/usr/share/gccxml-0.9/GCC/4.6/bits/stl_algo.h is in gccxml 0.9.0+cvs20120420-4.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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6022 6023 6024 6025 6026 6027 6028 6029 6030 6031 6032 6033 6034 6035 6036 6037 6038 6039 6040 6041 6042 6043 6044 6045 6046 6047 6048 6049 6050 6051 6052 6053 6054 6055 6056 6057 6058 6059 6060 6061 6062 6063 6064 6065 6066 6067 6068 6069 6070 6071 6072 6073 6074 6075 6076 6077 6078 6079 6080 6081 6082 6083 6084 6085 6086 6087 6088 6089 6090 6091 6092 6093 6094 6095 6096 6097 6098 6099 6100 6101 6102 6103 6104 6105 6106 6107 6108 6109 6110 6111 6112 6113 6114 6115 6116 6117 6118 6119 6120 6121 6122 6123 6124 6125 6126 6127 6128 6129 6130 6131 6132 6133 6134 6135 6136 6137 6138 6139 6140 6141 6142 6143 6144 6145 6146 6147 6148 6149 6150 6151 6152 6153 6154 6155 6156 6157 6158 6159 6160 6161 6162 6163 6164 6165 6166 6167 6168 6169 6170 6171 6172 6173 | // Algorithm implementation -*- C++ -*-
// Copyright (C) 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009,
// 2010, 2011
// 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) 1996
* 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_algo.h
* This is an internal header file, included by other library headers.
* Do not attempt to use it directly. @headername{algorithm}
*/
#ifndef _STL_ALGO_H
#define _STL_ALGO_H 1
#include <cstdlib> // for rand
#include <bits/algorithmfwd.h>
#include <bits/stl_heap.h>
#include <bits/stl_tempbuf.h> // for _Temporary_buffer
#ifdef __GXX_EXPERIMENTAL_CXX0X__
#include <random> // for std::uniform_int_distribution
#include <functional> // for std::bind
#endif
// See concept_check.h for the __glibcxx_*_requires macros.
namespace std _GLIBCXX_VISIBILITY(default)
{
_GLIBCXX_BEGIN_NAMESPACE_VERSION
/// Swaps the median value of *__a, *__b and *__c to *__a
template<typename _Iterator>
void
__move_median_first(_Iterator __a, _Iterator __b, _Iterator __c)
{
// concept requirements
__glibcxx_function_requires(_LessThanComparableConcept<
typename iterator_traits<_Iterator>::value_type>)
if (*__a < *__b)
{
if (*__b < *__c)
std::iter_swap(__a, __b);
else if (*__a < *__c)
std::iter_swap(__a, __c);
}
else if (*__a < *__c)
return;
else if (*__b < *__c)
std::iter_swap(__a, __c);
else
std::iter_swap(__a, __b);
}
/// Swaps the median value of *__a, *__b and *__c under __comp to *__a
template<typename _Iterator, typename _Compare>
void
__move_median_first(_Iterator __a, _Iterator __b, _Iterator __c,
_Compare __comp)
{
// concept requirements
__glibcxx_function_requires(_BinaryFunctionConcept<_Compare, bool,
typename iterator_traits<_Iterator>::value_type,
typename iterator_traits<_Iterator>::value_type>)
if (__comp(*__a, *__b))
{
if (__comp(*__b, *__c))
std::iter_swap(__a, __b);
else if (__comp(*__a, *__c))
std::iter_swap(__a, __c);
}
else if (__comp(*__a, *__c))
return;
else if (__comp(*__b, *__c))
std::iter_swap(__a, __c);
else
std::iter_swap(__a, __b);
}
// for_each
/// This is an overload used by find() for the Input Iterator case.
template<typename _InputIterator, typename _Tp>
inline _InputIterator
__find(_InputIterator __first, _InputIterator __last,
const _Tp& __val, input_iterator_tag)
{
while (__first != __last && !(*__first == __val))
++__first;
return __first;
}
/// This is an overload used by find_if() for the Input Iterator case.
