stack 、 queue的语法使用及底层实现以及deque的介绍【C++】

news2024/11/20 14:30:27

文章目录

  • stack的使用
  • queue的使用
  • 适配器
  • queue的模拟实现
  • stack的模拟实现
  • deque

stack的使用

stack是一种容器适配器,具有后进先出,只能从容器的一端进行元素的插入与提取操作
在这里插入图片描述

#include <iostream>
#include <vector>
#include <stack>
using namespace std;

int main()
{
	stack<int, vector<int>> st;
	st.push(1);
	st.push(2);
	st.push(3);
	st.push(4);
	cout << st.size() << endl; //4
	while (!st.empty())
	{
		cout << st.top() << " ";
		st.pop();
	}
	cout << endl; //4 3 2 1
	return 0;
}

queue的使用

队列是一种容器适配器,具有先进先出,只能从容器的一端插入元素,另一端提取元素
在这里插入图片描述

#include <iostream>
#include <list>
#include <queue>
using namespace std;

int main()
{
	queue<int, list<int>> q;
	q.push(1);
	q.push(2);
	q.push(3);
	q.push(4);
	cout << q.size() << endl; //4
	while (!q.empty())
	{
		cout << q.front() << " ";
		q.pop();
	}
	cout << endl; //1 2 3 4
	return 0;
}

适配器

stack和queue在STL中并没有将其划分在容器的行列,而是称为容器适配器
因为stack和queue对其他容器的接口进行了包装,STL中stack和queue默认使用deque容器。在这里插入图片描述

queue的模拟实现

核心接口

front:获取对列头部(第一个元素)
back:获取队列尾部(最后一个元素)
size:获取队列中的元素个数
pop:删除队列头部元素
push:队列尾部插入元素
empty:判空

namespace cxq
{
	template<class T ,class Container = deque<T> >
	class queue
	{
	public:
		void push(const T & x)
		{
			_con.push_back(x);
		}
		void pop()
		{
			_con.pop_front();
		}
		T&	front()
		{
			return _con.front();
		}
		T& back()
		{
			return _con.back();
		}
		size_t size()
		{
			return _con.size();
		}
		bool empty()
		{
			return _con.empty();
		}
	private:

		Container _con;
	};
	void test_queue1()
	{
		queue<int, list<int> > q ;
		q.push(1);
		q.push(2);
		q.push(3);
		q.push(4);
		while (!q.empty())
		{
			cout << q.front() << " ";
			q.pop();
		}
		cout << endl;

	}
}

stack的模拟实现

核心接口

top:获取尾部元素
size:获取栈中的元素个数
pop:删除栈顶元素
push:栈顶插入元素
empty:判空

namespace cxq
{
	template<class T  , class Container = deque<T> >
	class Stack
	{
	public:
		void push( const T & x )
		{
			_con.push_back(x);
		}
	 	T &  top()
		{
			return _con.back();
		}
		void pop()
		{
			_con.pop_back();
		}
		size_t size()
		{
			return _con.size();
		}
		bool empty()
		{
			return _con.empty();
		}

	private:
		Container _con;
	};
	void test_Stack1()
	{
		stack<int> st1;
		st1.push(1);
		st1.push(2);
		st1.push(3);
		st1.push(4);
		while (!st1.empty())
		{
			cout << st1.top() << " ";
			st1.pop();
		}
		cout << endl;
		stack<int ,list<int> > st2;
		st2.push(1);
		st2.push(2);
		st2.push(3);
		st2.push(4);
		while (!st2.empty())
		{
			cout << st2.top() << " ";
			st2.pop();
		}
		cout << endl;
	}
}

deque

deque(双端队列):是一种双开口的"连续"空间的数据结构,双开口的含义是:可以在头尾两端进行插入和删除操作,且时间复杂度为O(1),与vector比较,头插效率高,不需要搬移元素;与list比较,空间利用率比较高。

在这里插入图片描述

deque并不是真正连续的空间,而是由一段段连续的小空间拼接而成的,实际deque类似于一个动态的二维数组。
双端队列底层是一段假象的连续空间,实际是分段连续的,为了维护其“整体连续”以及随机访问的假象,落 在了deque的迭代器身上

在这里插入图片描述

deque 与vector比较:
deque的头插和头删时,不需要挪动元素,效率特别高,而且在扩容时,也不需要移动大量的元素。
deque与list比较:
其底层是连续空间,空间利用率比较高,不需要存储额外字段。

但是,deque不适合遍历
因为在遍历时,deque的迭代器要频繁的去检测其是否移动到某段小空间的边界,导致效率低下,而序列式场景中,可能需要经常遍历,因此在实际中,需要线性结构时,大多数情况下优先考虑vector和list,deque的应用并不多,而目前能看到的一个应用就是,STL用其作为stack和queue的底层数据结构。

为什么STL选择deque作为stack和queue的底层默认容器

stack是一种后进先出的数据结构,因此只要具有push_back()和pop_back()操作的结构,都可以作为stack的底层容器,比如vector和list都可以。
queue是先进先出的数据结构,只要具有 push_back和pop_front操作的结构,都可以作为queue的底层容器,比如list。但是STL中对stack和 queue默认选择deque作为其底层容器,主要是因为:
1、stack和queue不需要遍历(因此stack和queue没有迭代器),只需要在固定的一端或者两端进行操作。
2、在stack中元素增长时,deque比vector的效率高(扩容时不需要搬移大量数据);queue中的元素增长时,deque不仅效率高,而且内存使用率高。
结合了deque的优点,而完美的避开了其缺陷。

如果想要对deque有比较深入的了解,可以阅读STL库的源码

// Deque implementation -*- C++ -*-

// Copyright (C) 2001-2018 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 3, 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.

// Under Section 7 of GPL version 3, you are granted additional
// permissions described in the GCC Runtime Library Exception, version
// 3.1, as published by the Free Software Foundation.

// You should have received a copy of the GNU General Public License and
// a copy of the GCC Runtime Library Exception along with this program;
// see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
// <http://www.gnu.org/licenses/>.

/*
 *
 * Copyright (c) 1994
 * Hewlett-Packard Company
 *
 * Permission to use, copy, modify, distribute and sell this software
 * and its documentation for any purpose is hereby granted without fee,
 * provided that the above copyright notice appear in all copies and
 * that both that copyright notice and this permission notice appear
 * in supporting documentation.  Hewlett-Packard Company makes no
 * representations about the suitability of this software for any
 * purpose.  It is provided "as is" without express or implied warranty.
 *
 *
 * Copyright (c) 1997
 * Silicon Graphics Computer Systems, Inc.
 *
 * Permission to use, copy, modify, distribute and sell this software
 * and its documentation for any purpose is hereby granted without fee,
 * provided that the above copyright notice appear in all copies and
 * that both that copyright notice and this permission notice appear
 * in supporting documentation.  Silicon Graphics makes no
 * representations about the suitability of this software for any
 * purpose.  It is provided "as is" without express or implied warranty.
 */

/** @file bits/stl_deque.h
 *  This is an internal header file, included by other library headers.
 *  Do not attempt to use it directly. @headername{deque}
 */

#ifndef _STL_DEQUE_H
#define _STL_DEQUE_H 1

#include <bits/concept_check.h>
#include <bits/stl_iterator_base_types.h>
#include <bits/stl_iterator_base_funcs.h>
#if __cplusplus >= 201103L
#include <initializer_list>
#endif

#include <debug/assertions.h>

namespace std _GLIBCXX_VISIBILITY(default)
{
_GLIBCXX_BEGIN_NAMESPACE_VERSION
_GLIBCXX_BEGIN_NAMESPACE_CONTAINER

  /**
   *  @brief This function controls the size of memory nodes.
   *  @param  __size  The size of an element.
   *  @return   The number (not byte size) of elements per node.
   *
   *  This function started off as a compiler kludge from SGI, but
   *  seems to be a useful wrapper around a repeated constant
   *  expression.  The @b 512 is tunable (and no other code needs to
   *  change), but no investigation has been done since inheriting the
   *  SGI code.  Touch _GLIBCXX_DEQUE_BUF_SIZE only if you know what
   *  you are doing, however: changing it breaks the binary
   *  compatibility!!
  */

#ifndef _GLIBCXX_DEQUE_BUF_SIZE
#define _GLIBCXX_DEQUE_BUF_SIZE 512
#endif

  _GLIBCXX_CONSTEXPR inline size_t
  __deque_buf_size(size_t __size)
  { return (__size < _GLIBCXX_DEQUE_BUF_SIZE
	    ? size_t(_GLIBCXX_DEQUE_BUF_SIZE / __size) : size_t(1)); }


  /**
   *  @brief A deque::iterator.
   *
   *  Quite a bit of intelligence here.  Much of the functionality of
   *  deque is actually passed off to this class.  A deque holds two
   *  of these internally, marking its valid range.  Access to
   *  elements is done as offsets of either of those two, relying on
   *  operator overloading in this class.
   *
   *  All the functions are op overloads except for _M_set_node.
  */
  template<typename _Tp, typename _Ref, typename _Ptr>
    struct _Deque_iterator
    {
#if __cplusplus < 201103L
      typedef _Deque_iterator<_Tp, _Tp&, _Tp*>	     iterator;
      typedef _Deque_iterator<_Tp, const _Tp&, const _Tp*> const_iterator;
      typedef _Tp*					 _Elt_pointer;
      typedef _Tp**					_Map_pointer;
#else
    private:
      template<typename _Up>
	using __ptr_to = typename pointer_traits<_Ptr>::template rebind<_Up>;
      template<typename _CvTp>
	using __iter = _Deque_iterator<_Tp, _CvTp&, __ptr_to<_CvTp>>;
    public:
      typedef __iter<_Tp>		iterator;
      typedef __iter<const _Tp>		const_iterator;
      typedef __ptr_to<_Tp>		_Elt_pointer;
      typedef __ptr_to<_Elt_pointer>	_Map_pointer;
#endif

      static size_t _S_buffer_size() _GLIBCXX_NOEXCEPT
      { return __deque_buf_size(sizeof(_Tp)); }

      typedef std::random_access_iterator_tag	iterator_category;
      typedef _Tp				value_type;
      typedef _Ptr				pointer;
      typedef _Ref				reference;
      typedef size_t				size_type;
      typedef ptrdiff_t				difference_type;
      typedef _Deque_iterator			_Self;

      _Elt_pointer _M_cur;
      _Elt_pointer _M_first;
      _Elt_pointer _M_last;
      _Map_pointer _M_node;

      _Deque_iterator(_Elt_pointer __x, _Map_pointer __y) _GLIBCXX_NOEXCEPT
      : _M_cur(__x), _M_first(*__y),
	_M_last(*__y + _S_buffer_size()), _M_node(__y) { }

      _Deque_iterator() _GLIBCXX_NOEXCEPT
      : _M_cur(), _M_first(), _M_last(), _M_node() { }

      _Deque_iterator(const iterator& __x) _GLIBCXX_NOEXCEPT
      : _M_cur(__x._M_cur), _M_first(__x._M_first),
	_M_last(__x._M_last), _M_node(__x._M_node) { }

      iterator
      _M_const_cast() const _GLIBCXX_NOEXCEPT
      { return iterator(_M_cur, _M_node); }

      reference
      operator*() const _GLIBCXX_NOEXCEPT
      { return *_M_cur; }

      pointer
      operator->() const _GLIBCXX_NOEXCEPT
      { return _M_cur; }

      _Self&
      operator++() _GLIBCXX_NOEXCEPT
      {
	++_M_cur;
	if (_M_cur == _M_last)
	  {
	    _M_set_node(_M_node + 1);
	    _M_cur = _M_first;
	  }
	return *this;
      }

      _Self
      operator++(int) _GLIBCXX_NOEXCEPT
      {
	_Self __tmp = *this;
	++*this;
	return __tmp;
      }

      _Self&
      operator--() _GLIBCXX_NOEXCEPT
      {
	if (_M_cur == _M_first)
	  {
	    _M_set_node(_M_node - 1);
	    _M_cur = _M_last;
	  }
	--_M_cur;
	return *this;
      }

