lb, __le, __r); __n -= __bs; __l -= __bs - 1; } return __r; } template class __deque_base_common { protected: void __throw_length_error() const; void __throw_out_of_range() const; }; template void __deque_base_common<__b>::__throw_length_error() const { #ifndef _LIBCPP_NO_EXCEPTIONS throw length_error("deque"); #endif } template void __deque_base_common<__b>::__throw_out_of_range() const { #ifndef _LIBCPP_NO_EXCEPTIONS throw out_of_range("deque"); #endif } template class __deque_base : protected __deque_base_common { __deque_base(const __deque_base& __c); __deque_base& operator=(const __deque_base& __c); protected: typedef _Tp value_type; typedef _Allocator allocator_type; typedef allocator_traits __alloc_traits; typedef value_type& reference; typedef const value_type& const_reference; typedef typename __alloc_traits::size_type size_type; typedef typename __alloc_traits::difference_type difference_type; typedef typename __alloc_traits::pointer pointer; typedef typename __alloc_traits::const_pointer const_pointer; static const difference_type __block_size = sizeof(value_type) < 256 ? 4096 / sizeof(value_type) : 16; typedef typename __alloc_traits::template #ifndef _LIBCPP_HAS_NO_TEMPLATE_ALIASES rebind_alloc #else rebind_alloc::other #endif __pointer_allocator; typedef allocator_traits<__pointer_allocator> __map_traits; typedef typename __map_traits::pointer __map_pointer; typedef typename __map_traits::const_pointer __map_const_pointer; typedef __split_buffer __map; typedef __deque_iterator iterator; typedef __deque_iterator const_iterator; __map __map_; size_type __start_; __compressed_pair __size_; iterator begin(); const_iterator begin() const; iterator end(); const_iterator end() const; _LIBCPP_INLINE_VISIBILITY size_type& size() {return __size_.first();} _LIBCPP_INLINE_VISIBILITY const size_type& size() const {return __size_.first();} _LIBCPP_INLINE_VISIBILITY allocator_type& __alloc() {return __size_.second();} _LIBCPP_INLINE_VISIBILITY const allocator_type& __alloc() const {return __size_.second();} __deque_base(); explicit __deque_base(const allocator_type& __a); ~__deque_base(); #ifdef _LIBCPP_MOVE __deque_base(__deque_base&& __c); __deque_base(__deque_base&& __c, const allocator_type& __a); #endif void swap(__deque_base& __c); void clear(); bool __invariants() const; void __move_assign(__deque_base& __c) { __map_ = _STD::move(__c.__map_); __start_ = __c.__start_; size() = __c.size(); __move_assign_alloc(__c); __c.__start_ = __c.size() = 0; } void __move_assign_alloc(__deque_base& __c) {__move_assign_alloc(__c, integral_constant());} private: void __move_assign_alloc(const __deque_base& __c, true_type) { __alloc() = _STD::move(__c.__alloc()); } void __move_assign_alloc(const __deque_base& __c, false_type) {} static void __swap_alloc(allocator_type& __x, allocator_type& __y) {__swap_alloc(__x, __y, integral_constant());} static void __swap_alloc(allocator_type& __x, allocator_type& __y, true_type) { using _STD::swap; swap(__x, __y); } static void __swap_alloc(allocator_type& __x, allocator_type& __y, false_type) {} }; template bool __deque_base<_Tp, _Allocator>::__invariants() const { if (!__map_.__invariants()) return false; if (__map_.size() >= size_type(-1) / __block_size) return false; for (typename __map::const_iterator __i = __map_.begin(), __e = __map_.end(); __i != __e; ++__i) if (*__i == nullptr) return false; if (__map_.size() != 0) { if (size() >= __map_.size() * __block_size) return false; if (__start_ >= __map_.size() * __block_size - size()) return false; } else { if (size() != 0) return false; if (__start_ != 0) return false; } return true; } template typename __deque_base<_Tp, _Allocator>::iterator __deque_base<_Tp, _Allocator>::begin() { __map_pointer __mp = __map_.begin() + __start_ / __block_size; return iterator(__mp, __map_.empty() ? 0 : *__mp + __start_ % __block_size); } template typename __deque_base<_Tp, _Allocator>::const_iterator __deque_base<_Tp, _Allocator>::begin() const { __map_const_pointer __mp = __map_.begin() + __start_ / __block_size; return const_iterator(__mp, __map_.empty() ? 0 : *__mp + __start_ % __block_size); } template typename __deque_base<_Tp, _Allocator>::iterator __deque_base<_Tp, _Allocator>::end() { size_type __p = size() + __start_; __map_pointer __mp = __map_.begin() + __p / __block_size; return iterator(__mp, __map_.empty() ? 0 : *__mp + __p % __block_size); } template typename __deque_base<_Tp, _Allocator>::const_iterator __deque_base<_Tp, _Allocator>::end() const { size_type __p = size() + __start_; __map_const_pointer __mp = __map_.begin() + __p / __block_size; return const_iterator(__mp, __map_.empty() ? 0 : *__mp + __p % __block_size); } template inline _LIBCPP_INLINE_VISIBILITY __deque_base<_Tp, _Allocator>::__deque_base() : __start_(0), __size_(0) {} template inline _LIBCPP_INLINE_VISIBILITY __deque_base<_Tp, _Allocator>::__deque_base(const allocator_type& __a) : __map_(__pointer_allocator(__a)), __start_(0), __size_(0, __a) {} template __deque_base<_Tp, _Allocator>::~__deque_base() { clear(); typename __map::iterator __i = __map_.begin(); typename __map::iterator __e = __map_.end(); for (; __i != __e; ++__i) __alloc_traits::deallocate(__alloc(), *__i, __block_size); } #ifdef _LIBCPP_MOVE template __deque_base<_Tp, _Allocator>::__deque_base(__deque_base&& __c) : __map_(_STD::move(__c.__map_)), __start_(_STD::move(__c.__start_)), __size_(_STD::move(__c.__size_)) { __c.__start_ = 0; __c.size() = 0; } template __deque_base<_Tp, _Allocator>::__deque_base(__deque_base&& __c, const allocator_type& __a) : __map_(_STD::move(__c.__map_), __pointer_allocator(__a)), __start_(_STD::move(__c.__start_)), __size_(_STD::move(__c.size()), __a) { if (__a == __c.__alloc()) { __c.__start_ = 0; __c.size() = 0; } else { __map_.clear(); __start_ = 0; size() = 0; } } #endif template void __deque_base<_Tp, _Allocator>::swap(__deque_base& __c) { __map_.swap(__c.__map_); _STD::swap(__start_, __c.__start_); _STD::swap(size(), __c.size()); __swap_alloc(__alloc(), __c.