template<typename _InputIterator, typename _Predicate>
inline _InputIterator
__find_if(_InputIterator __first, _InputIterator __last,
_Predicate __pred, input_iterator_tag)
{
while (__first != __last && !bool(__pred(*__first)))
++__first;
return __first;
}
/// This is an overload used by find() for the RAI case.
template<typename _RandomAccessIterator, typename _Tp>
_RandomAccessIterator
__find(_RandomAccessIterator __first, _RandomAccessIterator __last,
const _Tp& __val, random_access_iterator_tag)
{
typename iterator_traits<_RandomAccessIterator>::difference_type
__trip_count = (__last - __first) >> 2;
for (; __trip_count > 0; --__trip_count)
{
if (*__first == __val)
return __first;
++__first;
if (*__first == __val)
return __first;
++__first;
if (*__first == __val)
return __first;
++__first;
if (*__first == __val)
return __first;
++__first;
}
switch (__last - __first)
{
case 3:
if (*__first == __val)
return __first;
++__first;
case 2:
if (*__first == __val)
return __first;
++__first;
case 1:
if (*__first == __val)
return __first;
++__first;
case 0:
default:
return __last;
}
}
/// This is an overload used by find_if() for the RAI case.
template<typename _RandomAccessIterator, typename _Predicate>
_RandomAccessIterator
__find_if(_RandomAccessIterator __first, _RandomAccessIterator __last,
_Predicate __pred, random_access_iterator_tag)
{
typename iterator_traits<_RandomAccessIterator>::difference_type
__trip_count = (__last - __first) >> 2;
for (; __trip_count > 0; --__trip_count)
{
if (__pred(*__first))
return __first;
++__first;
if (__pred(*__first))
return __first;
++__first;
if (__pred(*__first))
return __first;
++__first;
if (__pred(*__first))
return __first;
++__first;
}
switch (__last - __first)
{
case 3:
if (__pred(*__first))
return __first;
++__first;
case 2:
if (__pred(*__first))
return __first;
++__first;
case 1:
if (__pred(*__first))
return __first;
++__first;
case 0:
default:
return __last;
}
}
#ifdef __GXX_EXPERIMENTAL_CXX0X__
/// This is an overload used by find_if_not() for the Input Iterator case.
template<typename _InputIterator, typename _Predicate>
inline _InputIterator
__find_if_not(_InputIterator __first, _InputIterator __last,
_Predicate __pred, input_iterator_tag)
{
while (__first != __last && bool(__pred(*__first)))
++__first;
return __first;
}
/// This is an overload used by find_if_not() for the RAI case.
template<typename _RandomAccessIterator, typename _Predicate>
_RandomAccessIterator
__find_if_not(_RandomAccessIterator __first, _RandomAccessIterator __last,
_Predicate __pred, random_access_iterator_tag)
{
typename iterator_traits<_RandomAccessIterator>::difference_type
__trip_count = (__last - __first) >> 2;
for (; __trip_count > 0; --__trip_count)
{
if (!bool(__pred(*__first)))
return __first;
++__first;
if (!bool(__pred(*__first)))
return __first;
++__first;
if (!bool(__pred(*__first)))
return __first;
++__first;
if (!bool(__pred(*__first)))
return __first;
++__first;
}
switch (__last - __first)
{
case 3:
if (!bool(__pred(*__first)))
return __first;
++__first;
case 2:
if (!bool(__pred(*__first)))
return __first;
++__first;
case 1:
if (!bool(__pred(*__first)))
return __first;
++__first;
case 0:
default:
return __last;
}
}
#endif
// set_difference
// set_intersection
// set_symmetric_difference
// set_union
// for_each
// find
// find_if
// find_first_of
// adjacent_find
// count
// count_if
// search
/**
* This is an uglified
* search_n(_ForwardIterator, _ForwardIterator, _Integer, const _Tp&)
* overloaded for forward iterators.