      _Self
      operator--(int) _GLIBCXX_NOEXCEPT
      {
	_Self __tmp = *this;
	--*this;
	return __tmp;
      }

      _Self&
      operator+=(difference_type __n) _GLIBCXX_NOEXCEPT
      {
	const difference_type __offset = __n + (_M_cur - _M_first);
	if (__offset >= 0 && __offset < difference_type(_S_buffer_size()))
	  _M_cur += __n;
	else
	  {
	    const difference_type __node_offset =
	      __offset > 0 ? __offset / difference_type(_S_buffer_size())
			   : -difference_type((-__offset - 1)
					      / _S_buffer_size()) - 1;
	    _M_set_node(_M_node + __node_offset);
	    _M_cur = _M_first + (__offset - __node_offset
				 * difference_type(_S_buffer_size()));
	  }
	return *this;
      }

      _Self
      operator+(difference_type __n) const _GLIBCXX_NOEXCEPT
      {
	_Self __tmp = *this;
	return __tmp += __n;
      }

      _Self&
      operator-=(difference_type __n) _GLIBCXX_NOEXCEPT
      { return *this += -__n; }

      _Self
      operator-(difference_type __n) const _GLIBCXX_NOEXCEPT
      {
	_Self __tmp = *this;
	return __tmp -= __n;
      }

      reference
      operator[](difference_type __n) const _GLIBCXX_NOEXCEPT
      { return *(*this + __n); }

      /**
       *  Prepares to traverse new_node.  Sets everything except
       *  _M_cur, which should therefore be set by the caller
       *  immediately afterwards, based on _M_first and _M_last.
       */
      void
      _M_set_node(_Map_pointer __new_node) _GLIBCXX_NOEXCEPT
      {
	_M_node = __new_node;
	_M_first = *__new_node;
	_M_last = _M_first + difference_type(_S_buffer_size());
      }
    };

  // Note: we also provide overloads whose operands are of the same type in
  // order to avoid ambiguous overload resolution when std::rel_ops operators
  // are in scope (for additional details, see libstdc++/3628)
  template<typename _Tp, typename _Ref, typename _Ptr>
    inline bool
    operator==(const _Deque_iterator<_Tp, _Ref, _Ptr>& __x,
	       const _Deque_iterator<_Tp, _Ref, _Ptr>& __y) _GLIBCXX_NOEXCEPT
    { return __x._M_cur == __y._M_cur; }

  template<typename _Tp, typename _RefL, typename _PtrL,
	   typename _RefR, typename _PtrR>
    inline bool
    operator==(const _Deque_iterator<_Tp, _RefL, _PtrL>& __x,
	       const _Deque_iterator<_Tp, _RefR, _PtrR>& __y) _GLIBCXX_NOEXCEPT
    { return __x._M_cur == __y._M_cur; }

  template<typename _Tp, typename _Ref, typename _Ptr>
    inline bool
    operator!=(const _Deque_iterator<_Tp, _Ref, _Ptr>& __x,
	       const _Deque_iterator<_Tp, _Ref, _Ptr>& __y) _GLIBCXX_NOEXCEPT
    { return !(__x == __y); }

  template<typename _Tp, typename _RefL, typename _PtrL,
	   typename _RefR, typename _PtrR>
    inline bool
    operator!=(const _Deque_iterator<_Tp, _RefL, _PtrL>& __x,
	       const _Deque_iterator<_Tp, _RefR, _PtrR>& __y) _GLIBCXX_NOEXCEPT
    { return !(__x == __y); }

  template<typename _Tp, typename _Ref, typename _Ptr>
    inline bool
    operator<(const _Deque_iterator<_Tp, _Ref, _Ptr>& __x,
	      const _Deque_iterator<_Tp, _Ref, _Ptr>& __y) _GLIBCXX_NOEXCEPT
    { return (__x._M_node == __y._M_node) ? (__x._M_cur < __y._M_cur)
					  : (__x._M_node < __y._M_node); }

  template<typename _Tp, typename _RefL, typename _PtrL,
	   typename _RefR, typename _PtrR>
    inline bool
    operator<(const _Deque_iterator<_Tp, _RefL, _PtrL>& __x,
	      const _Deque_iterator<_Tp, _RefR, _PtrR>& __y) _GLIBCXX_NOEXCEPT
    { return (__x._M_node == __y._M_node) ? (__x._M_cur < __y._M_cur)
					  : (__x._M_node < __y._M_node); }

  template<typename _Tp, typename _Ref, typename _Ptr>
    inline bool
    operator>(const _Deque_iterator<_Tp, _Ref, _Ptr>& __x,
	      const _Deque_iterator<_Tp, _Ref, _Ptr>& __y) _GLIBCXX_NOEXCEPT
    { return __y < __x; }

  template<typename _Tp, typename _RefL, typename _PtrL,
	   typename _RefR, typename _PtrR>
    inline bool
    operator>(const _Deque_iterator<_Tp, _RefL, _PtrL>& __x,
	      const _Deque_iterator<_Tp, _RefR, _PtrR>& __y) _GLIBCXX_NOEXCEPT
    { return __y < __x; }

  template<typename _Tp, typename _Ref, typename _Ptr>
    inline bool
    operator<=(const _Deque_iterator<_Tp, _Ref, _Ptr>& __x,
	       const _Deque_iterator<_Tp, _Ref, _Ptr>& __y) _GLIBCXX_NOEXCEPT
    { return !(__y < __x); }

  template<typename _Tp, typename _RefL, typename _PtrL,
	   typename _RefR, typename _PtrR>
    inline bool
    operator<=(const _Deque_iterator<_Tp, _RefL, _PtrL>& __x,
	       const _Deque_iterator<_Tp, _RefR, _PtrR>& __y) _GLIBCXX_NOEXCEPT
    { return !(__y < __x); }

  template<typename _Tp, typename _Ref, typename _Ptr>
    inline bool
    operator>=(const _Deque_iterator<_Tp, _Ref, _Ptr>& __x,
	       const _Deque_iterator<_Tp, _Ref, _Ptr>& __y) _GLIBCXX_NOEXCEPT
    { return !(__x < __y); }

  template<typename _Tp, typename _RefL, typename _PtrL,
	   typename _RefR, typename _PtrR>
    inline bool
    operator>=(const _Deque_iterator<_Tp, _RefL, _PtrL>& __x,
	       const _Deque_iterator<_Tp, _RefR, _PtrR>& __y) _GLIBCXX_NOEXCEPT
    { return !(__x < __y); }

  // _GLIBCXX_RESOLVE_LIB_DEFECTS
  // According to the resolution of DR179 not only the various comparison
  // operators but also operator- must accept mixed iterator/const_iterator
  // parameters.
  template<typename _Tp, typename _Ref, typename _Ptr>
    inline typename _Deque_iterator<_Tp, _Ref, _Ptr>::difference_type
    operator-(const _Deque_iterator<_Tp, _Ref, _Ptr>& __x,
	      const _Deque_iterator<_Tp, _Ref, _Ptr>& __y) _GLIBCXX_NOEXCEPT
    {
      return typename _Deque_iterator<_Tp, _Ref, _Ptr>::difference_type
	(_Deque_iterator<_Tp, _Ref, _Ptr>::_S_buffer_size())
	* (__x._M_node - __y._M_node - 1) + (__x._M_cur - __x._M_first)
	+ (__y._M_last - __y._M_cur);
    }

  template<typename _Tp, typename _RefL, typename _PtrL,
	   typename _RefR, typename _PtrR>
    inline typename _Deque_iterator<_Tp, _RefL, _PtrL>::difference_type
    operator-(const _Deque_iterator<_Tp, _RefL, _PtrL>& __x,
	      const _Deque_iterator<_Tp, _RefR, _PtrR>& __y) _GLIBCXX_NOEXCEPT
    {
      return typename _Deque_iterator<_Tp, _RefL, _PtrL>::difference_type
	(_Deque_iterator<_Tp, _RefL, _PtrL>::_S_buffer_size())
	* (__x._M_node - __y._M_node - 1) + (__x._M_cur - __x._M_first)
	+ (__y._M_last - __y._M_cur);
    }

  template<typename _Tp, typename _Ref, typename _Ptr>
    inline _Deque_iterator<_Tp, _Ref, _Ptr>
    operator+(ptrdiff_t __n, const _Deque_iterator<_Tp, _Ref, _Ptr>& __x)
    _GLIBCXX_NOEXCEPT
    { return __x + __n; }

  template<typename _Tp>
    void
    fill(const _Deque_iterator<_Tp, _Tp&, _Tp*>&,
	 const _Deque_iterator<_Tp, _Tp&, _Tp*>&, const _Tp&);

  template<typename _Tp>
    _Deque_iterator<_Tp, _Tp&, _Tp*>
    copy(_Deque_iterator<_Tp, const _Tp&, const _Tp*>,
	 _Deque_iterator<_Tp, const _Tp&, const _Tp*>,
	 _Deque_iterator<_Tp, _Tp&, _Tp*>);

  template<typename _Tp>
    inline _Deque_iterator<_Tp, _Tp&, _Tp*>
    copy(_Deque_iterator<_Tp, _Tp&, _Tp*> __first,
	 _Deque_iterator<_Tp, _Tp&, _Tp*> __last,
	 _Deque_iterator<_Tp, _Tp&, _Tp*> __result)
    { return std::copy(_Deque_iterator<_Tp, const _Tp&, const _Tp*>(__first),
		       _Deque_iterator<_Tp, const _Tp&, const _Tp*>(__last),
		       __result); }

  template<typename _Tp>
    _Deque_iterator<_Tp, _Tp&, _Tp*>
    copy_backward(_Deque_iterator<_Tp, const _Tp&, const _Tp*>,
		  _Deque_iterator<_Tp, const _Tp&, const _Tp*>,
		  _Deque_iterator<_Tp, _Tp&, _Tp*>);

  template<typename _Tp>
    inline _Deque_iterator<_Tp, _Tp&, _Tp*>
    copy_backward(_Deque_iterator<_Tp, _Tp&, _Tp*> __first,
		  _Deque_iterator<_Tp, _Tp&, _Tp*> __last,
		  _Deque_iterator<_Tp, _Tp&, _Tp*> __result)
    { return std::copy_backward(_Deque_iterator<_Tp,
				const _Tp&, const _Tp*>(__first),
				_Deque_iterator<_Tp,
				const _Tp&, const _Tp*>(__last),
				__result); }

#if __cplusplus >= 201103L
  template<typename _Tp>
    _Deque_iterator<_Tp, _Tp&, _Tp*>
    move(_Deque_iterator<_Tp, const _Tp&, const _Tp*>,
	 _Deque_iterator<_Tp, const _Tp&, const _Tp*>,
	 _Deque_iterator<_Tp, _Tp&, _Tp*>);

  template<typename _Tp>
    inline _Deque_iterator<_Tp, _Tp&, _Tp*>
    move(_Deque_iterator<_Tp, _Tp&, _Tp*> __first,
	 _Deque_iterator<_Tp, _Tp&, _Tp*> __last,
	 _Deque_iterator<_Tp, _Tp&, _Tp*> __result)
    { return std::move(_Deque_iterator<_Tp, const _Tp&, const _Tp*>(__first),
		       _Deque_iterator<_Tp, const _Tp&, const _Tp*>(__last),
		       __result); }

  template<typename _Tp>
    _Deque_iterator<_Tp, _Tp&, _Tp*>
    move_backward(_Deque_iterator<_Tp, const _Tp&, const _Tp*>,
		  _Deque_iterator<_Tp, const _Tp&, const _Tp*>,
		  _Deque_iterator<_Tp, _Tp&, _Tp*>);

  template<typename _Tp>
    inline _Deque_iterator<_Tp, _Tp&, _Tp*>
    move_backward(_Deque_iterator<_Tp, _Tp&, _Tp*> __first,
		  _Deque_iterator<_Tp, _Tp&, _Tp*> __last,
		  _Deque_iterator<_Tp, _Tp&, _Tp*> __result)
    { return std::move_backward(_Deque_iterator<_Tp,
				const _Tp&, const _Tp*>(__first),
				_Deque_iterator<_Tp,
				const _Tp&, const _Tp*>(__last),
				__result); }
#endif