__alloc()); } template void __deque_base<_Tp, _Allocator>::clear() { allocator_type& __a = __alloc(); for (iterator __i = begin(), __e = end(); __i != __e; ++__i) __alloc_traits::destroy(__a, addressof(*__i)); size() = 0; while (__map_.size() > 2) { __alloc_traits::deallocate(__a, __map_.front(), __block_size); __map_.pop_front(); } switch (__map_.size()) { case 1: __start_ = __block_size / 2; break; case 2: __start_ = __block_size; break; } } template > class deque : private __deque_base<_Tp, _Allocator> { public: // types: typedef _Tp value_type; typedef _Allocator allocator_type; typedef __deque_base __base; typedef typename __base::__alloc_traits __alloc_traits; typedef typename __base::reference reference; typedef typename __base::const_reference const_reference; typedef typename __base::iterator iterator; typedef typename __base::const_iterator const_iterator; typedef typename __base::size_type size_type; typedef typename __base::difference_type difference_type; typedef typename __base::pointer pointer; typedef typename __base::const_pointer const_pointer; typedef _STD::reverse_iterator reverse_iterator; typedef _STD::reverse_iterator const_reverse_iterator; // construct/copy/destroy: _LIBCPP_INLINE_VISIBILITY deque() {} _LIBCPP_INLINE_VISIBILITY deque(const allocator_type& __a) : __base(__a) {} explicit deque(size_type __n); deque(size_type __n, const value_type& __v); deque(size_type __n, const value_type& __v, const allocator_type& __a); template deque(_InputIter __f, _InputIter __l, typename enable_if<__is_input_iterator<_InputIter>::value>::type* = 0); template deque(_InputIter __f, _InputIter __l, const allocator_type& __a, typename enable_if<__is_input_iterator<_InputIter>::value>::type* = 0); deque(const deque& __c); deque(const deque& __c, const allocator_type& __a); deque(initializer_list __il); deque(initializer_list __il, const allocator_type& __a); deque& operator=(const deque& __c); deque& operator=(initializer_list __il) {assign(__il); return *this;} #ifdef _LIBCPP_MOVE deque(deque&& __c); deque(deque&& __c, const allocator_type& __a); deque& operator=(deque&& __c); #endif template void assign(_InputIter __f, _InputIter __l, typename enable_if<__is_input_iterator<_InputIter>::value && !__is_random_access_iterator<_InputIter>::value>::type* = 0); template void assign(_RAIter __f, _RAIter __l, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type* = 0); void assign(size_type __n, const value_type& __v); void assign(initializer_list __il) {assign(__il.begin(), __il.end());} allocator_type get_allocator() const; // iterators: iterator begin() {return __base::begin();} const_iterator begin() const {return __base::begin();} iterator end() {return __base::end();} const_iterator end() const {return __base::end();} reverse_iterator rbegin() {return reverse_iterator(__base::end());} const_reverse_iterator rbegin() const {return const_reverse_iterator(__base::end());} reverse_iterator rend() {return reverse_iterator(__base::begin());} const_reverse_iterator rend() const {return const_reverse_iterator(__base::begin());} const_iterator cbegin() const {return __base::begin();} const_iterator cend() const {return __base::end();} const_reverse_iterator crbegin() const {return const_reverse_iterator(__base::end());} const_reverse_iterator crend() const {return const_reverse_iterator(__base::begin());} // capacity: _LIBCPP_INLINE_VISIBILITY size_type size() const {return __base::size();} size_type max_size() const {return __alloc_traits::max_size(__base::__alloc());} void resize(size_type __n); void resize(size_type __n, const value_type& __v); void shrink_to_fit(); bool empty() const {return __base::size() == 0;} // element access: reference operator[](size_type __i); const_reference operator[](size_type __i) const; reference at(size_type __i); const_reference at(size_type __i) const; reference front(); const_reference front() const; reference back(); const_reference back() const; // 23.2.2.3 modifiers: void push_front(const value_type& __v); void push_back(const value_type& __v); #ifdef _LIBCPP_MOVE template void emplace_front(_Args&&... __args); template void emplace_back(_Args&&... __args); template iterator emplace(const_iterator __p, _Args&&... __args); void push_front(value_type&& __v); void push_back(value_type&& __v); iterator insert(const_iterator __p, value_type&& __v); #endif iterator insert(const_iterator __p, const value_type& __v); iterator insert(const_iterator __p, size_type __n, const value_type& __v); template iterator insert (const_iterator __p, _InputIter __f, _InputIter __l, typename enable_if<__is_input_iterator<_InputIter>::value &&!__is_bidirectional_iterator<_InputIter>::value>::type* = 0); template iterator insert (const_iterator __p, _BiIter __f, _BiIter __l, typename enable_if<__is_bidirectional_iterator<_BiIter>::value>::type* = 0); iterator insert(const_iterator __p, initializer_list __il) {return insert(__p, __il.begin(), __il.end());} void pop_front(); void pop_back(); iterator erase(const_iterator __p); iterator erase(const_iterator __f, const_iterator __l); void swap(deque& __c); void clear(); bool __invariants() const {return __base::__invariants();} private: static size_type __recommend_blocks(size_type __n) { return __n / __base::__block_size + (__n % __base::__block_size != 0); } size_type __capacity() const { return __base::__map_.size() == 0 ? 0 : __base::__map_.size() * __base::__block_size - 1; } size_type __front_spare() const { return __base::__start_; } size_type __back_spare() const { return __capacity() - (__base::__start_ + __base::size()); } template void __append(_InpIter __f, _InpIter __l, typename enable_if<__is_input_iterator<_InpIter>::value && !__is_forward_iterator<_InpIter>::value>::type* = 0); template void __append(_ForIter __f, _ForIter __l, typename enable_if<__is_forward_iterator<_ForIter>::value>::type* = 0); void __append(size_type __n); void __append(size_type __n, const value_type& __v); void __erase_to_end(const_iterator __f); void __add_front_capacity(); void __add_front_capacity(size_type __n); void __add_back_capacity(); void __add_back_capacity(size_type __n); iterator __move_and_check(iterator __f, iterator __l, iterator __r, const_pointer& __vt); iterator __move_backward_and_check(iterator __f, iterator __l, iterator __r, const_pointer& __vt); void __move_construct_and_check(iterator __f, iterator __l, iterator __r, const_pointer& __vt); void __move_construct_backward_and_check(iterator __f, iterator __l, iterator __r, const_pointer& __vt); void __copy_assign_alloc(const deque& __c) {__copy_assign_alloc(__c, integral_constant());} void __copy_assign_alloc(const deque& __c, true_type) { if (__base::__alloc() != __c.