*/
template<typename _ForwardIterator, typename _Integer, typename _Tp>
_ForwardIterator
__search_n(_ForwardIterator __first, _ForwardIterator __last,
_Integer __count, const _Tp& __val,
std::forward_iterator_tag)
{
__first = _GLIBCXX_STD_A::find(__first, __last, __val);
while (__first != __last)
{
typename iterator_traits<_ForwardIterator>::difference_type
__n = __count;
_ForwardIterator __i = __first;
++__i;
while (__i != __last && __n != 1 && *__i == __val)
{
++__i;
--__n;
}
if (__n == 1)
return __first;
if (__i == __last)
return __last;
__first = _GLIBCXX_STD_A::find(++__i, __last, __val);
}
return __last;
}
/**
* This is an uglified
* search_n(_ForwardIterator, _ForwardIterator, _Integer, const _Tp&)
* overloaded for random access iterators.
*/
template<typename _RandomAccessIter, typename _Integer, typename _Tp>
_RandomAccessIter
__search_n(_RandomAccessIter __first, _RandomAccessIter __last,
_Integer __count, const _Tp& __val,
std::random_access_iterator_tag)
{
typedef typename std::iterator_traits<_RandomAccessIter>::difference_type
_DistanceType;
_DistanceType __tailSize = __last - __first;
const _DistanceType __pattSize = __count;
if (__tailSize < __pattSize)
return __last;
const _DistanceType __skipOffset = __pattSize - 1;
_RandomAccessIter __lookAhead = __first + __skipOffset;
__tailSize -= __pattSize;
while (1) // the main loop...
{
// __lookAhead here is always pointing to the last element of next
// possible match.
while (!(*__lookAhead == __val)) // the skip loop...
{
if (__tailSize < __pattSize)
return __last; // Failure
__lookAhead += __pattSize;
__tailSize -= __pattSize;
}
_DistanceType __remainder = __skipOffset;
for (_RandomAccessIter __backTrack = __lookAhead - 1;
*__backTrack == __val; --__backTrack)
{
if (--__remainder == 0)
return (__lookAhead - __skipOffset); // Success
}
if (__remainder > __tailSize)
return __last; // Failure
__lookAhead += __remainder;
__tailSize -= __remainder;
}
}
// search_n
/**
* This is an uglified
* search_n(_ForwardIterator, _ForwardIterator, _Integer, const _Tp&,
* _BinaryPredicate)
* overloaded for forward iterators.
*/
template<typename _ForwardIterator, typename _Integer, typename _Tp,
typename _BinaryPredicate>
_ForwardIterator
__search_n(_ForwardIterator __first, _ForwardIterator __last,
_Integer __count, const _Tp& __val,
_BinaryPredicate __binary_pred, std::forward_iterator_tag)
{
while (__first != __last && !bool(__binary_pred(*__first, __val)))
++__first;
while (__first != __last)
{
typename iterator_traits<_ForwardIterator>::difference_type
__n = __count;
_ForwardIterator __i = __first;
++__i;
while (__i != __last && __n != 1 && bool(__binary_pred(*__i, __val)))
{
++__i;
--__n;
}
if (__n == 1)
return __first;
if (__i == __last)
return __last;
__first = ++__i;
while (__first != __last
&& !bool(__binary_pred(*__first, __val)))
++__first;
}
return __last;
}
/**
* This is an uglified
* search_n(_ForwardIterator, _ForwardIterator, _Integer, const _Tp&,
* _BinaryPredicate)
* overloaded for random access iterators.
*/
template<typename _RandomAccessIter, typename _Integer, typename _Tp,
typename _BinaryPredicate>
_RandomAccessIter
__search_n(_RandomAccessIter __first, _RandomAccessIter __last,
_Integer __count, const _Tp& __val,
_BinaryPredicate __binary_pred, std::random_access_iterator_tag)
{
typedef typename std::iterator_traits<_RandomAccessIter>::difference_type
_DistanceType;
_DistanceType __tailSize = __last - __first;
const _DistanceType __pattSize = __count;
if (__tailSize < __pattSize)
return __last;
const _DistanceType __skipOffset = __pattSize - 1;
_RandomAccessIter __lookAhead = __first + __skipOffset;
__tailSize -= __pattSize;
while (1) // the main loop...