  /**
   *  Deque base class.  This class provides the unified face for %deque's
   *  allocation.  This class's constructor and destructor allocate and
   *  deallocate (but do not initialize) storage.  This makes %exception
   *  safety easier.
   *
   *  Nothing in this class ever constructs or destroys an actual Tp element.
   *  (Deque handles that itself.)  Only/All memory management is performed
   *  here.
  */
  template<typename _Tp, typename _Alloc>
    class _Deque_base
    {
    protected:
      typedef typename __gnu_cxx::__alloc_traits<_Alloc>::template
	rebind<_Tp>::other _Tp_alloc_type;
      typedef __gnu_cxx::__alloc_traits<_Tp_alloc_type>	 _Alloc_traits;

#if __cplusplus < 201103L
      typedef _Tp*					_Ptr;
      typedef const _Tp*				_Ptr_const;
#else
      typedef typename _Alloc_traits::pointer		_Ptr;
      typedef typename _Alloc_traits::const_pointer	_Ptr_const;
#endif

      typedef typename _Alloc_traits::template rebind<_Ptr>::other
	_Map_alloc_type;
      typedef __gnu_cxx::__alloc_traits<_Map_alloc_type> _Map_alloc_traits;

    public:
      typedef _Alloc		  allocator_type;
      typedef typename _Alloc_traits::size_type size_type;

      allocator_type
      get_allocator() const _GLIBCXX_NOEXCEPT
      { return allocator_type(_M_get_Tp_allocator()); }

      typedef _Deque_iterator<_Tp, _Tp&, _Ptr>	  iterator;
      typedef _Deque_iterator<_Tp, const _Tp&, _Ptr_const>   const_iterator;

      _Deque_base()
      : _M_impl()
      { _M_initialize_map(0); }

      _Deque_base(size_t __num_elements)
      : _M_impl()
      { _M_initialize_map(__num_elements); }

      _Deque_base(const allocator_type& __a, size_t __num_elements)
      : _M_impl(__a)
      { _M_initialize_map(__num_elements); }

      _Deque_base(const allocator_type& __a)
      : _M_impl(__a)
      { /* Caller must initialize map. */ }

#if __cplusplus >= 201103L
      _Deque_base(_Deque_base&& __x, false_type)
      : _M_impl(__x._M_move_impl())
      { }

      _Deque_base(_Deque_base&& __x, true_type)
      : _M_impl(std::move(__x._M_get_Tp_allocator()))
      {
	_M_initialize_map(0);
	if (__x._M_impl._M_map)
	  this->_M_impl._M_swap_data(__x._M_impl);
      }

      _Deque_base(_Deque_base&& __x)
      : _Deque_base(std::move(__x), typename _Alloc_traits::is_always_equal{})
      { }

      _Deque_base(_Deque_base&& __x, const allocator_type& __a, size_type __n)
      : _M_impl(__a)
      {
	if (__x.get_allocator() == __a)
	  {
	    if (__x._M_impl._M_map)
	      {
		_M_initialize_map(0);
		this->_M_impl._M_swap_data(__x._M_impl);
	      }
	  }
	else
	  {
	    _M_initialize_map(__n);
	  }
      }
#endif

      ~_Deque_base() _GLIBCXX_NOEXCEPT;

    protected:
      typedef typename iterator::_Map_pointer _Map_pointer;

      //This struct encapsulates the implementation of the std::deque
      //standard container and at the same time makes use of the EBO
      //for empty allocators.
      struct _Deque_impl
      : public _Tp_alloc_type
      {
	_Map_pointer _M_map;
	size_t _M_map_size;
	iterator _M_start;
	iterator _M_finish;

	_Deque_impl()
	: _Tp_alloc_type(), _M_map(), _M_map_size(0),
	  _M_start(), _M_finish()
	{ }

	_Deque_impl(const _Tp_alloc_type& __a) _GLIBCXX_NOEXCEPT
	: _Tp_alloc_type(__a), _M_map(), _M_map_size(0),
	  _M_start(), _M_finish()
	{ }

#if __cplusplus >= 201103L
	_Deque_impl(_Deque_impl&&) = default;

	_Deque_impl(_Tp_alloc_type&& __a) noexcept
	: _Tp_alloc_type(std::move(__a)), _M_map(), _M_map_size(0),
	  _M_start(), _M_finish()
	{ }
#endif

	void _M_swap_data(_Deque_impl& __x) _GLIBCXX_NOEXCEPT
	{
	  using std::swap;
	  swap(this->_M_start, __x._M_start);
	  swap(this->_M_finish, __x._M_finish);
	  swap(this->_M_map, __x._M_map);
	  swap(this->_M_map_size, __x._M_map_size);
	}
      };

      _Tp_alloc_type&
      _M_get_Tp_allocator() _GLIBCXX_NOEXCEPT
      { return *static_cast<_Tp_alloc_type*>(&this->_M_impl); }

      const _Tp_alloc_type&
      _M_get_Tp_allocator() const _GLIBCXX_NOEXCEPT
      { return *static_cast<const _Tp_alloc_type*>(&this->_M_impl); }

      _Map_alloc_type
      _M_get_map_allocator() const _GLIBCXX_NOEXCEPT
      { return _Map_alloc_type(_M_get_Tp_allocator()); }

      _Ptr
      _M_allocate_node()
      {
	typedef __gnu_cxx::__alloc_traits<_Tp_alloc_type> _Traits;
	return _Traits::allocate(_M_impl, __deque_buf_size(sizeof(_Tp)));
      }

      void
      _M_deallocate_node(_Ptr __p) _GLIBCXX_NOEXCEPT
      {
	typedef __gnu_cxx::__alloc_traits<_Tp_alloc_type> _Traits;
	_Traits::deallocate(_M_impl, __p, __deque_buf_size(sizeof(_Tp)));
      }

      _Map_pointer
      _M_allocate_map(size_t __n)
      {
	_Map_alloc_type __map_alloc = _M_get_map_allocator();
	return _Map_alloc_traits::allocate(__map_alloc, __n);
      }

      void
      _M_deallocate_map(_Map_pointer __p, size_t __n) _GLIBCXX_NOEXCEPT
      {
	_Map_alloc_type __map_alloc = _M_get_map_allocator();
	_Map_alloc_traits::deallocate(__map_alloc, __p, __n);
      }

    protected:
      void _M_initialize_map(size_t);
      void _M_create_nodes(_Map_pointer __nstart, _Map_pointer __nfinish);
      void _M_destroy_nodes(_Map_pointer __nstart,
			    _Map_pointer __nfinish) _GLIBCXX_NOEXCEPT;
      enum { _S_initial_map_size = 8 };

      _Deque_impl _M_impl;

#if __cplusplus >= 201103L
    private:
      _Deque_impl
      _M_move_impl()
      {
	if (!_M_impl._M_map)
	  return std::move(_M_impl);

	// Create a copy of the current allocator.
	_Tp_alloc_type __alloc{_M_get_Tp_allocator()};
	// Put that copy in a moved-from state.
	_Tp_alloc_type __sink __attribute((__unused__)) {std::move(__alloc)};
	// Create an empty map that allocates using the moved-from allocator.
	_Deque_base __empty{__alloc};
	__empty._M_initialize_map(0);
	// Now safe to modify current allocator and perform non-throwing swaps.
	_Deque_impl __ret{std::move(_M_get_Tp_allocator())};
	_M_impl._M_swap_data(__ret);
	_M_impl._M_swap_data(__empty._M_impl);
	return __ret;
      }
#endif
    };

  template<typename _Tp, typename _Alloc>
    _Deque_base<_Tp, _Alloc>::
    ~_Deque_base() _GLIBCXX_NOEXCEPT
    {
      if (this->_M_impl._M_map)
	{
	  _M_destroy_nodes(this->_M_impl._M_start._M_node,
			   this->_M_impl._M_finish._M_node + 1);
	  _M_deallocate_map(this->_M_impl._M_map, this->_M_impl._M_map_size);
	}
    }

  /**
   *  @brief Layout storage.
   *  @param  __num_elements  The count of T's for which to allocate space
   *                          at first.
   *  @return   Nothing.
   *
   *  The initial underlying memory layout is a bit complicated...
  */
  template<typename _Tp, typename _Alloc>
    void
    _Deque_base<_Tp, _Alloc>::
    _M_initialize_map(size_t __num_elements)
    {
      const size_t __num_nodes = (__num_elements/ __deque_buf_size(sizeof(_Tp))
				  + 1);

      this->_M_impl._M_map_size = std::max((size_t) _S_initial_map_size,
					   size_t(__num_nodes + 2));
      this->_M_impl._M_map = _M_allocate_map(this->_M_impl._M_map_size);

      // For "small" maps (needing less than _M_map_size nodes), allocation
      // starts in the middle elements and grows outwards.  So nstart may be
      // the beginning of _M_map, but for small maps it may be as far in as
      // _M_map+3.

      _Map_pointer __nstart = (this->_M_impl._M_map
			       + (this->_M_impl._M_map_size - __num_nodes) / 2);
      _Map_pointer __nfinish = __nstart + __num_nodes;

      __try
	{ _M_create_nodes(__nstart, __nfinish); }
      __catch(...)
	{
	  _M_deallocate_map(this->_M_impl._M_map, this->_M_impl._M_map_size);
	  this->_M_impl._M_map = _Map_pointer();
	  this->_M_impl._M_map_size = 0;
	  __throw_exception_again;
	}

      this->_M_impl._M_start._M_set_node(__nstart);
      this->_M_impl._M_finish._M_set_node(__nfinish - 1);
      this->_M_impl._M_start._M_cur = _M_impl._M_start._M_first;
      this->_M_impl._M_finish._M_cur = (this->_M_impl._M_finish._M_first
					+ __num_elements
					% __deque_buf_size(sizeof(_Tp)));
    }

  template<typename _Tp, typename _Alloc>
    void
    _Deque_base<_Tp, _Alloc>::
    _M_create_nodes(_Map_pointer __nstart, _Map_pointer __nfinish)
    {
      _Map_pointer __cur;
      __try
	{
	  for (__cur = __nstart; __cur < __nfinish; ++__cur)
	    *__cur = this->_M_allocate_node();
	}
      __catch(...)
	{
	  _M_destroy_nodes(__nstart, __cur);
	  __throw_exception_again;
	}
    }

  template<typename _Tp, typename _Alloc>
    void
    _Deque_base<_Tp, _Alloc>::
    _M_destroy_nodes(_Map_pointer __nstart,
		     _Map_pointer __nfinish) _GLIBCXX_NOEXCEPT
    {
      for (_Map_pointer __n = __nstart; __n < __nfinish; ++__n)
	_M_deallocate_node(*__n);
    }