__alloc()) { clear(); shrink_to_fit(); } __base::__alloc() = __c.__alloc(); __base::__map_.__alloc() = __c.__map_.__alloc(); } void __copy_assign_alloc(const deque& __c, false_type) {} void __move_assign(deque& __c, true_type); void __move_assign(deque& __c, false_type); }; template deque<_Tp, _Allocator>::deque(size_type __n) { if (__n > 0) __append(__n); } template deque<_Tp, _Allocator>::deque(size_type __n, const value_type& __v) { if (__n > 0) __append(__n, __v); } template deque<_Tp, _Allocator>::deque(size_type __n, const value_type& __v, const allocator_type& __a) : __base(__a) { if (__n > 0) __append(__n, __v); } template template deque<_Tp, _Allocator>::deque(_InputIter __f, _InputIter __l, typename enable_if<__is_input_iterator<_InputIter>::value>::type*) { __append(__f, __l); } template template deque<_Tp, _Allocator>::deque(_InputIter __f, _InputIter __l, const allocator_type& __a, typename enable_if<__is_input_iterator<_InputIter>::value>::type*) : __base(__a) { __append(__f, __l); } template deque<_Tp, _Allocator>::deque(const deque& __c) : __base(__alloc_traits::select_on_container_copy_construction(__c.__alloc())) { __append(__c.begin(), __c.end()); } template deque<_Tp, _Allocator>::deque(const deque& __c, const allocator_type& __a) : __base(__a) { __append(__c.begin(), __c.end()); } template deque<_Tp, _Allocator>::deque(initializer_list __il) { __append(__il.begin(), __il.end()); } template deque<_Tp, _Allocator>::deque(initializer_list __il, const allocator_type& __a) : __base(__a) { __append(__il.begin(), __il.end()); } template deque<_Tp, _Allocator>& deque<_Tp, _Allocator>::operator=(const deque& __c) { if (this != &__c) { __copy_assign_alloc(__c); assign(__c.begin(), __c.end()); } return *this; } #ifdef _LIBCPP_MOVE template inline deque<_Tp, _Allocator>::deque(deque&& __c) : __base(_STD::move(__c)) { } template inline deque<_Tp, _Allocator>::deque(deque&& __c, const allocator_type& __a) : __base(_STD::move(__c), __a) { if (__a != __c.__alloc()) { typedef move_iterator _I; assign(_I(__c.begin()), _I(__c.end())); } } template inline deque<_Tp, _Allocator>& deque<_Tp, _Allocator>::operator=(deque&& __c) { __move_assign(__c, integral_constant()); return *this; } template void deque<_Tp, _Allocator>::__move_assign(deque& __c, false_type) { if (__base::__alloc() != __c.__alloc()) { typedef move_iterator _I; assign(_I(__c.begin()), _I(__c.end())); } else __move_assign(__c, true_type()); } template void deque<_Tp, _Allocator>::__move_assign(deque& __c, true_type) { clear(); shrink_to_fit(); __base::__move_assign(__c); } #endif template template void deque<_Tp, _Allocator>::assign(_InputIter __f, _InputIter __l, typename enable_if<__is_input_iterator<_InputIter>::value && !__is_random_access_iterator<_InputIter>::value>::type*) { iterator __i = __base::begin(); iterator __e = __base::end(); for (; __f != __l && __i != __e; ++__f, ++__i) *__i = *__f; if (__f != __l) __append(__f, __l); else __erase_to_end(__i); } template template void deque<_Tp, _Allocator>::assign(_RAIter __f, _RAIter __l, typename enable_if<__is_random_access_iterator<_RAIter>::value>::type*) { if (static_cast(__l - __f) > __base::size()) { _RAIter __m = __f + __base::size(); _STD::copy(__f, __m, __base::begin()); __append(__m, __l); } else __erase_to_end(_STD::copy(__f, __l, __base::begin())); } template void deque<_Tp, _Allocator>::assign(size_type __n, const value_type& __v) { if (__n > __base::size()) { _STD::fill_n(__base::begin(), __base::size(), __v); __n -= __base::size(); __append(__n, __v); } else __erase_to_end(_STD::fill_n(__base::begin(), __n, __v)); } template inline _Allocator deque<_Tp, _Allocator>::get_allocator() const { return __base::__alloc(); } template void deque<_Tp, _Allocator>::resize(size_type __n) { if (__n > __base::size()) __append(__n - __base::size()); else if (__n < __base::size()) __erase_to_end(__base::begin() + __n); } template void deque<_Tp, _Allocator>::resize(size_type __n, const value_type& __v) { if (__n > __base::size()) __append(__n - __base::size(), __v); else if (__n < __base::size()) __erase_to_end(__base::begin() + __n); } template void deque<_Tp, _Allocator>::shrink_to_fit() { allocator_type& __a = __base::__alloc(); if (empty()) { while (__base::__map_.size() > 0) { __alloc_traits::deallocate(__a, __base::__map_.back(), __base::__block_size); __base::__map_.pop_back(); } __base::__start_ = 0; } else { if (__front_spare() >= __base::__block_size) { __alloc_traits::deallocate(__a, __base::__map_.front(), __base::__block_size); __base::__map_.pop_front(); __base::__start_ -= __base::__block_size; } if (__back_spare() >= __base::__block_size) { __alloc_traits::deallocate(__a, __base::__map_.back(), __base::__block_size); __base::__map_.pop_back(); } } __base::__map_.shrink_to_fit(); } template inline typename deque<_Tp, _Allocator>::reference deque<_Tp, _Allocator>::operator[](size_type __i) { size_type __p = __base::__start_ + __i; return *(*(__base::__map_.begin() + __p / __base::__block_size) + __p % __base::__block_size); } template inline typename deque<_Tp, _Allocator>::const_reference deque<_Tp, _Allocator>::operator[](size_type __i) const { size_type __p = __base::__start_ + __i; return *(*(__base::__map_.begin() + __p / __base::__block_size) + __p % __base::__block_size); } template inline typename deque<_Tp, _Allocator>::reference deque<_Tp, _Allocator>::at(size_type __i) { if (__i >= __base::size()) __base::__throw_out_of_range(); size_type __p = __base::__start_ + __i; return *(*(__base::__map_.begin() + __p / __base::__block_size) + __p % __base::__block_size); } template inline typename deque<_Tp, _Allocator>::const_reference deque<_Tp, _Allocator>::at(size_type __i) const { if (__i >= __base::size()) __base::__throw_out_of_range(); size_type __p = __base::__start_ + __i; return *(*(__base::__map_.begin() + __p / __base::__block_size) + __p % __base::__block_size); } template inline typename deque<_Tp, _Allocator>::reference