{
// __lookAhead here is always pointing to the last element of next
// possible match.
while (!bool(__binary_pred(*__lookAhead, __val))) // the skip loop...
{
if (__tailSize < __pattSize)
return __last; // Failure
__lookAhead += __pattSize;
__tailSize -= __pattSize;
}
_DistanceType __remainder = __skipOffset;
for (_RandomAccessIter __backTrack = __lookAhead - 1;
__binary_pred(*__backTrack, __val); --__backTrack)
{
if (--__remainder == 0)
return (__lookAhead - __skipOffset); // Success
}
if (__remainder > __tailSize)
return __last; // Failure
__lookAhead += __remainder;
__tailSize -= __remainder;
}
}
// find_end for forward iterators.
template<typename _ForwardIterator1, typename _ForwardIterator2>
_ForwardIterator1
__find_end(_ForwardIterator1 __first1, _ForwardIterator1 __last1,
_ForwardIterator2 __first2, _ForwardIterator2 __last2,
forward_iterator_tag, forward_iterator_tag)
{
if (__first2 == __last2)
return __last1;
else
{
_ForwardIterator1 __result = __last1;
while (1)
{
_ForwardIterator1 __new_result
= _GLIBCXX_STD_A::search(__first1, __last1, __first2, __last2);
if (__new_result == __last1)
return __result;
else
{
__result = __new_result;
__first1 = __new_result;
++__first1;
}
}
}
}
template<typename _ForwardIterator1, typename _ForwardIterator2,
typename _BinaryPredicate>
_ForwardIterator1
__find_end(_ForwardIterator1 __first1, _ForwardIterator1 __last1,
_ForwardIterator2 __first2, _ForwardIterator2 __last2,
forward_iterator_tag, forward_iterator_tag,
_BinaryPredicate __comp)
{
if (__first2 == __last2)
return __last1;
else
{
_ForwardIterator1 __result = __last1;
while (1)
{
_ForwardIterator1 __new_result
= _GLIBCXX_STD_A::search(__first1, __last1, __first2,
__last2, __comp);
if (__new_result == __last1)
return __result;
else
{
__result = __new_result;
__first1 = __new_result;
++__first1;
}
}
}
}
// find_end for bidirectional iterators (much faster).
template<typename _BidirectionalIterator1, typename _BidirectionalIterator2>
_BidirectionalIterator1
__find_end(_BidirectionalIterator1 __first1,
_BidirectionalIterator1 __last1,
_BidirectionalIterator2 __first2,
_BidirectionalIterator2 __last2,
bidirectional_iterator_tag, bidirectional_iterator_tag)
{
// concept requirements
__glibcxx_function_requires(_BidirectionalIteratorConcept<
_BidirectionalIterator1>)
__glibcxx_function_requires(_BidirectionalIteratorConcept<
_BidirectionalIterator2>)
typedef reverse_iterator<_BidirectionalIterator1> _RevIterator1;
typedef reverse_iterator<_BidirectionalIterator2> _RevIterator2;
_RevIterator1 __rlast1(__first1);
_RevIterator2 __rlast2(__first2);
_RevIterator1 __rresult = _GLIBCXX_STD_A::search(_RevIterator1(__last1),
__rlast1,
_RevIterator2(__last2),
__rlast2);
if (__rresult == __rlast1)
return __last1;
else
{
_BidirectionalIterator1 __result = __rresult.base();
std::advance(__result, -std::distance(__first2, __last2));
return __result;
}
}
template<typename _BidirectionalIterator1, typename _BidirectionalIterator2,
typename _BinaryPredicate>
_BidirectionalIterator1
__find_end(_BidirectionalIterator1 __first1,
_BidirectionalIterator1 __last1,
_BidirectionalIterator2 __first2,
_BidirectionalIterator2 __last2,
bidirectional_iterator_tag, bidirectional_iterator_tag,
_BinaryPredicate __comp)
{
// concept requirements
__glibcxx_function_requires(_BidirectionalIteratorConcept<
_BidirectionalIterator1>)
__glibcxx_function_requires(_BidirectionalIteratorConcept<
_BidirectionalIterator2>)
typedef reverse_iterator<_BidirectionalIterator1> _RevIterator1;
typedef reverse_iterator<_BidirectionalIterator2> _RevIterator2;
_RevIterator1 __rlast1(__first1);
_RevIterator2 __rlast2(__first2);
_RevIterator1 __rresult = std::search(_RevIterator1(__last1), __rlast1,
_RevIterator2(__last2), __rlast2,
__comp);
if (__rresult == __rlast1)
return __last1;
else
{
_BidirectionalIterator1 __result = __rresult.base();
std::advance(__result, -std::distance(__first2, __last2));
return __result;
}
}
/**
* @brief Find last matching subsequence in a sequence.