  /**
   *  @brief  A standard container using fixed-size memory allocation and
   *  constant-time manipulation of elements at either end.
   *
   *  @ingroup sequences
   *
   *  @tparam _Tp  Type of element.
   *  @tparam _Alloc  Allocator type, defaults to allocator<_Tp>.
   *
   *  Meets the requirements of a <a href="tables.html#65">container</a>, a
   *  <a href="tables.html#66">reversible container</a>, and a
   *  <a href="tables.html#67">sequence</a>, including the
   *  <a href="tables.html#68">optional sequence requirements</a>.
   *
   *  In previous HP/SGI versions of deque, there was an extra template
   *  parameter so users could control the node size.  This extension turned
   *  out to violate the C++ standard (it can be detected using template
   *  template parameters), and it was removed.
   *
   *  Here's how a deque<Tp> manages memory.  Each deque has 4 members:
   *
   *  - Tp**        _M_map
   *  - size_t      _M_map_size
   *  - iterator    _M_start, _M_finish
   *
   *  map_size is at least 8.  %map is an array of map_size
   *  pointers-to-@a nodes.  (The name %map has nothing to do with the
   *  std::map class, and @b nodes should not be confused with
   *  std::list's usage of @a node.)
   *
   *  A @a node has no specific type name as such, but it is referred
   *  to as @a node in this file.  It is a simple array-of-Tp.  If Tp
   *  is very large, there will be one Tp element per node (i.e., an
   *  @a array of one).  For non-huge Tp's, node size is inversely
   *  related to Tp size: the larger the Tp, the fewer Tp's will fit
   *  in a node.  The goal here is to keep the total size of a node
   *  relatively small and constant over different Tp's, to improve
   *  allocator efficiency.
   *
   *  Not every pointer in the %map array will point to a node.  If
   *  the initial number of elements in the deque is small, the
   *  /middle/ %map pointers will be valid, and the ones at the edges
   *  will be unused.  This same situation will arise as the %map
   *  grows: available %map pointers, if any, will be on the ends.  As
   *  new nodes are created, only a subset of the %map's pointers need
   *  to be copied @a outward.
   *
   *  Class invariants:
   * - For any nonsingular iterator i:
   *    - i.node points to a member of the %map array.  (Yes, you read that
   *      correctly:  i.node does not actually point to a node.)  The member of
   *      the %map array is what actually points to the node.
   *    - i.first == *(i.node)    (This points to the node (first Tp element).)
   *    - i.last  == i.first + node_size
   *    - i.cur is a pointer in the range [i.first, i.last).  NOTE:
   *      the implication of this is that i.cur is always a dereferenceable
   *      pointer, even if i is a past-the-end iterator.
   * - Start and Finish are always nonsingular iterators.  NOTE: this
   * means that an empty deque must have one node, a deque with <N
   * elements (where N is the node buffer size) must have one node, a
   * deque with N through (2N-1) elements must have two nodes, etc.
   * - For every node other than start.node and finish.node, every
   * element in the node is an initialized object.  If start.node ==
   * finish.node, then [start.cur, finish.cur) are initialized
   * objects, and the elements outside that range are uninitialized
   * storage.  Otherwise, [start.cur, start.last) and [finish.first,
   * finish.cur) are initialized objects, and [start.first, start.cur)
   * and [finish.cur, finish.last) are uninitialized storage.
   * - [%map, %map + map_size) is a valid, non-empty range.
   * - [start.node, finish.node] is a valid range contained within
   *   [%map, %map + map_size).
   * - A pointer in the range [%map, %map + map_size) points to an allocated
   *   node if and only if the pointer is in the range
   *   [start.node, finish.node].
   *
   *  Here's the magic:  nothing in deque is @b aware of the discontiguous
   *  storage!
   *
   *  The memory setup and layout occurs in the parent, _Base, and the iterator
   *  class is entirely responsible for @a leaping from one node to the next.
   *  All the implementation routines for deque itself work only through the
   *  start and finish iterators.  This keeps the routines simple and sane,
   *  and we can use other standard algorithms as well.
  */
  template<typename _Tp, typename _Alloc = std::allocator<_Tp> >
    class deque : protected _Deque_base<_Tp, _Alloc>
    {
#ifdef _GLIBCXX_CONCEPT_CHECKS
      // concept requirements
      typedef typename _Alloc::value_type	_Alloc_value_type;
# if __cplusplus < 201103L
      __glibcxx_class_requires(_Tp, _SGIAssignableConcept)
# endif
      __glibcxx_class_requires2(_Tp, _Alloc_value_type, _SameTypeConcept)
#endif

#if __cplusplus >= 201103L
      static_assert(is_same<typename remove_cv<_Tp>::type, _Tp>::value,
	  "std::deque must have a non-const, non-volatile value_type");
# ifdef __STRICT_ANSI__
      static_assert(is_same<typename _Alloc::value_type, _Tp>::value,
	  "std::deque must have the same value_type as its allocator");
# endif
#endif

      typedef _Deque_base<_Tp, _Alloc>			_Base;
      typedef typename _Base::_Tp_alloc_type		_Tp_alloc_type;
      typedef typename _Base::_Alloc_traits		_Alloc_traits;
      typedef typename _Base::_Map_pointer		_Map_pointer;

    public:
      typedef _Tp					value_type;
      typedef typename _Alloc_traits::pointer		pointer;
      typedef typename _Alloc_traits::const_pointer	const_pointer;
      typedef typename _Alloc_traits::reference		reference;
      typedef typename _Alloc_traits::const_reference	const_reference;
      typedef typename _Base::iterator			iterator;
      typedef typename _Base::const_iterator		const_iterator;
      typedef std::reverse_iterator<const_iterator>	const_reverse_iterator;
      typedef std::reverse_iterator<iterator>		reverse_iterator;
      typedef size_t					size_type;
      typedef ptrdiff_t					difference_type;
      typedef _Alloc					allocator_type;

    protected:
      static size_t _S_buffer_size() _GLIBCXX_NOEXCEPT
      { return __deque_buf_size(sizeof(_Tp)); }

      // Functions controlling memory layout, and nothing else.
      using _Base::_M_initialize_map;
      using _Base::_M_create_nodes;
      using _Base::_M_destroy_nodes;
      using _Base::_M_allocate_node;
      using _Base::_M_deallocate_node;
      using _Base::_M_allocate_map;
      using _Base::_M_deallocate_map;
      using _Base::_M_get_Tp_allocator;

      /**
       *  A total of four data members accumulated down the hierarchy.
       *  May be accessed via _M_impl.*
       */
      using _Base::_M_impl;

    public:
      // [23.2.1.1] construct/copy/destroy
      // (assign() and get_allocator() are also listed in this section)

      /**
       *  @brief  Creates a %deque with no elements.
       */
      deque() : _Base() { }

      /**
       *  @brief  Creates a %deque with no elements.
       *  @param  __a  An allocator object.
       */
      explicit
      deque(const allocator_type& __a)
      : _Base(__a, 0) { }

#if __cplusplus >= 201103L
      /**
       *  @brief  Creates a %deque with default constructed elements.
       *  @param  __n  The number of elements to initially create.
       *  @param  __a  An allocator.
       *
       *  This constructor fills the %deque with @a n default
       *  constructed elements.
       */
      explicit
      deque(size_type __n, const allocator_type& __a = allocator_type())
      : _Base(__a, __n)
      { _M_default_initialize(); }

      /**
       *  @brief  Creates a %deque with copies of an exemplar element.
       *  @param  __n  The number of elements to initially create.
       *  @param  __value  An element to copy.
       *  @param  __a  An allocator.
       *
       *  This constructor fills the %deque with @a __n copies of @a __value.
       */
      deque(size_type __n, const value_type& __value,
	    const allocator_type& __a = allocator_type())
      : _Base(__a, __n)
      { _M_fill_initialize(__value); }
#else
      /**
       *  @brief  Creates a %deque with copies of an exemplar element.
       *  @param  __n  The number of elements to initially create.
       *  @param  __value  An element to copy.
       *  @param  __a  An allocator.
       *
       *  This constructor fills the %deque with @a __n copies of @a __value.
       */
      explicit
      deque(size_type __n, const value_type& __value = value_type(),
	    const allocator_type& __a = allocator_type())
      : _Base(__a, __n)
      { _M_fill_initialize(__value); }
#endif

      /**
       *  @brief  %Deque copy constructor.
       *  @param  __x  A %deque of identical element and allocator types.
       *
       *  The newly-created %deque uses a copy of the allocator object used
       *  by @a __x (unless the allocator traits dictate a different object).
       */
      deque(const deque& __x)
      : _Base(_Alloc_traits::_S_select_on_copy(__x._M_get_Tp_allocator()),
	      __x.size())
      { std::__uninitialized_copy_a(__x.begin(), __x.end(),
				    this->_M_impl._M_start,
				    _M_get_Tp_allocator()); }

#if __cplusplus >= 201103L
      /**
       *  @brief  %Deque move constructor.
       *  @param  __x  A %deque of identical element and allocator types.
       *
       *  The newly-created %deque contains the exact contents of @a __x.
       *  The contents of @a __x are a valid, but unspecified %deque.
       */
      deque(deque&& __x)
      : _Base(std::move(__x)) { }

      /// Copy constructor with alternative allocator
      deque(const deque& __x, const allocator_type& __a)
      : _Base(__a, __x.size())
      { std::__uninitialized_copy_a(__x.begin(), __x.end(),
				    this->_M_impl._M_start,
				    _M_get_Tp_allocator()); }

      /// Move constructor with alternative allocator
      deque(deque&& __x, const allocator_type& __a)
      : _Base(std::move(__x), __a, __x.size())
      {
	if (__x.get_allocator() != __a)
	  {
	    std::__uninitialized_move_a(__x.begin(), __x.end(),
					this->_M_impl._M_start,
					_M_get_Tp_allocator());
	    __x.clear();
	  }
      }

      /**
       *  @brief  Builds a %deque from an initializer list.
       *  @param  __l  An initializer_list.
       *  @param  __a  An allocator object.
       *
       *  Create a %deque consisting of copies of the elements in the
       *  initializer_list @a __l.
       *
       *  This will call the element type's copy constructor N times
       *  (where N is __l.size()) and do no memory reallocation.
       */
      deque(initializer_list<value_type> __l,
	    const allocator_type& __a = allocator_type())
      : _Base(__a)
      {
	_M_range_initialize(__l.begin(), __l.end(),
			    random_access_iterator_tag());
      }
#endif

      /**
       *  @brief  Builds a %deque from a range.
       *  @param  __first  An input iterator.
       *  @param  __last  An input iterator.
       *  @param  __a  An allocator object.
       *
       *  Create a %deque consisting of copies of the elements from [__first,
       *  __last).
       *
       *  If the iterators are forward, bidirectional, or random-access, then
       *  this will call the elements' copy constructor N times (where N is
       *  distance(__first,__last)) and do no memory reallocation.  But if only
       *  input iterators are used, then this will do at most 2N calls to the
       *  copy constructor, and logN memory reallocations.
       */
#if __cplusplus >= 201103L
      template<typename _InputIterator,
	       typename = std::_RequireInputIter<_InputIterator>>
	deque(_InputIterator __first, _InputIterator __last,
	      const allocator_type& __a = allocator_type())
	: _Base(__a)
	{ _M_initialize_dispatch(__first, __last, __false_type()); }
#else
      template<typename _InputIterator>
	deque(_InputIterator __first, _InputIterator __last,
	      const allocator_type& __a = allocator_type())
	: _Base(__a)
	{
	  // Check whether it's an integral type.  If so, it's not an iterator.
	  typedef typename std::__is_integer<_InputIterator>::__type _Integral;
	  _M_initialize_dispatch(__first, __last, _Integral());
	}
#endif

      /**
       *  The dtor only erases the elements, and note that if the elements
       *  themselves are pointers, the pointed-to memory is not touched in any
       *  way.  Managing the pointer is the user's responsibility.
       */
      ~deque()
      { _M_destroy_data(begin(), end(), _M_get_Tp_allocator()); }

      /**
       *  @brief  %Deque assignment operator.
       *  @param  __x  A %deque of identical element and allocator types.
       *
       *  All the elements of @a x are copied.
       *
       *  The newly-created %deque uses a copy of the allocator object used
       *  by @a __x (unless the allocator traits dictate a different object).
       */
      deque&
      operator=(const deque& __x);

#if __cplusplus >= 201103L
      /**
       *  @brief  %Deque move assignment operator.
       *  @param  __x  A %deque of identical element and allocator types.
       *
       *  The contents of @a __x are moved into this deque (without copying,
       *  if the allocators permit it).
       *  @a __x is a valid, but unspecified %deque.
       */
      deque&
      operator=(deque&& __x) noexcept(_Alloc_traits::_S_always_equal())
      {
	using __always_equal = typename _Alloc_traits::is_always_equal;
	_M_move_assign1(std::move(__x), __always_equal{});
	return *this;
      }