deque<_Tp, _Allocator>::front() { return *(*(__base::__map_.begin() + __base::__start_ / __base::__block_size) + __base::__start_ % __base::__block_size); } template inline typename deque<_Tp, _Allocator>::const_reference deque<_Tp, _Allocator>::front() const { return *(*(__base::__map_.begin() + __base::__start_ / __base::__block_size) + __base::__start_ % __base::__block_size); } template inline typename deque<_Tp, _Allocator>::reference deque<_Tp, _Allocator>::back() { size_type __p = __base::size() + __base::__start_ - 1; return *(*(__base::__map_.begin() + __p / __base::__block_size) + __p % __base::__block_size); } template inline typename deque<_Tp, _Allocator>::const_reference deque<_Tp, _Allocator>::back() const { size_type __p = __base::size() + __base::__start_ - 1; return *(*(__base::__map_.begin() + __p / __base::__block_size) + __p % __base::__block_size); } template void deque<_Tp, _Allocator>::push_back(const value_type& __v) { allocator_type& __a = __base::__alloc(); if (__back_spare() == 0) __add_back_capacity(); // __back_spare() >= 1 __alloc_traits::construct(__a, addressof(*__base::end()), __v); ++__base::size(); } #ifdef _LIBCPP_MOVE template void deque<_Tp, _Allocator>::push_back(value_type&& __v) { allocator_type& __a = __base::__alloc(); if (__back_spare() == 0) __add_back_capacity(); // __back_spare() >= 1 __alloc_traits::construct(__a, addressof(*__base::end()), _STD::move(__v)); ++__base::size(); } template template void deque<_Tp, _Allocator>::emplace_back(_Args&&... __args) { allocator_type& __a = __base::__alloc(); if (__back_spare() == 0) __add_back_capacity(); // __back_spare() >= 1 __alloc_traits::construct(__a, addressof(*__base::end()), _STD::forward<_Args>(__args)...); ++__base::size(); } #endif template void deque<_Tp, _Allocator>::push_front(const value_type& __v) { allocator_type& __a = __base::__alloc(); if (__front_spare() == 0) __add_front_capacity(); // __front_spare() >= 1 __alloc_traits::construct(__a, addressof(*--__base::begin()), __v); --__base::__start_; ++__base::size(); } #ifdef _LIBCPP_MOVE template void deque<_Tp, _Allocator>::push_front(value_type&& __v) { allocator_type& __a = __base::__alloc(); if (__front_spare() == 0) __add_front_capacity(); // __front_spare() >= 1 __alloc_traits::construct(__a, addressof(*--__base::begin()), _STD::move(__v)); --__base::__start_; ++__base::size(); } template template void deque<_Tp, _Allocator>::emplace_front(_Args&&... __args) { allocator_type& __a = __base::__alloc(); if (__front_spare() == 0) __add_front_capacity(); // __front_spare() >= 1 __alloc_traits::construct(__a, addressof(*--__base::begin()), _STD::forward<_Args>(__args)...); --__base::__start_; ++__base::size(); } #endif template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::insert(const_iterator __p, const value_type& __v) { size_type __pos = __p - __base::begin(); size_type __to_end = __base::size() - __pos; allocator_type& __a = __base::__alloc(); if (__pos < __to_end) { // insert by shifting things backward if (__front_spare() == 0) __add_front_capacity(); // __front_spare() >= 1 if (__pos == 0) { __alloc_traits::construct(__a, addressof(*--__base::begin()), __v); --__base::__start_; ++__base::size(); } else { const_pointer __vt = pointer_traits::pointer_to(__v); iterator __b = __base::begin(); iterator __bm1 = prev(__b); if (__vt == pointer_traits::pointer_to(*__b)) __vt = pointer_traits::pointer_to(*__bm1); __alloc_traits::construct(__a, addressof(*__bm1), _STD::move(*__b)); --__base::__start_; ++__base::size(); if (__pos > 1) __b = __move_and_check(next(__b), __b + __pos, __b, __vt); *__b = *__vt; } } else { // insert by shifting things forward if (__back_spare() == 0) __add_back_capacity(); // __back_capacity >= 1 size_type __de = __base::size() - __pos; if (__de == 0) { __alloc_traits::construct(__a, addressof(*__base::end()), __v); ++__base::size(); } else { const_pointer __vt = pointer_traits::pointer_to(__v); iterator __e = __base::end(); iterator __em1 = prev(__e); if (__vt == pointer_traits::pointer_to(*__em1)) __vt = pointer_traits::pointer_to(*__e); __alloc_traits::construct(__a, addressof(*__e), _STD::move(*__em1)); ++__base::size(); if (__de > 1) __e = __move_backward_and_check(__e - __de, __em1, __e, __vt); *--__e = *__vt; } } return __base::begin() + __pos; } #ifdef _LIBCPP_MOVE template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::insert(const_iterator __p, value_type&& __v) { size_type __pos = __p - __base::begin(); size_type __to_end = __base::size() - __pos; allocator_type& __a = __base::__alloc(); if (__pos < __to_end) { // insert by shifting things backward if (__front_spare() == 0) __add_front_capacity(); // __front_spare() >= 1 if (__pos == 0) { __alloc_traits::construct(__a, addressof(*--__base::begin()), _STD::move(__v)); --__base::__start_; ++__base::size(); } else { iterator __b = __base::begin(); iterator __bm1 = prev(__b); __alloc_traits::construct(__a, addressof(*__bm1), _STD::move(*__b)); --__base::__start_; ++__base::size(); if (__pos > 1) __b = _STD::move(next(__b), __b + __pos, __b); *__b = _STD::move(__v); } } else { // insert by shifting things forward if (__back_spare() == 0) __add_back_capacity(); // __back_capacity >= 1 size_type __de = __base::size() - __pos; if (__de == 0) { __alloc_traits::construct(__a, addressof(*__base::end()), _STD::move(__v)); ++__base::size(); } else { iterator __e = __base::end(); iterator __em1 = prev(__e); __alloc_traits::construct(__a, addressof(*__e), _STD::move(*__em1)); ++__base::size(); if (__de > 1) __e = _STD::move_backward(__e - __de, __em1, __e); *--__e = _STD::move(__v); } } return __base::begin() + __pos; } template template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::emplace(const_iterator __p, _Args&&... __args) { size_type __pos = __p - __base::begin(); size_type __to_end = __base::size() - __pos; allocator_type& __a = __base::__alloc(); if (__pos < __to_end) { // insert by shifting things backward if (__front_spare() == 0) __add_front_capacity(); // __front_spare() >= 1 if (__pos == 0) { __alloc_traits::construct(__a, addressof(*--__base::begin()), _STD::forward<_Args>(__args)...); --__base::__start_; ++__base::size(); } else { iterator __b = __base::begin(); iterator __bm1 = prev(__b); __alloc_traits::construct(__a, addressof(*__bm1), _STD::move(*__b)); --__base::__start_; ++__base::size(); if (__pos > 1) __b = _STD::move(next(__b), __b + __pos, __b); *__b = value_type(_STD::forward<_Args>(__args)...); } } else { // insert by shifting things forward if (__back_spare() == 0) __add_back_capacity(); // __back_capacity >= 1 size_type __de = __base::size() - __pos; if (__de == 0) { __alloc_traits::construct(__a, addressof(*__base::end()), _STD::forward<_Args>(__args)...); ++__base::size(); } else { iterator __e = __base::end(); iterator __em1 = prev(__e); __alloc_traits::construct(__a, addressof(*__e), _STD::move(*__em1)); ++__base::size(); if (__de > 1) __e = _STD::move_backward(__e - __de, __em1, __e); *--__e = value_type(_STD::forward<_Args>(__args)...); } } return __base::begin() + __pos; } #endif template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::insert(const_iterator __p, size_type __n, const value_type& __v) { size_type __pos = __p - __base::begin(); size_type __to_end = __base::size() - __pos; allocator_type& __a = __base::__alloc(); if (__pos < __to_end) { // insert by shifting things backward if (__n > __front_spare()) __add_front_capacity(__n - __front_spare()); // __n <= __front_spare() size_type __old_n = __n; iterator __old_begin = __base::begin(); iterator __i = __old_begin; if (__n > __pos) { for (size_type __m = __n - __pos; __m; --__m, --__base::__start_, ++__base::size()) __alloc_traits::construct(__a, addressof(*--__i), __v); __n = __pos; } if (__n > 0) { const_pointer __vt = pointer_traits::pointer_to(__v); iterator __obn = __old_begin + __n; __move_construct_backward_and_check(__old_begin, __obn, __i, __vt); if (__n < __pos) __old_begin = __move_and_check(__obn, __old_begin + __pos, __old_begin, __vt); _STD::fill_n(__old_begin, __n, *__vt); } } else { // insert by shifting things forward size_type __back_capacity = __back_spare(); if (__n > __back_capacity) __add_back_capacity(__n - __back_capacity); // __n <= __back_capacity size_type __old_n = __n; iterator __old_end = __base::end(); iterator __i = __old_end; size_type __de = __base::size() - __pos; if (__n > __de) { for (size_type __m = __n - __de; __m; --__m, ++__i, ++__base::size()) __alloc_traits::construct(__a, addressof(*__i), __v); __n = __de; } if (__n > 0) { const_pointer __vt = pointer_traits::pointer_to(__v); iterator __oen = __old_end - __n; __move_construct_and_check(__oen, __old_end, __i, __vt); if (__n < __de) __old_end = __move_backward_and_check(__old_end - __de, __oen, __old_end, __vt); _STD::fill_n(__old_end - __n, __n, *__vt); } } return __base::begin() + __pos; } template template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::insert(const_iterator __p, _InputIter __f, _InputIter __l, typename enable_if<__is_input_iterator<_InputIter>::value &&!__is_bidirectional_iterator<_InputIter>::value>::type*) { __split_buffer __buf(__base::__alloc()); __buf.__construct_at_end(__f, __l); typedef typename __split_buffer::iterator __bi; return insert(__p, move_iterator<__bi>(__buf.begin()), move_iterator<__bi>(__buf.end())); } template template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::insert(const_iterator __p, _BiIter __f, _BiIter __l, typename enable_if<__is_bidirectional_iterator<_BiIter>::value>::type*) { size_type __n = _STD::distance(__f, __l); size_type __pos = __p - __base::begin(); size_type __to_end = __base::size() - __pos; allocator_type& __a = __base::__alloc(); if (__pos < __to_end) { // insert by shifting things backward if (__n > __front_spare()) __add_front_capacity(__n - __front_spare()); // __n <= __front_spare() size_type __old_n = __n; iterator __old_begin = __base::begin(); iterator __i = __old_begin; _BiIter __m = __f; if (__n > __pos) { __m = __pos < __n / 2 ? _STD::prev(__l, __pos) : _STD::next(__f, __n - __pos); for (_BiIter __j = __m; __j != __f; --__base::__start_, ++__base::size()) __alloc_traits::construct(__a, addressof(*--__i), *--__j); __n = __pos; } if (__n > 0) { iterator __obn = __old_begin + __n; for (iterator __j = __obn; __j != __old_begin;) { __alloc_traits::construct(__a, addressof(*--__i), _STD::move(*--__j)); --__base::__start_; ++__base::size(); } if (__n < __pos) __old_begin = _STD::move(__obn, __old_begin + __pos, __old_begin); _STD::copy(__m, __l, __old_begin); } } else { // insert by shifting things forward size_type __back_capacity = __back_spare(); if (__n > __back_capacity) __add_back_capacity(__n - __back_capacity); // __n <= __back_capacity size_type __old_n = __n; iterator __old_end = __base::end(); iterator __i = __old_end; _BiIter __m = __l; size_type __de = __base::size() - __pos; if (__n > __de) { __m = __de < __n / 2 ? _STD::next(__f, __de) : _STD::prev(__l, __n - __de); for (_BiIter __j = __m; __j != __l; ++__i, ++__j, ++__base::size()) __alloc_traits::construct(__a, addressof(*__i), *__j); __n = __de; } if (__n > 0) { iterator __oen = __old_end - __n; for (iterator __j = __oen; __j != __old_end; ++__i, ++__j, ++__base::size()) __alloc_traits::construct(__a, addressof(*__i), _STD::move(*__j)); if (__n < __de) __old_end = _STD::move_backward(__old_end - __de, __oen, __old_end); _STD::copy_backward(__f, __m, __old_end); } } return __base::begin() + __pos; } template template void deque<_Tp, _Allocator>::__append(_InpIter __f, _InpIter __l, typename enable_if<__is_input_iterator<_InpIter>::value && !