* @ingroup non_mutating_algorithms
* @param first1 Start of range to search.
* @param last1 End of range to search.
* @param first2 Start of sequence to match.
* @param last2 End of sequence to match.
* @return The last iterator @c i in the range
* @p [first1,last1-(last2-first2)) such that @c *(i+N) == @p *(first2+N)
* for each @c N in the range @p [0,last2-first2), or @p last1 if no
* such iterator exists.
*
* Searches the range @p [first1,last1) for a sub-sequence that compares
* equal value-by-value with the sequence given by @p [first2,last2) and
* returns an iterator to the first element of the sub-sequence, or
* @p last1 if the sub-sequence is not found. The sub-sequence will be the
* last such subsequence contained in [first,last1).
*
* Because the sub-sequence must lie completely within the range
* @p [first1,last1) it must start at a position less than
* @p last1-(last2-first2) where @p last2-first2 is the length of the
* sub-sequence.
* This means that the returned iterator @c i will be in the range
* @p [first1,last1-(last2-first2))
*/
template<typename _ForwardIterator1, typename _ForwardIterator2>
inline _ForwardIterator1
find_end(_ForwardIterator1 __first1, _ForwardIterator1 __last1,
_ForwardIterator2 __first2, _ForwardIterator2 __last2)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator1>)
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator2>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_ForwardIterator1>::value_type,
typename iterator_traits<_ForwardIterator2>::value_type>)
__glibcxx_requires_valid_range(__first1, __last1);
__glibcxx_requires_valid_range(__first2, __last2);
return std::__find_end(__first1, __last1, __first2, __last2,
std::__iterator_category(__first1),
std::__iterator_category(__first2));
}
/**
* @brief Find last matching subsequence in a sequence using a predicate.
* @ingroup non_mutating_algorithms
* @param first1 Start of range to search.
* @param last1 End of range to search.
* @param first2 Start of sequence to match.
* @param last2 End of sequence to match.
* @param comp The predicate to use.
* @return The last iterator @c i in the range
* @p [first1,last1-(last2-first2)) such that @c predicate(*(i+N), @p
* (first2+N)) is true for each @c N in the range @p [0,last2-first2), or
* @p last1 if no such iterator exists.
*
* Searches the range @p [first1,last1) for a sub-sequence that compares
* equal value-by-value with the sequence given by @p [first2,last2) using
* comp as a predicate and returns an iterator to the first element of the
* sub-sequence, or @p last1 if the sub-sequence is not found. The
* sub-sequence will be the last such subsequence contained in
* [first,last1).
*
* Because the sub-sequence must lie completely within the range
* @p [first1,last1) it must start at a position less than
* @p last1-(last2-first2) where @p last2-first2 is the length of the
* sub-sequence.
* This means that the returned iterator @c i will be in the range
* @p [first1,last1-(last2-first2))
*/
template<typename _ForwardIterator1, typename _ForwardIterator2,
typename _BinaryPredicate>
inline _ForwardIterator1
find_end(_ForwardIterator1 __first1, _ForwardIterator1 __last1,
_ForwardIterator2 __first2, _ForwardIterator2 __last2,
_BinaryPredicate __comp)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator1>)
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_BinaryPredicate,
typename iterator_traits<_ForwardIterator1>::value_type,
typename iterator_traits<_ForwardIterator2>::value_type>)
__glibcxx_requires_valid_range(__first1, __last1);
__glibcxx_requires_valid_range(__first2, __last2);
return std::__find_end(__first1, __last1, __first2, __last2,
std::__iterator_category(__first1),
std::__iterator_category(__first2),
__comp);
}
#ifdef __GXX_EXPERIMENTAL_CXX0X__
/**
* @brief Checks that a predicate is true for all the elements
* of a sequence.