      /**
       *  @brief  Assigns an initializer list to a %deque.
       *  @param  __l  An initializer_list.
       *
       *  This function fills a %deque with copies of the elements in the
       *  initializer_list @a __l.
       *
       *  Note that the assignment completely changes the %deque and that the
       *  resulting %deque's size is the same as the number of elements
       *  assigned.
       */
      deque&
      operator=(initializer_list<value_type> __l)
      {
	_M_assign_aux(__l.begin(), __l.end(),
		      random_access_iterator_tag());
	return *this;
      }
#endif

      /**
       *  @brief  Assigns a given value to a %deque.
       *  @param  __n  Number of elements to be assigned.
       *  @param  __val  Value to be assigned.
       *
       *  This function fills a %deque with @a n copies of the given
       *  value.  Note that the assignment completely changes the
       *  %deque and that the resulting %deque's size is the same as
       *  the number of elements assigned.
       */
      void
      assign(size_type __n, const value_type& __val)
      { _M_fill_assign(__n, __val); }

      /**
       *  @brief  Assigns a range to a %deque.
       *  @param  __first  An input iterator.
       *  @param  __last   An input iterator.
       *
       *  This function fills a %deque with copies of the elements in the
       *  range [__first,__last).
       *
       *  Note that the assignment completely changes the %deque and that the
       *  resulting %deque's size is the same as the number of elements
       *  assigned.
       */
#if __cplusplus >= 201103L
      template<typename _InputIterator,
	       typename = std::_RequireInputIter<_InputIterator>>
	void
	assign(_InputIterator __first, _InputIterator __last)
	{ _M_assign_dispatch(__first, __last, __false_type()); }
#else
      template<typename _InputIterator>
	void
	assign(_InputIterator __first, _InputIterator __last)
	{
	  typedef typename std::__is_integer<_InputIterator>::__type _Integral;
	  _M_assign_dispatch(__first, __last, _Integral());
	}
#endif

#if __cplusplus >= 201103L
      /**
       *  @brief  Assigns an initializer list to a %deque.
       *  @param  __l  An initializer_list.
       *
       *  This function fills a %deque with copies of the elements in the
       *  initializer_list @a __l.
       *
       *  Note that the assignment completely changes the %deque and that the
       *  resulting %deque's size is the same as the number of elements
       *  assigned.
       */
      void
      assign(initializer_list<value_type> __l)
      { _M_assign_aux(__l.begin(), __l.end(), random_access_iterator_tag()); }
#endif

      /// Get a copy of the memory allocation object.
      allocator_type
      get_allocator() const _GLIBCXX_NOEXCEPT
      { return _Base::get_allocator(); }

      // iterators
      /**
       *  Returns a read/write iterator that points to the first element in the
       *  %deque.  Iteration is done in ordinary element order.
       */
      iterator
      begin() _GLIBCXX_NOEXCEPT
      { return this->_M_impl._M_start; }

      /**
       *  Returns a read-only (constant) iterator that points to the first
       *  element in the %deque.  Iteration is done in ordinary element order.
       */
      const_iterator
      begin() const _GLIBCXX_NOEXCEPT
      { return this->_M_impl._M_start; }

      /**
       *  Returns a read/write iterator that points one past the last
       *  element in the %deque.  Iteration is done in ordinary
       *  element order.
       */
      iterator
      end() _GLIBCXX_NOEXCEPT
      { return this->_M_impl._M_finish; }

      /**
       *  Returns a read-only (constant) iterator that points one past
       *  the last element in the %deque.  Iteration is done in
       *  ordinary element order.
       */
      const_iterator
      end() const _GLIBCXX_NOEXCEPT
      { return this->_M_impl._M_finish; }

      /**
       *  Returns a read/write reverse iterator that points to the
       *  last element in the %deque.  Iteration is done in reverse
       *  element order.
       */
      reverse_iterator
      rbegin() _GLIBCXX_NOEXCEPT
      { return reverse_iterator(this->_M_impl._M_finish); }

      /**
       *  Returns a read-only (constant) reverse iterator that points
       *  to the last element in the %deque.  Iteration is done in
       *  reverse element order.
       */
      const_reverse_iterator
      rbegin() const _GLIBCXX_NOEXCEPT
      { return const_reverse_iterator(this->_M_impl._M_finish); }

      /**
       *  Returns a read/write reverse iterator that points to one
       *  before the first element in the %deque.  Iteration is done
       *  in reverse element order.
       */
      reverse_iterator
      rend() _GLIBCXX_NOEXCEPT
      { return reverse_iterator(this->_M_impl._M_start); }

      /**
       *  Returns a read-only (constant) reverse iterator that points
       *  to one before the first element in the %deque.  Iteration is
       *  done in reverse element order.
       */
      const_reverse_iterator
      rend() const _GLIBCXX_NOEXCEPT
      { return const_reverse_iterator(this->_M_impl._M_start); }

#if __cplusplus >= 201103L
      /**
       *  Returns a read-only (constant) iterator that points to the first
       *  element in the %deque.  Iteration is done in ordinary element order.
       */
      const_iterator
      cbegin() const noexcept
      { return this->_M_impl._M_start; }

      /**
       *  Returns a read-only (constant) iterator that points one past
       *  the last element in the %deque.  Iteration is done in
       *  ordinary element order.
       */
      const_iterator
      cend() const noexcept
      { return this->_M_impl._M_finish; }

      /**
       *  Returns a read-only (constant) reverse iterator that points
       *  to the last element in the %deque.  Iteration is done in
       *  reverse element order.
       */
      const_reverse_iterator
      crbegin() const noexcept
      { return const_reverse_iterator(this->_M_impl._M_finish); }

      /**
       *  Returns a read-only (constant) reverse iterator that points
       *  to one before the first element in the %deque.  Iteration is
       *  done in reverse element order.
       */
      const_reverse_iterator
      crend() const noexcept
      { return const_reverse_iterator(this->_M_impl._M_start); }
#endif

      // [23.2.1.2] capacity
      /**  Returns the number of elements in the %deque.  */
      size_type
      size() const _GLIBCXX_NOEXCEPT
      { return this->_M_impl._M_finish - this->_M_impl._M_start; }

      /**  Returns the size() of the largest possible %deque.  */
      size_type
      max_size() const _GLIBCXX_NOEXCEPT
      { return _Alloc_traits::max_size(_M_get_Tp_allocator()); }

#if __cplusplus >= 201103L
      /**
       *  @brief  Resizes the %deque to the specified number of elements.
       *  @param  __new_size  Number of elements the %deque should contain.
       *
       *  This function will %resize the %deque to the specified
       *  number of elements.  If the number is smaller than the
       *  %deque's current size the %deque is truncated, otherwise
       *  default constructed elements are appended.
       */
      void
      resize(size_type __new_size)
      {
	const size_type __len = size();
	if (__new_size > __len)
	  _M_default_append(__new_size - __len);
	else if (__new_size < __len)
	  _M_erase_at_end(this->_M_impl._M_start
			  + difference_type(__new_size));
      }

      /**
       *  @brief  Resizes the %deque to the specified number of elements.
       *  @param  __new_size  Number of elements the %deque should contain.
       *  @param  __x  Data with which new elements should be populated.
       *
       *  This function will %resize the %deque to the specified
       *  number of elements.  If the number is smaller than the
       *  %deque's current size the %deque is truncated, otherwise the
       *  %deque is extended and new elements are populated with given
       *  data.
       */
      void
      resize(size_type __new_size, const value_type& __x)
      {
	const size_type __len = size();
	if (__new_size > __len)
	  _M_fill_insert(this->_M_impl._M_finish, __new_size - __len, __x);
	else if (__new_size < __len)
	  _M_erase_at_end(this->_M_impl._M_start
			  + difference_type(__new_size));
      }
#else
      /**
       *  @brief  Resizes the %deque to the specified number of elements.
       *  @param  __new_size  Number of elements the %deque should contain.
       *  @param  __x  Data with which new elements should be populated.
       *
       *  This function will %resize the %deque to the specified
       *  number of elements.  If the number is smaller than the
       *  %deque's current size the %deque is truncated, otherwise the
       *  %deque is extended and new elements are populated with given
       *  data.
       */
      void
      resize(size_type __new_size, value_type __x = value_type())
      {
	const size_type __len = size();
	if (__new_size > __len)
	  _M_fill_insert(this->_M_impl._M_finish, __new_size - __len, __x);
	else if (__new_size < __len)
	  _M_erase_at_end(this->_M_impl._M_start
			  + difference_type(__new_size));
      }
#endif

#if __cplusplus >= 201103L
      /**  A non-binding request to reduce memory use.  */
      void
      shrink_to_fit() noexcept
      { _M_shrink_to_fit(); }
#endif

      /**
       *  Returns true if the %deque is empty.  (Thus begin() would
       *  equal end().)
       */
      bool
      empty() const _GLIBCXX_NOEXCEPT
      { return this->_M_impl._M_finish == this->_M_impl._M_start; }

      // element access
      /**
       *  @brief Subscript access to the data contained in the %deque.
       *  @param __n The index of the element for which data should be
       *  accessed.
       *  @return  Read/write reference to data.
       *
       *  This operator allows for easy, array-style, data access.
       *  Note that data access with this operator is unchecked and
       *  out_of_range lookups are not defined. (For checked lookups
       *  see at().)
       */
      reference
      operator[](size_type __n) _GLIBCXX_NOEXCEPT
      {
	__glibcxx_requires_subscript(__n);
	return this->_M_impl._M_start[difference_type(__n)];
      }

      /**
       *  @brief Subscript access to the data contained in the %deque.
       *  @param __n The index of the element for which data should be
       *  accessed.
       *  @return  Read-only (constant) reference to data.
       *
       *  This operator allows for easy, array-style, data access.
       *  Note that data access with this operator is unchecked and
       *  out_of_range lookups are not defined. (For checked lookups
       *  see at().)
       */
      const_reference
      operator[](size_type __n) const _GLIBCXX_NOEXCEPT
      {
	__glibcxx_requires_subscript(__n);
	return this->_M_impl._M_start[difference_type(__n)];
      }

    protected:
      /// Safety check used only from at().
      void
      _M_range_check(size_type __n) const
      {
	if (__n >= this->size())
	  __throw_out_of_range_fmt(__N("deque::_M_range_check: __n "
				       "(which is %zu)>= this->size() "
				       "(which is %zu)"),
				   __n, this->size());
      }

    public:
      /**
       *  @brief  Provides access to the data contained in the %deque.
       *  @param __n The index of the element for which data should be
       *  accessed.
       *  @return  Read/write reference to data.
       *  @throw  std::out_of_range  If @a __n is an invalid index.
       *
       *  This function provides for safer data access.  The parameter
       *  is first checked that it is in the range of the deque.  The
       *  function throws out_of_range if the check fails.
       */
      reference
      at(size_type __n)
      {
	_M_range_check(__n);
	return (*this)[__n];
      }

      /**
       *  @brief  Provides access to the data contained in the %deque.
       *  @param __n The index of the element for which data should be
       *  accessed.
       *  @return  Read-only (constant) reference to data.
       *  @throw  std::out_of_range  If @a __n is an invalid index.
       *
       *  This function provides for safer data access.  The parameter is first
       *  checked that it is in the range of the deque.  The function throws
       *  out_of_range if the check fails.
       */
      const_reference
      at(size_type __n) const
      {
	_M_range_check(__n);
	return (*this)[__n];
      }

      /**
       *  Returns a read/write reference to the data at the first
       *  element of the %deque.
       */
      reference
      front() _GLIBCXX_NOEXCEPT
      {
	__glibcxx_requires_nonempty();
	return *begin();
      }

      /**
       *  Returns a read-only (constant) reference to the data at the first
       *  element of the %deque.
       */
      const_reference
      front() const _GLIBCXX_NOEXCEPT
      {
	__glibcxx_requires_nonempty();
	return *begin();
      }

      /**
       *  Returns a read/write reference to the data at the last element of the
       *  %deque.
       */
      reference
      back() _GLIBCXX_NOEXCEPT
      {
	__glibcxx_requires_nonempty();
	iterator __tmp = end();
	--__tmp;
	return *__tmp;
      }