__is_forward_iterator<_InpIter>::value>::type*) { for (; __f != __l; ++__f) push_back(*__f); } template template void deque<_Tp, _Allocator>::__append(_ForIter __f, _ForIter __l, typename enable_if<__is_forward_iterator<_ForIter>::value>::type*) { size_type __n = _STD::distance(__f, __l); allocator_type& __a = __base::__alloc(); size_type __back_capacity = __back_spare(); if (__n > __back_capacity) __add_back_capacity(__n - __back_capacity); // __n <= __back_capacity for (iterator __i = __base::end(); __f != __l; ++__i, ++__f, ++__base::size()) __alloc_traits::construct(__a, addressof(*__i), *__f); } template void deque<_Tp, _Allocator>::__append(size_type __n) { allocator_type& __a = __base::__alloc(); size_type __back_capacity = __back_spare(); if (__n > __back_capacity) __add_back_capacity(__n - __back_capacity); // __n <= __back_capacity for (iterator __i = __base::end(); __n; --__n, ++__i, ++__base::size()) __alloc_traits::construct(__a, addressof(*__i)); } template void deque<_Tp, _Allocator>::__append(size_type __n, const value_type& __v) { allocator_type& __a = __base::__alloc(); size_type __back_capacity = __back_spare(); if (__n > __back_capacity) __add_back_capacity(__n - __back_capacity); // __n <= __back_capacity for (iterator __i = __base::end(); __n; --__n, ++__i, ++__base::size()) __alloc_traits::construct(__a, addressof(*__i), __v); } // Create front capacity for one block of elements. // Strong guarantee. Either do it or don't touch anything. template void deque<_Tp, _Allocator>::__add_front_capacity() { allocator_type& __a = __base::__alloc(); if (__back_spare() >= __base::__block_size) { __base::__start_ += __base::__block_size; pointer __pt = __base::__map_.back(); __base::__map_.pop_back(); __base::__map_.push_front(__pt); } // Else if __base::__map_.size() < __base::__map_.capacity() then we need to allocate 1 buffer else if (__base::__map_.size() < __base::__map_.capacity()) { // we can put the new buffer into the map, but don't shift things around // until all buffers are allocated. If we throw, we don't need to fix // anything up (any added buffers are undetectible) if (__base::__map_.__front_spare() > 0) __base::__map_.push_front(__alloc_traits::allocate(__a, __base::__block_size)); else { __base::__map_.push_back(__alloc_traits::allocate(__a, __base::__block_size)); // Done allocating, reorder capacity pointer __pt = __base::__map_.back(); __base::__map_.pop_back(); __base::__map_.push_front(__pt); } __base::__start_ = __base::__map_.size() == 1 ? __base::__block_size / 2 : __base::__start_ + __base::__block_size; } // Else need to allocate 1 buffer, *and* we need to reallocate __map_. else { __split_buffer __buf(max(2 * __base::__map_.capacity(), 1), 0, __base::__map_.__alloc()); #ifndef _LIBCPP_NO_EXCEPTIONS try { #endif __buf.push_back(__alloc_traits::allocate(__a, __base::__block_size)); #ifndef _LIBCPP_NO_EXCEPTIONS } catch (...) { __alloc_traits::deallocate(__a, __buf.front(), __base::__block_size); throw; } #endif for (typename __base::__map_pointer __i = __base::__map_.begin(); __i != __base::__map_.end(); ++__i) __buf.push_back(*__i); _STD::swap(__base::__map_.__first_, __buf.__first_); _STD::swap(__base::__map_.__begin_, __buf.__begin_); _STD::swap(__base::__map_.__end_, __buf.__end_); _STD::swap(__base::__map_.__end_cap(), __buf.__end_cap()); __base::__start_ = __base::__map_.size() == 1 ? __base::__block_size / 2 : __base::__start_ + __base::__block_size; } } // Create front capacity for __n elements. // Strong guarantee. Either do it or don't touch anything. template void deque<_Tp, _Allocator>::__add_front_capacity(size_type __n) { allocator_type& __a = __base::__alloc(); size_type __nb = __recommend_blocks(__n + __base::__map_.empty()); // Number of unused blocks at back: size_type __back_capacity = __back_spare() / __base::__block_size; __back_capacity = min(__back_capacity, __nb); // don't take more than you need __nb -= __back_capacity; // number of blocks need to allocate // If __nb == 0, then we have sufficient capacity. if (__nb == 0) { __base::__start_ += __base::__block_size * __back_capacity; for (; __back_capacity > 0; --__back_capacity) { pointer __pt = __base::__map_.back(); __base::__map_.pop_back(); __base::__map_.push_front(__pt); } } // Else if __nb <= __map_.capacity() - __map_.size() then we need to allocate __nb buffers else if (__nb <= __base::__map_.capacity() - __base::__map_.size()) { // we can put the new buffers into the map, but don't shift things around // until all buffers are allocated. If we throw, we don't need to fix // anything up (any added buffers are undetectible) for (; __nb > 0; --__nb, __base::__start_ += __base::__block_size - (__base::__map_.size() == 1)) { if (__base::__map_.__front_spare() == 0) break; __base::__map_.push_front(__alloc_traits::allocate(__a, __base::__block_size)); } for (; __nb > 0; --__nb, ++__back_capacity) __base::__map_.push_back(__alloc_traits::allocate(__a, __base::__block_size)); // Done allocating, reorder capacity __base::__start_ += __back_capacity * __base::__block_size; for (; __back_capacity > 0; --__back_capacity) { pointer __pt = __base::__map_.back(); __base::__map_.pop_back(); __base::__map_.push_front(__pt); } } // Else need to allocate __nb buffers, *and* we need to reallocate __map_. else { size_type __ds = (__nb + __back_capacity) * __base::__block_size - __base::__map_.empty(); __split_buffer __buf(max(2* __base::__map_.capacity(), __nb + __base::__map_.size()), 0, __base::__map_.__alloc()); #ifndef _LIBCPP_NO_EXCEPTIONS try { #endif for (; __nb > 0; --__nb) __buf.push_back(__alloc_traits::allocate(__a, __base::__block_size)); #ifndef _LIBCPP_NO_EXCEPTIONS } catch (...) { for (typename __base::__map_pointer __i = __buf.begin(); __i != __buf.end(); ++__i) __alloc_traits::deallocate(__a, *__i, __base::__block_size); throw; } #endif for (; __back_capacity > 0; --__back_capacity) { __buf.push_back(__base::__map_.back()); __base::__map_.pop_back(); } for (typename __base::__map_pointer __i = __base::__map_.begin(); __i != __base::__map_.end(); ++__i) __buf.push_back(*__i); _STD::swap(__base::__map_.__first_, __buf.__first_); _STD::swap(__base::__map_.__begin_, __buf.__begin_); _STD::swap(__base::__map_.__end_, __buf.__end_); _STD::swap(__base::__map_.__end_cap(), __buf.__end_cap()); __base::__start_ += __ds; } } // Create back capacity for one block of elements. // Strong guarantee. Either do it or don't touch anything. template void deque<_Tp, _Allocator>::__add_back_capacity() { allocator_type& __a = __base::__alloc(); if (__front_spare() >= __base::__block_size) { __base::__start_ -= __base::__block_size; pointer __pt = __base::__map_.front(); __base::__map_.pop_front(); __base::__map_.push_back(__pt); } // Else if __nb <= __map_.capacity() - __map_.size() then we need to allocate __nb buffers else if (__base::__map_.size() < __base::__map_.capacity()) { // we can put the new buffer into the map, but don't shift things around // until it is allocated. If we throw, we don't need to fix // anything up (any added buffers are undetectible) if (__base::__map_.