* @ingroup non_mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param pred A predicate.
* @return True if the check is true, false otherwise.
*
* Returns true if @p pred is true for each element in the range
* @p [first,last), and false otherwise.
*/
template<typename _InputIterator, typename _Predicate>
inline bool
all_of(_InputIterator __first, _InputIterator __last, _Predicate __pred)
{ return __last == std::find_if_not(__first, __last, __pred); }
/**
* @brief Checks that a predicate is false for all the elements
* of a sequence.
* @ingroup non_mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param pred A predicate.
* @return True if the check is true, false otherwise.
*
* Returns true if @p pred is false for each element in the range
* @p [first,last), and false otherwise.
*/
template<typename _InputIterator, typename _Predicate>
inline bool
none_of(_InputIterator __first, _InputIterator __last, _Predicate __pred)
{ return __last == _GLIBCXX_STD_A::find_if(__first, __last, __pred); }
/**
* @brief Checks that a predicate is false for at least an element
* of a sequence.
* @ingroup non_mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param pred A predicate.
* @return True if the check is true, false otherwise.
*
* Returns true if an element exists in the range @p [first,last) such that
* @p pred is true, and false otherwise.
*/
template<typename _InputIterator, typename _Predicate>
inline bool
any_of(_InputIterator __first, _InputIterator __last, _Predicate __pred)
{ return !std::none_of(__first, __last, __pred); }
/**
* @brief Find the first element in a sequence for which a
* predicate is false.
* @ingroup non_mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param pred A predicate.
* @return The first iterator @c i in the range @p [first,last)
* such that @p pred(*i) is false, or @p last if no such iterator exists.
*/
template<typename _InputIterator, typename _Predicate>
inline _InputIterator
find_if_not(_InputIterator __first, _InputIterator __last,
_Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
return std::__find_if_not(__first, __last, __pred,
std::__iterator_category(__first));
}
/**
* @brief Checks whether the sequence is partitioned.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param pred A predicate.
* @return True if the range @p [first,last) is partioned by @p pred,
* i.e. if all elements that satisfy @p pred appear before those that
* do not.
*/
template<typename _InputIterator, typename _Predicate>
inline bool
is_partitioned(_InputIterator __first, _InputIterator __last,
_Predicate __pred)
{
__first = std::find_if_not(__first, __last, __pred);
return std::none_of(__first, __last, __pred);
}
/**
* @brief Find the partition point of a partitioned range.
* @ingroup mutating_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param pred A predicate.
* @return An iterator @p mid such that @p all_of(first, mid, pred)
* and @p none_of(mid, last, pred) are both true.
*/
template<typename _ForwardIterator, typename _Predicate>
_ForwardIterator
partition_point(_ForwardIterator __first, _ForwardIterator __last,
_Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_ForwardIterator>::value_type>)
// A specific debug-mode test will be necessary...
__glibcxx_requires_valid_range(__first, __last);
typedef typename iterator_traits<_ForwardIterator>::difference_type
_DistanceType;
_DistanceType __len = std::distance(__first, __last);
_DistanceType __half;
_ForwardIterator __middle;
while (__len > 0)
{
__half = __len >> 1;
__middle = __first;
std::advance(__middle, __half);
if (__pred(*__middle))
{
__first = __middle;
++__first;
__len = __len - __half - 1;
}
else
__len = __half;
}
return __first;
}
#endif
/**
* @brief Copy a sequence, removing elements of a given value.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param result An output iterator.
* @param value The value to be removed.
* @return An iterator designating the end of the resulting sequence.