      /**
       *  Returns a read-only (constant) reference to the data at the last
       *  element of the %deque.
       */
      const_reference
      back() const _GLIBCXX_NOEXCEPT
      {
	__glibcxx_requires_nonempty();
	const_iterator __tmp = end();
	--__tmp;
	return *__tmp;
      }

      // [23.2.1.2] modifiers
      /**
       *  @brief  Add data to the front of the %deque.
       *  @param  __x  Data to be added.
       *
       *  This is a typical stack operation.  The function creates an
       *  element at the front of the %deque and assigns the given
       *  data to it.  Due to the nature of a %deque this operation
       *  can be done in constant time.
       */
      void
      push_front(const value_type& __x)
      {
	if (this->_M_impl._M_start._M_cur != this->_M_impl._M_start._M_first)
	  {
	    _Alloc_traits::construct(this->_M_impl,
				     this->_M_impl._M_start._M_cur - 1,
				     __x);
	    --this->_M_impl._M_start._M_cur;
	  }
	else
	  _M_push_front_aux(__x);
      }

#if __cplusplus >= 201103L
      void
      push_front(value_type&& __x)
      { emplace_front(std::move(__x)); }

      template<typename... _Args>
#if __cplusplus > 201402L
	reference
#else
	void
#endif
	emplace_front(_Args&&... __args);
#endif

      /**
       *  @brief  Add data to the end of the %deque.
       *  @param  __x  Data to be added.
       *
       *  This is a typical stack operation.  The function creates an
       *  element at the end of the %deque and assigns the given data
       *  to it.  Due to the nature of a %deque this operation can be
       *  done in constant time.
       */
      void
      push_back(const value_type& __x)
      {
	if (this->_M_impl._M_finish._M_cur
	    != this->_M_impl._M_finish._M_last - 1)
	  {
	    _Alloc_traits::construct(this->_M_impl,
				     this->_M_impl._M_finish._M_cur, __x);
	    ++this->_M_impl._M_finish._M_cur;
	  }
	else
	  _M_push_back_aux(__x);
      }

#if __cplusplus >= 201103L
      void
      push_back(value_type&& __x)
      { emplace_back(std::move(__x)); }

      template<typename... _Args>
#if __cplusplus > 201402L
	reference
#else
	void
#endif
	emplace_back(_Args&&... __args);
#endif

      /**
       *  @brief  Removes first element.
       *
       *  This is a typical stack operation.  It shrinks the %deque by one.
       *
       *  Note that no data is returned, and if the first element's data is
       *  needed, it should be retrieved before pop_front() is called.
       */
      void
      pop_front() _GLIBCXX_NOEXCEPT
      {
	__glibcxx_requires_nonempty();
	if (this->_M_impl._M_start._M_cur
	    != this->_M_impl._M_start._M_last - 1)
	  {
	    _Alloc_traits::destroy(this->_M_impl,
				   this->_M_impl._M_start._M_cur);
	    ++this->_M_impl._M_start._M_cur;
	  }
	else
	  _M_pop_front_aux();
      }

      /**
       *  @brief  Removes last element.
       *
       *  This is a typical stack operation.  It shrinks the %deque by one.
       *
       *  Note that no data is returned, and if the last element's data is
       *  needed, it should be retrieved before pop_back() is called.
       */
      void
      pop_back() _GLIBCXX_NOEXCEPT
      {
	__glibcxx_requires_nonempty();
	if (this->_M_impl._M_finish._M_cur
	    != this->_M_impl._M_finish._M_first)
	  {
	    --this->_M_impl._M_finish._M_cur;
	    _Alloc_traits::destroy(this->_M_impl,
				   this->_M_impl._M_finish._M_cur);
	  }
	else
	  _M_pop_back_aux();
      }

#if __cplusplus >= 201103L
      /**
       *  @brief  Inserts an object in %deque before specified iterator.
       *  @param  __position  A const_iterator into the %deque.
       *  @param  __args  Arguments.
       *  @return  An iterator that points to the inserted data.
       *
       *  This function will insert an object of type T constructed
       *  with T(std::forward<Args>(args)...) before the specified location.
       */
      template<typename... _Args>
	iterator
	emplace(const_iterator __position, _Args&&... __args);

      /**
       *  @brief  Inserts given value into %deque before specified iterator.
       *  @param  __position  A const_iterator into the %deque.
       *  @param  __x  Data to be inserted.
       *  @return  An iterator that points to the inserted data.
       *
       *  This function will insert a copy of the given value before the
       *  specified location.
       */
      iterator
      insert(const_iterator __position, const value_type& __x);
#else
      /**
       *  @brief  Inserts given value into %deque before specified iterator.
       *  @param  __position  An iterator into the %deque.
       *  @param  __x  Data to be inserted.
       *  @return  An iterator that points to the inserted data.
       *
       *  This function will insert a copy of the given value before the
       *  specified location.
       */
      iterator
      insert(iterator __position, const value_type& __x);
#endif

#if __cplusplus >= 201103L
      /**
       *  @brief  Inserts given rvalue into %deque before specified iterator.
       *  @param  __position  A const_iterator into the %deque.
       *  @param  __x  Data to be inserted.
       *  @return  An iterator that points to the inserted data.
       *
       *  This function will insert a copy of the given rvalue before the
       *  specified location.
       */
      iterator
      insert(const_iterator __position, value_type&& __x)
      { return emplace(__position, std::move(__x)); }

      /**
       *  @brief  Inserts an initializer list into the %deque.
       *  @param  __p  An iterator into the %deque.
       *  @param  __l  An initializer_list.
       *
       *  This function will insert copies of the data in the
       *  initializer_list @a __l into the %deque before the location
       *  specified by @a __p.  This is known as <em>list insert</em>.
       */
      iterator
      insert(const_iterator __p, initializer_list<value_type> __l)
      {
	auto __offset = __p - cbegin();
	_M_range_insert_aux(__p._M_const_cast(), __l.begin(), __l.end(),
			    std::random_access_iterator_tag());
	return begin() + __offset;
      }
#endif

#if __cplusplus >= 201103L
      /**
       *  @brief  Inserts a number of copies of given data into the %deque.
       *  @param  __position  A const_iterator into the %deque.
       *  @param  __n  Number of elements to be inserted.
       *  @param  __x  Data to be inserted.
       *  @return  An iterator that points to the inserted data.
       *
       *  This function will insert a specified number of copies of the given
       *  data before the location specified by @a __position.
       */
      iterator
      insert(const_iterator __position, size_type __n, const value_type& __x)
      {
	difference_type __offset = __position - cbegin();
	_M_fill_insert(__position._M_const_cast(), __n, __x);
	return begin() + __offset;
      }
#else
      /**
       *  @brief  Inserts a number of copies of given data into the %deque.
       *  @param  __position  An iterator into the %deque.
       *  @param  __n  Number of elements to be inserted.
       *  @param  __x  Data to be inserted.
       *
       *  This function will insert a specified number of copies of the given
       *  data before the location specified by @a __position.
       */
      void
      insert(iterator __position, size_type __n, const value_type& __x)
      { _M_fill_insert(__position, __n, __x); }
#endif

#if __cplusplus >= 201103L
      /**
       *  @brief  Inserts a range into the %deque.
       *  @param  __position  A const_iterator into the %deque.
       *  @param  __first  An input iterator.
       *  @param  __last   An input iterator.
       *  @return  An iterator that points to the inserted data.
       *
       *  This function will insert copies of the data in the range
       *  [__first,__last) into the %deque before the location specified
       *  by @a __position.  This is known as <em>range insert</em>.
       */
      template<typename _InputIterator,
	       typename = std::_RequireInputIter<_InputIterator>>
	iterator
	insert(const_iterator __position, _InputIterator __first,
	       _InputIterator __last)
	{
	  difference_type __offset = __position - cbegin();
	  _M_insert_dispatch(__position._M_const_cast(),
			     __first, __last, __false_type());
	  return begin() + __offset;
	}
#else
      /**
       *  @brief  Inserts a range into the %deque.
       *  @param  __position  An iterator into the %deque.
       *  @param  __first  An input iterator.
       *  @param  __last   An input iterator.
       *
       *  This function will insert copies of the data in the range
       *  [__first,__last) into the %deque before the location specified
       *  by @a __position.  This is known as <em>range insert</em>.
       */
      template<typename _InputIterator>
	void
	insert(iterator __position, _InputIterator __first,
	       _InputIterator __last)
	{
	  // Check whether it's an integral type.  If so, it's not an iterator.
	  typedef typename std::__is_integer<_InputIterator>::__type _Integral;
	  _M_insert_dispatch(__position, __first, __last, _Integral());
	}
#endif

      /**
       *  @brief  Remove element at given position.
       *  @param  __position  Iterator pointing to element to be erased.
       *  @return  An iterator pointing to the next element (or end()).
       *
       *  This function will erase the element at the given position and thus
       *  shorten the %deque by one.
       *
       *  The user is cautioned that
       *  this function only erases the element, and that if the element is
       *  itself a pointer, the pointed-to memory is not touched in any way.
       *  Managing the pointer is the user's responsibility.
       */
      iterator
#if __cplusplus >= 201103L
      erase(const_iterator __position)
#else
      erase(iterator __position)
#endif
      { return _M_erase(__position._M_const_cast()); }

      /**
       *  @brief  Remove a range of elements.
       *  @param  __first  Iterator pointing to the first element to be erased.
       *  @param  __last  Iterator pointing to one past the last element to be
       *                erased.
       *  @return  An iterator pointing to the element pointed to by @a last
       *           prior to erasing (or end()).
       *
       *  This function will erase the elements in the range
       *  [__first,__last) and shorten the %deque accordingly.
       *
       *  The user is cautioned that
       *  this function only erases the elements, and that if the elements
       *  themselves are pointers, the pointed-to memory is not touched in any
       *  way.  Managing the pointer is the user's responsibility.
       */
      iterator
#if __cplusplus >= 201103L
      erase(const_iterator __first, const_iterator __last)
#else
      erase(iterator __first, iterator __last)
#endif
      { return _M_erase(__first._M_const_cast(), __last._M_const_cast()); }

      /**
       *  @brief  Swaps data with another %deque.
       *  @param  __x  A %deque of the same element and allocator types.
       *
       *  This exchanges the elements between two deques in constant time.
       *  (Four pointers, so it should be quite fast.)
       *  Note that the global std::swap() function is specialized such that
       *  std::swap(d1,d2) will feed to this function.
       *
       *  Whether the allocators are swapped depends on the allocator traits.
       */
      void
      swap(deque& __x) _GLIBCXX_NOEXCEPT
      {
#if __cplusplus >= 201103L
	__glibcxx_assert(_Alloc_traits::propagate_on_container_swap::value
			 || _M_get_Tp_allocator() == __x._M_get_Tp_allocator());
#endif
	_M_impl._M_swap_data(__x._M_impl);
	_Alloc_traits::_S_on_swap(_M_get_Tp_allocator(),
				  __x._M_get_Tp_allocator());
      }

      /**
       *  Erases all the elements.  Note that this function only erases the
       *  elements, and that if the elements themselves are pointers, the
       *  pointed-to memory is not touched in any way.  Managing the pointer is
       *  the user's responsibility.
       */
      void
      clear() _GLIBCXX_NOEXCEPT
      { _M_erase_at_end(begin()); }

    protected:
      // Internal constructor functions follow.