__back_spare() != 0) __base::__map_.push_back(__alloc_traits::allocate(__a, __base::__block_size)); else { __base::__map_.push_front(__alloc_traits::allocate(__a, __base::__block_size)); // Done allocating, reorder capacity pointer __pt = __base::__map_.front(); __base::__map_.pop_front(); __base::__map_.push_back(__pt); } } // Else need to allocate 1 buffer, *and* we need to reallocate __map_. else { __split_buffer __buf(max(2* __base::__map_.capacity(), 1), __base::__map_.size(), __base::__map_.__alloc()); #ifndef _LIBCPP_NO_EXCEPTIONS try { #endif __buf.push_back(__alloc_traits::allocate(__a, __base::__block_size)); #ifndef _LIBCPP_NO_EXCEPTIONS } catch (...) { __alloc_traits::deallocate(__a, __buf.back(), __base::__block_size); throw; } #endif for (typename __base::__map_pointer __i = __base::__map_.end(); __i != __base::__map_.begin();) __buf.push_front(*--__i); _STD::swap(__base::__map_.__first_, __buf.__first_); _STD::swap(__base::__map_.__begin_, __buf.__begin_); _STD::swap(__base::__map_.__end_, __buf.__end_); _STD::swap(__base::__map_.__end_cap(), __buf.__end_cap()); } } // Create back capacity for __n elements. // Strong guarantee. Either do it or don't touch anything. template void deque<_Tp, _Allocator>::__add_back_capacity(size_type __n) { allocator_type& __a = __base::__alloc(); size_type __nb = __recommend_blocks(__n + __base::__map_.empty()); // Number of unused blocks at front: size_type __front_capacity = __front_spare() / __base::__block_size; __front_capacity = min(__front_capacity, __nb); // don't take more than you need __nb -= __front_capacity; // number of blocks need to allocate // If __nb == 0, then we have sufficient capacity. if (__nb == 0) { __base::__start_ -= __base::__block_size * __front_capacity; for (; __front_capacity > 0; --__front_capacity) { pointer __pt = __base::__map_.front(); __base::__map_.pop_front(); __base::__map_.push_back(__pt); } } // Else if __nb <= __map_.capacity() - __map_.size() then we need to allocate __nb buffers else if (__nb <= __base::__map_.capacity() - __base::__map_.size()) { // we can put the new buffers into the map, but don't shift things around // until all buffers are allocated. If we throw, we don't need to fix // anything up (any added buffers are undetectible) for (; __nb > 0; --__nb) { if (__base::__map_.__back_spare() == 0) break; __base::__map_.push_back(__alloc_traits::allocate(__a, __base::__block_size)); } for (; __nb > 0; --__nb, ++__front_capacity, __base::__start_ += __base::__block_size - (__base::__map_.size() == 1)) __base::__map_.push_front(__alloc_traits::allocate(__a, __base::__block_size)); // Done allocating, reorder capacity __base::__start_ -= __base::__block_size * __front_capacity; for (; __front_capacity > 0; --__front_capacity) { pointer __pt = __base::__map_.front(); __base::__map_.pop_front(); __base::__map_.push_back(__pt); } } // Else need to allocate __nb buffers, *and* we need to reallocate __map_. else { size_type __ds = __front_capacity * __base::__block_size; __split_buffer __buf(max(2* __base::__map_.capacity(), __nb + __base::__map_.size()), __base::__map_.size() - __front_capacity, __base::__map_.__alloc()); #ifndef _LIBCPP_NO_EXCEPTIONS try { #endif for (; __nb > 0; --__nb) __buf.push_back(__alloc_traits::allocate(__a, __base::__block_size)); #ifndef _LIBCPP_NO_EXCEPTIONS } catch (...) { for (typename __base::__map_pointer __i = __buf.begin(); __i != __buf.end(); ++__i) __alloc_traits::deallocate(__a, *__i, __base::__block_size); throw; } #endif for (; __front_capacity > 0; --__front_capacity) { __buf.push_back(__base::__map_.front()); __base::__map_.pop_front(); } for (typename __base::__map_pointer __i = __base::__map_.end(); __i != __base::__map_.begin();) __buf.push_front(*--__i); _STD::swap(__base::__map_.__first_, __buf.__first_); _STD::swap(__base::__map_.__begin_, __buf.__begin_); _STD::swap(__base::__map_.__end_, __buf.__end_); _STD::swap(__base::__map_.__end_cap(), __buf.__end_cap()); __base::__start_ -= __ds; } } template void deque<_Tp, _Allocator>::pop_front() { allocator_type& __a = __base::__alloc(); __alloc_traits::destroy(__a, *(__base::__map_.begin() + __base::__start_ / __base::__block_size) + __base::__start_ % __base::__block_size); --__base::size(); if (++__base::__start_ >= 2 * __base::__block_size) { __alloc_traits::deallocate(__a, __base::__map_.front(), __base::__block_size); __base::__map_.pop_front(); __base::__start_ -= __base::__block_size; } } template void deque<_Tp, _Allocator>::pop_back() { allocator_type& __a = __base::__alloc(); size_type __p = __base::size() + __base::__start_ - 1; __alloc_traits::destroy(__a, *(__base::__map_.begin() + __p / __base::__block_size) + __p % __base::__block_size); --__base::size(); if (__back_spare() >= 2 * __base::__block_size) { __alloc_traits::deallocate(__a, __base::__map_.back(), __base::__block_size); __base::__map_.pop_back(); } } // move assign [__f, __l) to [__r, __r + (__l-__f)). // If __vt points into [__f, __l), then subtract (__f - __r) from __vt. template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::__move_and_check(iterator __f, iterator __l, iterator __r, const_pointer& __vt) { // as if // for (; __f != __l; ++__f, ++__r) // *__r = _STD::move(*__f); difference_type __n = __l - __f; while (__n > 0) { pointer __fb = __f.__ptr_; pointer __fe = *__f.__m_iter_ + __base::__block_size; difference_type __bs = __fe - __fb; if (__bs > __n) { __bs = __n; __fe = __fb + __bs; } if (__fb <= __vt && __vt < __fe) __vt = (const_iterator(__f.__m_iter_, __vt) -= __f - __r).__ptr_; __r = _STD::move(__fb, __fe, __r); __n -= __bs; __f += __bs; } return __r; } // move assign [__f, __l) to [__r - (__l-__f), __r) backwards. // If __vt points into [__f, __l), then add (__r - __l) to __vt. template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::__move_backward_and_check(iterator __f, iterator __l, iterator __r, const_pointer& __vt) { // as if // while (__f != __l) // *--__r = _STD::move(*--__l); difference_type __n = __l - __f; while (__n > 0) { --__l; pointer __lb = *__l.__m_iter_; pointer __le = __l.