*
* Copies each element in the range @p [first,last) not equal to @p value
* to the range beginning at @p result.
* remove_copy() is stable, so the relative order of elements that are
* copied is unchanged.
*/
template<typename _InputIterator, typename _OutputIterator, typename _Tp>
_OutputIterator
remove_copy(_InputIterator __first, _InputIterator __last,
_OutputIterator __result, const _Tp& __value)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_InputIterator>::value_type, _Tp>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first)
if (!(*__first == __value))
{
*__result = *__first;
++__result;
}
return __result;
}
/**
* @brief Copy a sequence, removing elements for which a predicate is true.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param result An output iterator.
* @param pred A predicate.
* @return An iterator designating the end of the resulting sequence.
*
* Copies each element in the range @p [first,last) for which
* @p pred returns false to the range beginning at @p result.
*
* remove_copy_if() is stable, so the relative order of elements that are
* copied is unchanged.
*/
template<typename _InputIterator, typename _OutputIterator,
typename _Predicate>
_OutputIterator
remove_copy_if(_InputIterator __first, _InputIterator __last,
_OutputIterator __result, _Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first)
if (!bool(__pred(*__first)))
{
*__result = *__first;
++__result;
}
return __result;
}
#ifdef __GXX_EXPERIMENTAL_CXX0X__
/**
* @brief Copy the elements of a sequence for which a predicate is true.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param result An output iterator.
* @param pred A predicate.
* @return An iterator designating the end of the resulting sequence.
*
* Copies each element in the range @p [first,last) for which
* @p pred returns true to the range beginning at @p result.
*
* copy_if() is stable, so the relative order of elements that are
* copied is unchanged.
*/
template<typename _InputIterator, typename _OutputIterator,
typename _Predicate>
_OutputIterator
copy_if(_InputIterator __first, _InputIterator __last,
_OutputIterator __result, _Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first)
if (__pred(*__first))
{
*__result = *__first;
++__result;
}
return __result;
}
template<typename _InputIterator, typename _Size, typename _OutputIterator>
_OutputIterator
__copy_n(_InputIterator __first, _Size __n,
_OutputIterator __result, input_iterator_tag)
{
for (; __n > 0; --__n)
{
*__result = *__first;
++__first;
++__result;
}
return __result;
}
template<typename _RandomAccessIterator, typename _Size,
typename _OutputIterator>
inline _OutputIterator
__copy_n(_RandomAccessIterator __first, _Size __n,
_OutputIterator __result, random_access_iterator_tag)
{ return std::copy(__first, __first + __n, __result); }
/**
* @brief Copies the range [first,first+n) into [result,result+n).
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param n The number of elements to copy.
* @param result An output iterator.
* @return result+n.
*
* This inline function will boil down to a call to @c memmove whenever
* possible. Failing that, if random access iterators are passed, then the
* loop count will be known (and therefore a candidate for compiler
* optimizations such as unrolling).
*/
template<typename _InputIterator, typename _Size, typename _OutputIterator>
inline _OutputIterator
copy_n(_InputIterator __first, _Size __n, _OutputIterator __result)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_InputIterator>::value_type>)
return std::__copy_n(__first, __n, __result,
std::__iterator_category(__first));
}
/**
* @brief Copy the elements of a sequence to separate output sequences
* depending on the truth value of a predicate.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param out_true An output iterator.
* @param out_false An output iterator.
* @param pred A predicate.
* @return A pair designating the ends of the resulting sequences.
*
* Copies each element in the range @p [first,last) for which
* @p pred returns true to the range beginning at @p out_true
* and each element for which @p pred returns false to @p out_false.
*/
template<typename _InputIterator, typename _OutputIterator1,
typename _OutputIterator2, typename _Predicate>
pair<_OutputIterator1, _OutputIterator2>
partition_copy(_InputIterator __first, _InputIterator __last,
_OutputIterator1 __out_true, _OutputIterator2 __out_false,
_Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator1,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator2,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first)
if (__pred(*__first))
{
*__out_true = *__first;
++__out_true;
}
else
{
*__out_false = *__first;
++__out_false;
}
return pair<_OutputIterator1, _OutputIterator2>(__out_true, __out_false);
}
#endif
/**
* @brief Remove elements from a sequence.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param value The value to be removed.