      // called by the range constructor to implement [23.1.1]/9

      // _GLIBCXX_RESOLVE_LIB_DEFECTS
      // 438. Ambiguity in the "do the right thing" clause
      template<typename _Integer>
	void
	_M_initialize_dispatch(_Integer __n, _Integer __x, __true_type)
	{
	  _M_initialize_map(static_cast<size_type>(__n));
	  _M_fill_initialize(__x);
	}

      // called by the range constructor to implement [23.1.1]/9
      template<typename _InputIterator>
	void
	_M_initialize_dispatch(_InputIterator __first, _InputIterator __last,
			       __false_type)
	{
	  _M_range_initialize(__first, __last,
			      std::__iterator_category(__first));
	}

      // called by the second initialize_dispatch above
      //@{
      /**
       *  @brief Fills the deque with whatever is in [first,last).
       *  @param  __first  An input iterator.
       *  @param  __last  An input iterator.
       *  @return   Nothing.
       *
       *  If the iterators are actually forward iterators (or better), then the
       *  memory layout can be done all at once.  Else we move forward using
       *  push_back on each value from the iterator.
       */
      template<typename _InputIterator>
	void
	_M_range_initialize(_InputIterator __first, _InputIterator __last,
			    std::input_iterator_tag);

      // called by the second initialize_dispatch above
      template<typename _ForwardIterator>
	void
	_M_range_initialize(_ForwardIterator __first, _ForwardIterator __last,
			    std::forward_iterator_tag);
      //@}

      /**
       *  @brief Fills the %deque with copies of value.
       *  @param  __value  Initial value.
       *  @return   Nothing.
       *  @pre _M_start and _M_finish have already been initialized,
       *  but none of the %deque's elements have yet been constructed.
       *
       *  This function is called only when the user provides an explicit size
       *  (with or without an explicit exemplar value).
       */
      void
      _M_fill_initialize(const value_type& __value);

#if __cplusplus >= 201103L
      // called by deque(n).
      void
      _M_default_initialize();
#endif

      // Internal assign functions follow.  The *_aux functions do the actual
      // assignment work for the range versions.

      // called by the range assign to implement [23.1.1]/9

      // _GLIBCXX_RESOLVE_LIB_DEFECTS
      // 438. Ambiguity in the "do the right thing" clause
      template<typename _Integer>
	void
	_M_assign_dispatch(_Integer __n, _Integer __val, __true_type)
	{ _M_fill_assign(__n, __val); }

      // called by the range assign to implement [23.1.1]/9
      template<typename _InputIterator>
	void
	_M_assign_dispatch(_InputIterator __first, _InputIterator __last,
			   __false_type)
	{ _M_assign_aux(__first, __last, std::__iterator_category(__first)); }

      // called by the second assign_dispatch above
      template<typename _InputIterator>
	void
	_M_assign_aux(_InputIterator __first, _InputIterator __last,
		      std::input_iterator_tag);

      // called by the second assign_dispatch above
      template<typename _ForwardIterator>
	void
	_M_assign_aux(_ForwardIterator __first, _ForwardIterator __last,
		      std::forward_iterator_tag)
	{
	  const size_type __len = std::distance(__first, __last);
	  if (__len > size())
	    {
	      _ForwardIterator __mid = __first;
	      std::advance(__mid, size());
	      std::copy(__first, __mid, begin());
	      _M_range_insert_aux(end(), __mid, __last,
				  std::__iterator_category(__first));
	    }
	  else
	    _M_erase_at_end(std::copy(__first, __last, begin()));
	}

      // Called by assign(n,t), and the range assign when it turns out
      // to be the same thing.
      void
      _M_fill_assign(size_type __n, const value_type& __val)
      {
	if (__n > size())
	  {
	    std::fill(begin(), end(), __val);
	    _M_fill_insert(end(), __n - size(), __val);
	  }
	else
	  {
	    _M_erase_at_end(begin() + difference_type(__n));
	    std::fill(begin(), end(), __val);
	  }
      }

      //@{
      /// Helper functions for push_* and pop_*.
#if __cplusplus < 201103L
      void _M_push_back_aux(const value_type&);

      void _M_push_front_aux(const value_type&);
#else
      template<typename... _Args>
	void _M_push_back_aux(_Args&&... __args);

      template<typename... _Args>
	void _M_push_front_aux(_Args&&... __args);
#endif

      void _M_pop_back_aux();

      void _M_pop_front_aux();
      //@}

      // Internal insert functions follow.  The *_aux functions do the actual
      // insertion work when all shortcuts fail.

      // called by the range insert to implement [23.1.1]/9

      // _GLIBCXX_RESOLVE_LIB_DEFECTS
      // 438. Ambiguity in the "do the right thing" clause
      template<typename _Integer>
	void
	_M_insert_dispatch(iterator __pos,
			   _Integer __n, _Integer __x, __true_type)
	{ _M_fill_insert(__pos, __n, __x); }

      // called by the range insert to implement [23.1.1]/9
      template<typename _InputIterator>
	void
	_M_insert_dispatch(iterator __pos,
			   _InputIterator __first, _InputIterator __last,
			   __false_type)
	{
	  _M_range_insert_aux(__pos, __first, __last,
			      std::__iterator_category(__first));
	}

      // called by the second insert_dispatch above
      template<typename _InputIterator>
	void
	_M_range_insert_aux(iterator __pos, _InputIterator __first,
			    _InputIterator __last, std::input_iterator_tag);

      // called by the second insert_dispatch above
      template<typename _ForwardIterator>
	void
	_M_range_insert_aux(iterator __pos, _ForwardIterator __first,
			    _ForwardIterator __last, std::forward_iterator_tag);

      // Called by insert(p,n,x), and the range insert when it turns out to be
      // the same thing.  Can use fill functions in optimal situations,
      // otherwise passes off to insert_aux(p,n,x).
      void
      _M_fill_insert(iterator __pos, size_type __n, const value_type& __x);

      // called by insert(p,x)
#if __cplusplus < 201103L
      iterator
      _M_insert_aux(iterator __pos, const value_type& __x);
#else
      template<typename... _Args>
	iterator
	_M_insert_aux(iterator __pos, _Args&&... __args);
#endif

      // called by insert(p,n,x) via fill_insert
      void
      _M_insert_aux(iterator __pos, size_type __n, const value_type& __x);

      // called by range_insert_aux for forward iterators
      template<typename _ForwardIterator>
	void
	_M_insert_aux(iterator __pos,
		      _ForwardIterator __first, _ForwardIterator __last,
		      size_type __n);


      // Internal erase functions follow.

      void
      _M_destroy_data_aux(iterator __first, iterator __last);

      // Called by ~deque().
      // NB: Doesn't deallocate the nodes.
      template<typename _Alloc1>
	void
	_M_destroy_data(iterator __first, iterator __last, const _Alloc1&)
	{ _M_destroy_data_aux(__first, __last); }

      void
      _M_destroy_data(iterator __first, iterator __last,
		      const std::allocator<_Tp>&)
      {
	if (!__has_trivial_destructor(value_type))
	  _M_destroy_data_aux(__first, __last);
      }

      // Called by erase(q1, q2).
      void
      _M_erase_at_begin(iterator __pos)
      {
	_M_destroy_data(begin(), __pos, _M_get_Tp_allocator());
	_M_destroy_nodes(this->_M_impl._M_start._M_node, __pos._M_node);
	this->_M_impl._M_start = __pos;
      }

      // Called by erase(q1, q2), resize(), clear(), _M_assign_aux,
      // _M_fill_assign, operator=.
      void
      _M_erase_at_end(iterator __pos)
      {
	_M_destroy_data(__pos, end(), _M_get_Tp_allocator());
	_M_destroy_nodes(__pos._M_node + 1,
			 this->_M_impl._M_finish._M_node + 1);
	this->_M_impl._M_finish = __pos;
      }

      iterator
      _M_erase(iterator __pos);

      iterator
      _M_erase(iterator __first, iterator __last);

#if __cplusplus >= 201103L
      // Called by resize(sz).
      void
      _M_default_append(size_type __n);

      bool
      _M_shrink_to_fit();
#endif

      //@{
      /// Memory-handling helpers for the previous internal insert functions.
      iterator
      _M_reserve_elements_at_front(size_type __n)
      {
	const size_type __vacancies = this->_M_impl._M_start._M_cur
				      - this->_M_impl._M_start._M_first;
	if (__n > __vacancies)
	  _M_new_elements_at_front(__n - __vacancies);
	return this->_M_impl._M_start - difference_type(__n);
      }

      iterator
      _M_reserve_elements_at_back(size_type __n)
      {
	const size_type __vacancies = (this->_M_impl._M_finish._M_last
				       - this->_M_impl._M_finish._M_cur) - 1;
	if (__n > __vacancies)
	  _M_new_elements_at_back(__n - __vacancies);
	return this->_M_impl._M_finish + difference_type(__n);
      }

      void
      _M_new_elements_at_front(size_type __new_elements);

      void
      _M_new_elements_at_back(size_type __new_elements);
      //@}


      //@{
      /**
       *  @brief Memory-handling helpers for the major %map.
       *
       *  Makes sure the _M_map has space for new nodes.  Does not
       *  actually add the nodes.  Can invalidate _M_map pointers.
       *  (And consequently, %deque iterators.)
       */
      void
      _M_reserve_map_at_back(size_type __nodes_to_add = 1)
      {
	if (__nodes_to_add + 1 > this->_M_impl._M_map_size
	    - (this->_M_impl._M_finish._M_node - this->_M_impl._M_map))
	  _M_reallocate_map(__nodes_to_add, false);
      }

      void
      _M_reserve_map_at_front(size_type __nodes_to_add = 1)
      {
	if (__nodes_to_add > size_type(this->_M_impl._M_start._M_node
				       - this->_M_impl._M_map))
	  _M_reallocate_map(__nodes_to_add, true);
      }

      void
      _M_reallocate_map(size_type __nodes_to_add, bool __add_at_front);
      //@}

#if __cplusplus >= 201103L
      // Constant-time, nothrow move assignment when source object's memory
      // can be moved because the allocators are equal.
      void
      _M_move_assign1(deque&& __x, /* always equal: */ true_type) noexcept
      {
	this->_M_impl._M_swap_data(__x._M_impl);
	__x.clear();
	std::__alloc_on_move(_M_get_Tp_allocator(), __x._M_get_Tp_allocator());
      }

      // When the allocators are not equal the operation could throw, because
      // we might need to allocate a new map for __x after moving from it
      // or we might need to allocate new elements for *this.
      void
      _M_move_assign1(deque&& __x, /* always equal: */ false_type)
      {
	constexpr bool __move_storage =
	  _Alloc_traits::_S_propagate_on_move_assign();
	_M_move_assign2(std::move(__x), __bool_constant<__move_storage>());
      }

      // Destroy all elements and deallocate all memory, then replace
      // with elements created from __args.
      template<typename... _Args>
      void
      _M_replace_map(_Args&&... __args)
      {
	// Create new data first, so if allocation fails there are no effects.
	deque __newobj(std::forward<_Args>(__args)...);
	// Free existing storage using existing allocator.
	clear();
	_M_deallocate_node(*begin()._M_node); // one node left after clear()
	_M_deallocate_map(this->_M_impl._M_map, this->_M_impl._M_map_size);
	this->_M_impl._M_map = nullptr;
	this->_M_impl._M_map_size = 0;
	// Take ownership of replacement memory.
	this->_M_impl._M_swap_data(__newobj._M_impl);
      }

      // Do move assignment when the allocator propagates.
      void
      _M_move_assign2(deque&& __x, /* propagate: */ true_type)
      {
	// Make a copy of the original allocator state.
	auto __alloc = __x._M_get_Tp_allocator();
	// The allocator propagates so storage can be moved from __x,
	// leaving __x in a valid empty state with a moved-from allocator.
	_M_replace_map(std::move(__x));
	// Move the corresponding allocator state too.
	_M_get_Tp_allocator() = std::move(__alloc);
      }

      // Do move assignment when it may not be possible to move source
      // object's memory, resulting in a linear-time operation.
      void
      _M_move_assign2(deque&& __x, /* propagate: */ false_type)
      {
	if (__x._M_get_Tp_allocator() == this->_M_get_Tp_allocator())
	  {
	    // The allocators are equal so storage can be moved from __x,
	    // leaving __x in a valid empty state with its current allocator.
	    _M_replace_map(std::move(__x), __x.get_allocator());
	  }
	else
	  {
	    // The rvalue's allocator cannot be moved and is not equal,
	    // so we need to individually move each element.
	    _M_assign_aux(std::__make_move_if_noexcept_iterator(__x.begin()),
			  std::__make_move_if_noexcept_iterator(__x.end()),
			  std::random_access_iterator_tag());
	    __x.clear();
	  }
      }
#endif
    };