__ptr_ + 1; difference_type __bs = __le - __lb; if (__bs > __n) { __bs = __n; __lb = __le - __bs; } if (__lb <= __vt && __vt < __le) __vt = (const_iterator(__l.__m_iter_, __vt) += __r - __l - 1).__ptr_; __r = _STD::move_backward(__lb, __le, __r); __n -= __bs; __l -= __bs - 1; } return __r; } // move construct [__f, __l) to [__r, __r + (__l-__f)). // If __vt points into [__f, __l), then add (__r - __f) to __vt. template void deque<_Tp, _Allocator>::__move_construct_and_check(iterator __f, iterator __l, iterator __r, const_pointer& __vt) { allocator_type& __a = __base::__alloc(); // as if // for (; __f != __l; ++__r, ++__f, ++__base::size()) // __alloc_traits::construct(__a, addressof(*__r), _STD::move(*__f)); difference_type __n = __l - __f; while (__n > 0) { pointer __fb = __f.__ptr_; pointer __fe = *__f.__m_iter_ + __base::__block_size; difference_type __bs = __fe - __fb; if (__bs > __n) { __bs = __n; __fe = __fb + __bs; } if (__fb <= __vt && __vt < __fe) __vt = (const_iterator(__f.__m_iter_, __vt) += __r - __f).__ptr_; for (; __fb != __fe; ++__fb, ++__r, ++__base::size()) __alloc_traits::construct(__a, addressof(*__r), _STD::move(*__fb)); __n -= __bs; __f += __bs; } } // move construct [__f, __l) to [__r - (__l-__f), __r) backwards. // If __vt points into [__f, __l), then subtract (__l - __r) from __vt. template void deque<_Tp, _Allocator>::__move_construct_backward_and_check(iterator __f, iterator __l, iterator __r, const_pointer& __vt) { allocator_type& __a = __base::__alloc(); // as if // for (iterator __j = __l; __j != __f;) // { // __alloc_traitsconstruct(__a, addressof(*--__r), _STD::move(*--__j)); // --__base::__start_; // ++__base::size(); // } difference_type __n = __l - __f; while (__n > 0) { --__l; pointer __lb = *__l.__m_iter_; pointer __le = __l.__ptr_ + 1; difference_type __bs = __le - __lb; if (__bs > __n) { __bs = __n; __lb = __le - __bs; } if (__lb <= __vt && __vt < __le) __vt = (const_iterator(__l.__m_iter_, __vt) -= __l - __r + 1).__ptr_; while (__le != __lb) { __alloc_traits::construct(__a, addressof(*--__r), _STD::move(*--__le)); --__base::__start_; ++__base::size(); } __n -= __bs; __l -= __bs - 1; } } template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::erase(const_iterator __f) { difference_type __n = 1; iterator __b = __base::begin(); difference_type __pos = __f - __b; iterator __p = __b + __pos; allocator_type& __a = __base::__alloc(); if (__pos < (__base::size() - 1) / 2) { // erase from front _STD::move_backward(__b, __p, next(__p)); __alloc_traits::destroy(__a, addressof(*__b)); --__base::size(); ++__base::__start_; if (__front_spare() >= 2 * __base::__block_size) { __alloc_traits::deallocate(__a, __base::__map_.front(), __base::__block_size); __base::__map_.pop_front(); __base::__start_ -= __base::__block_size; } } else { // erase from back iterator __i = _STD::move(next(__p), __base::end(), __p); __alloc_traits::destroy(__a, addressof(*__i)); --__base::size(); if (__back_spare() >= 2 * __base::__block_size) { __alloc_traits::deallocate(__a, __base::__map_.back(), __base::__block_size); __base::__map_.pop_back(); } } return __base::begin() + __pos; } template typename deque<_Tp, _Allocator>::iterator deque<_Tp, _Allocator>::erase(const_iterator __f, const_iterator __l) { difference_type __n = __l - __f; iterator __b = __base::begin(); difference_type __pos = __f - __b; iterator __p = __b + __pos; if (__n > 0) { allocator_type& __a = __base::__alloc(); if (__pos < (__base::size() - __n) / 2) { // erase from front iterator __i = _STD::move_backward(__b, __p, __p + __n); for (; __b != __i; ++__b) __alloc_traits::destroy(__a, addressof(*__b)); __base::size() -= __n; __base::__start_ += __n; while (__front_spare() >= 2 * __base::__block_size) { __alloc_traits::deallocate(__a, __base::__map_.front(), __base::__block_size); __base::__map_.pop_front(); __base::__start_ -= __base::__block_size; } } else { // erase from back iterator __i = _STD::move(__p + __n, __base::end(), __p); for (iterator __e = __base::end(); __i != __e; ++__i) __alloc_traits::destroy(__a, addressof(*__i)); __base::size() -= __n; while (__back_spare() >= 2 * __base::__block_size) { __alloc_traits::deallocate(__a, __base::__map_.back(), __base::__block_size); __base::__map_.pop_back(); } } } return __base::begin() + __pos; } template void deque<_Tp, _Allocator>::__erase_to_end(const_iterator __f) { iterator __e = __base::end(); difference_type __n = __e - __f; if (__n > 0) { allocator_type& __a = __base::__alloc(); iterator __b = __base::begin(); difference_type __pos = __f - __b; for (iterator __p = __b + __pos; __p != __e; ++__p) __alloc_traits::destroy(__a, addressof(*__p)); __base::size() -= __n; while (__back_spare() >= 2 * __base::__block_size) { __alloc_traits::deallocate(__a, __base::__map_.back(), __base::__block_size); __base::__map_.pop_back(); } } } template inline void deque<_Tp, _Allocator>::swap(deque& __c) { __base::swap(__c); } template inline void deque<_Tp, _Allocator>::clear() { __base::clear(); } template _LIBCPP_INLINE_VISIBILITY inline bool operator==(const deque<_Tp, _Allocator>& __x, const deque<_Tp, _Allocator>& __y) { const typename deque<_Tp, _Allocator>::size_type __sz = __x.size(); return __sz == __y.size() && _STD::equal(__x.begin(), __x.end(), __y.begin()); } template _LIBCPP_INLINE_VISIBILITY inline bool operator!=(const deque<_Tp, _Allocator>& __x, const deque<_Tp, _Allocator>& __y) { return !(__x == __y); } template _LIBCPP_INLINE_VISIBILITY inline bool operator< (const deque<_Tp, _Allocator>& __x, const deque<_Tp, _Allocator>& __y) { return _STD::lexicographical_compare(__x.begin(), __x.end(), __y.begin(), __y.end()); } template _LIBCPP_INLINE_VISIBILITY inline bool operator> (const deque<_Tp, _Allocator>& __x, const deque<_Tp, _Allocator>& __y) { return __y < __x; } template _LIBCPP_INLINE_VISIBILITY inline bool operator>=(const deque<_Tp, _Allocator>& __x, const deque<_Tp, _Allocator>& __y) { return !(__x < __y); } template _LIBCPP_INLINE_VISIBILITY inline bool operator<=(const deque<_Tp, _Allocator>& __x, const deque<_Tp, _Allocator>& __y) { return !(__y < __x); } template _LIBCPP_INLINE_VISIBILITY inline void swap(deque<_Tp, _Allocator>& __x, deque<_Tp, _Allocator>& __y) { __x.swap(__y); } _LIBCPP_END_NAMESPACE_STD #endif // _LIBCPP_DEQUE