#if __cpp_deduction_guides >= 201606
  template<typename _InputIterator, typename _ValT
	     = typename iterator_traits<_InputIterator>::value_type,
	   typename _Allocator = allocator<_ValT>,
	   typename = _RequireInputIter<_InputIterator>,
	   typename = _RequireAllocator<_Allocator>>
    deque(_InputIterator, _InputIterator, _Allocator = _Allocator())
      -> deque<_ValT, _Allocator>;
#endif

  /**
   *  @brief  Deque equality comparison.
   *  @param  __x  A %deque.
   *  @param  __y  A %deque of the same type as @a __x.
   *  @return  True iff the size and elements of the deques are equal.
   *
   *  This is an equivalence relation.  It is linear in the size of the
   *  deques.  Deques are considered equivalent if their sizes are equal,
   *  and if corresponding elements compare equal.
  */
  template<typename _Tp, typename _Alloc>
    inline bool
    operator==(const deque<_Tp, _Alloc>& __x,
                         const deque<_Tp, _Alloc>& __y)
    { return __x.size() == __y.size()
	     && std::equal(__x.begin(), __x.end(), __y.begin()); }

  /**
   *  @brief  Deque ordering relation.
   *  @param  __x  A %deque.
   *  @param  __y  A %deque of the same type as @a __x.
   *  @return  True iff @a x is lexicographically less than @a __y.
   *
   *  This is a total ordering relation.  It is linear in the size of the
   *  deques.  The elements must be comparable with @c <.
   *
   *  See std::lexicographical_compare() for how the determination is made.
  */
  template<typename _Tp, typename _Alloc>
    inline bool
    operator<(const deque<_Tp, _Alloc>& __x,
	      const deque<_Tp, _Alloc>& __y)
    { return std::lexicographical_compare(__x.begin(), __x.end(),
					  __y.begin(), __y.end()); }

  /// Based on operator==
  template<typename _Tp, typename _Alloc>
    inline bool
    operator!=(const deque<_Tp, _Alloc>& __x,
	       const deque<_Tp, _Alloc>& __y)
    { return !(__x == __y); }

  /// Based on operator<
  template<typename _Tp, typename _Alloc>
    inline bool
    operator>(const deque<_Tp, _Alloc>& __x,
	      const deque<_Tp, _Alloc>& __y)
    { return __y < __x; }

  /// Based on operator<
  template<typename _Tp, typename _Alloc>
    inline bool
    operator<=(const deque<_Tp, _Alloc>& __x,
	       const deque<_Tp, _Alloc>& __y)
    { return !(__y < __x); }

  /// Based on operator<
  template<typename _Tp, typename _Alloc>
    inline bool
    operator>=(const deque<_Tp, _Alloc>& __x,
	       const deque<_Tp, _Alloc>& __y)
    { return !(__x < __y); }

  /// See std::deque::swap().
  template<typename _Tp, typename _Alloc>
    inline void
    swap(deque<_Tp,_Alloc>& __x, deque<_Tp,_Alloc>& __y)
    _GLIBCXX_NOEXCEPT_IF(noexcept(__x.swap(__y)))
    { __x.swap(__y); }

#undef _GLIBCXX_DEQUE_BUF_SIZE

_GLIBCXX_END_NAMESPACE_CONTAINER
_GLIBCXX_END_NAMESPACE_VERSION
} // namespace std

#endif /* _STL_DEQUE_H */

如果你觉得这篇文章对你有帮助,不妨动动手指给点赞收藏加转发,给鄃鳕一个大大的关注你们的每一次支持都将转化为我前进的动力!!!

本文来自互联网用户投稿,该文观点仅代表作者本人,不代表本站立场。本站仅提供信息存储空间服务,不拥有所有权,不承担相关法律责任。如若转载,请注明出处:http://www.coloradmin.cn/o/885766.html

如若内容造成侵权/违法违规/事实不符,请联系多彩编程网进行投诉反馈,一经查实,立即删除!

相关文章

猿人学刷题系列(第一届比赛)——第三题

题目&#xff1a;抓取下列5页商标的数据&#xff0c;并将出现频率最高的申请号填入答案中 地址&#xff1a;https://match.yuanrenxue.cn/match/3 本题主要考察请求逻辑&#xff0c;可以借助fiddler或Charles等抓包工具进行分析。首先通过浏览器来简单进行请求逻辑分析。 从抓…

Linux系统下消息中间件RocketMQ下载、安装、搭建、配置、控制台rocketmq-dashboard的安装保姆级教程 rocketmq ui

这里给出我使用的 RocketMQ 版本&#xff08;5.1.3&#xff09;、RocketMQ-Dashboard 版本的百度网盘链接&#xff1a; 链接&#xff1a;https://pan.baidu.com/s/1HaKBBDGWZ0WKLGgVwIG9pw 提取码&#xff1a;1234 文章目录 一. 官网下载安装二、启动NameServer三、启动Broker四…

Linux学习之初识Linux

目录 一.Linux的发展历史及概念 1.什么是Linux UNIX发展的历史&#xff1a; Linux发展历史&#xff1a; 2. 开源 商业化发行版本 二. 如何搭建Linux环境 Linux 环境的搭建方式主要有三种&#xff1a; 1. 直接安装在物理机上 2. 使用虚拟机软件 3. 使用云服务器 三. …

4.SpringCloud

1.SpringCloud概述 Spring Cloud为开发人员提供了快速构建分布式系统中一些常见模式的工具&#xff08;例如配置管理&#xff0c;服务发现&#xff0c;断路器&#xff0c;智能路由&#xff0c;微代理&#xff0c;控制总线&#xff0c;一次性令牌&#xff0c;全局锁&#xff0c;…

【游戏评测】河洛群侠传一周目玩后感

总游戏时长接近100小时&#xff0c;刚好一个月。 这两天费了点劲做了些成就&#xff0c;刷了等级&#xff0c;把最终决战做了。 总体感觉还是不错的。游戏是开放世界3D游戏&#xff0c;Unity引擎&#xff0c;瑕疵很多&#xff0c;但胜在剧情扎实&#xff0c;天赋系统、秘籍功法…

读书笔记 |【项目思维与管理】➾ 成功的项目需要有效的管理

读书笔记 |【项目思维与管理】➾ 成功的项目需要有效的管理 一、项目:一项难以完成的使命二、要管理项目先要理解"管理"三、项目管理成功的标准四、使项目利益相关者满意 &#x1f496;The Begin&#x1f496;点点关注&#xff0c;收藏不迷路&#x1f496; 如果你没有…

Activity启动模式中的生命周期

彻底明白Activity启动模式中的生命周期&#xff0c;从此不再成为面试难点。 参考&#xff1a; https://www.zhihu.com/tardis/zm/art/429845377?source_id1003 https://developer.aliyun.com/article/951609 https://cloud.tencent.com/developer/article/1763205 Activity…

2020年9月全国计算机等级考试真题(C语言二级)

2020年9月全国计算机等级考试真题&#xff08;C语言二级&#xff09; 第1题 有下列程序&#xff1a; #include<stdio.h> main() { FILE*fp;int k,n,a[6]{1,2,3,4,5,6}; fpfopen("d2.dat","w"); fprintf(fp,"%d%d%d\n",a[0],…

代码随想录章节目录—力扣算法题系列:数组.Java版(可点击文中超链接跳转到想看的题目)

版本说明 当前版本号[20230816]。 版本修改说明20230816初版 目录 文章目录 版本说明目录数组总结篇数组理论基础数组的经典题目二分法双指针法滑动窗口模拟行为 总结 数组总结篇 数组理论基础 数组是非常基础的数据结构&#xff0c;在面试中&#xff0c;考察数组的题目一…

B-树和B+树的区别

B-树和B树的区别 一、B-tree数据存储 在下图中 P 代表的是指针&#xff0c;指向的是下一个磁盘块。在第一个节点中的 16、24 就是代表我们的 key 值是什么。date 就是这个 key 值对应的这一行记录是什么。 假设寻找 key 为 33 的这条记录&#xff0c;33 在 16 和 34 中间&am…

Kubernetes入门 五、深入Pod:探针和生命周期

目录 探针探针类型LivenessProbeReadinessProbeStartupProbe&#xff1a; 探测方式ExecActionTCPSocketActionHTTPGetAction 参数配置操作示例 生命周期钩子函数生命周期 探针 所谓的探针就是容器内应用的监测机制&#xff0c;为了确保容器在部署后确实处在正常运行状态。 比…

系统驱动-点亮LED灯

实现LED点亮 demo.c #include <linux/init.h> #include <linux/module.h> #include <linux/fs.h> #include <linux/uaccess.h> #include <linux/io.h> #include <linux/device.h> #include "head.h" int major; char kbuf[12…

GitHub星标11.9k的机器学习开源项目分享,3 万行代码,30多个主流模型

今天给大家分享一个超剽悍的开源项目&#xff0c;目前在github上已获11.9k星标。 项目作者是普林斯顿博士后David Bourgin&#xff0c;他用 NumPy 手推了一大波 ML 模型&#xff0c;基本上把主流模型都实现了一遍&#xff0c;这个工作量我直呼牛X。 虽然现在手写模型已经不是…

星星之火:国产讯飞星火大模型的实际使用体验(与GPT对比)

#AIGC技术内容创作征文&#xff5c;全网寻找AI创作者&#xff0c;快来释放你的创作潜能吧&#xff01;# 文章目录 1 前言2 测试详情2.1 文案写作2.2 知识写作2.3 阅读理解2.4 语意测试&#xff08;重点关注&#xff09;2.5 常识性测试&#xff08;重点关注&#xff09;2.6 代码…

摄影馆预约小程序开发指南:打造高效预约管理系统

随着数字化时代的到来&#xff0c;越来越多的行业开始借助互联网工具提升服务质量和效率。摄影行业也不例外&#xff0c;为了更好地满足用户的需求&#xff0c;许多摄影店开始搭建预约小程序&#xff0c;方便用户在线预约和管理。 首先&#xff0c;进入乔拓云网后台&#xff0c…

回归预测 | MATLAB实现BiLSTM双向长短期记忆神经网络多输入多输出预测

回归预测 | MATLAB实现BiLSTM双向长短期记忆神经网络多输入多输出预测 目录 回归预测 | MATLAB实现BiLSTM双向长短期记忆神经网络多输入多输出预测预测效果基本介绍程序设计往期精彩参考资料 预测效果 基本介绍 MATLAB实现BiLSTM双向长短期记忆神经网络多输入多输出预测&#x…

深入剖析低代码平台的优势与挑战

近年来&#xff0c;我国高度重视数字经济的发展&#xff0c;强化数字技术创新应用&#xff0c;全面推进企业数字化转型工作。在全国各行业数字化转型的浪潮中&#xff0c;低代码通过可视化、模块化开发操作&#xff0c;降低软件开发门槛&#xff0c;强化资源扩展和信息集成&…

分布式学习:从分布式系统的特征开始

正文   在延伸feature&#xff08;分布式系统需要考虑的特性&#xff09;的时候&#xff0c;我逐渐明白&#xff0c;这是因为要满足这些feature&#xff0c;才设计了很多协议与算法&#xff0c;也提出了一些理论。比如说&#xff0c;这是因为要解决去中心化副本的一致性问题&…

司徒理财:8.16黄金行情走势分析及策略美盘看涨

黄金早盘已经给了1902的现价多单&#xff0c;日内最高触及1907&#xff01;如期拉升&#xff01;黄金现在筑底阶段&#xff0c;维持低多看涨思路&#xff0c;美盘1900附近继续做多看涨&#xff0c;等待反弹&#xff01;黄金现在的下跌已经到达日线前低位置&#xff0c;继续破位…

程序员的新型生产力工具,效率起飞了~

文章目录 一、低代码平台存在的意义 二、国内外低代码开发研究现状 三、低代码开发平台设计与实现 系统架构总体设计 01.表单引擎设计 02.流程引擎设计 03.数据库设计 四、总结 一、低代码平台存在的意义 传统软件开发交付链中&#xff0c;需求经过3次传递&#xff0c;用户→业…