* @return An iterator designating the end of the resulting sequence.
*
* All elements equal to @p value are removed from the range
* @p [first,last).
*
* remove() is stable, so the relative order of elements that are
* not removed is unchanged.
*
* Elements between the end of the resulting sequence and @p last
* are still present, but their value is unspecified.
*/
template<typename _ForwardIterator, typename _Tp>
_ForwardIterator
remove(_ForwardIterator __first, _ForwardIterator __last,
const _Tp& __value)
{
// concept requirements
__glibcxx_function_requires(_Mutable_ForwardIteratorConcept<
_ForwardIterator>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_ForwardIterator>::value_type, _Tp>)
__glibcxx_requires_valid_range(__first, __last);
__first = _GLIBCXX_STD_A::find(__first, __last, __value);
if(__first == __last)
return __first;
_ForwardIterator __result = __first;
++__first;
for(; __first != __last; ++__first)
if(!(*__first == __value))
{
*__result = _GLIBCXX_MOVE(*__first);
++__result;
}
return __result;
}
/**
* @brief Remove elements from a sequence using a predicate.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param pred A predicate.
* @return An iterator designating the end of the resulting sequence.
*
* All elements for which @p pred returns true are removed from the range
* @p [first,last).
*
* remove_if() is stable, so the relative order of elements that are
* not removed is unchanged.
*
* Elements between the end of the resulting sequence and @p last
* are still present, but their value is unspecified.
*/
template<typename _ForwardIterator, typename _Predicate>
_ForwardIterator
remove_if(_ForwardIterator __first, _ForwardIterator __last,
_Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_Mutable_ForwardIteratorConcept<
_ForwardIterator>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
__first = _GLIBCXX_STD_A::find_if(__first, __last, __pred);
if(__first == __last)
return __first;
_ForwardIterator __result = __first;
++__first;
for(; __first != __last; ++__first)
if(!bool(__pred(*__first)))
{
*__result = _GLIBCXX_MOVE(*__first);
++__result;
}
return __result;
}
/**
* @brief Remove consecutive duplicate values from a sequence.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @return An iterator designating the end of the resulting sequence.
*
* Removes all but the first element from each group of consecutive
* values that compare equal.
* unique() is stable, so the relative order of elements that are
* not removed is unchanged.
* Elements between the end of the resulting sequence and @p last
* are still present, but their value is unspecified.
*/
template<typename _ForwardIterator>
_ForwardIterator
unique(_ForwardIterator __first, _ForwardIterator __last)
{
// concept requirements
__glibcxx_function_requires(_Mutable_ForwardIteratorConcept<
_ForwardIterator>)
__glibcxx_function_requires(_EqualityComparableConcept<
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
// Skip the beginning, if already unique.
__first = _GLIBCXX_STD_A::adjacent_find(__first, __last);
if (__first == __last)
return __last;
// Do the real copy work.
_ForwardIterator __dest = __first;
++__first;
while (++__first != __last)
if (!(*__dest == *__first))
*++__dest = _GLIBCXX_MOVE(*__first);
return ++__dest;
}
/**
* @brief Remove consecutive values from a sequence using a predicate.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param binary_pred A binary predicate.
* @return An iterator designating the end of the resulting sequence.
*
* Removes all but the first element from each group of consecutive
* values for which @p binary_pred returns true.
* unique() is stable, so the relative order of elements that are
* not removed is unchanged.
* Elements between the end of the resulting sequence and @p last
* are still present, but their value is unspecified.
*/
template<typename _ForwardIterator, typename _BinaryPredicate>
_ForwardIterator
unique(_ForwardIterator __first, _ForwardIterator __last,
_BinaryPredicate __binary_pred)
{
// concept requirements
__glibcxx_function_requires(_Mutable_ForwardIteratorConcept<
_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_BinaryPredicate,
typename iterator_traits<_ForwardIterator>::value_type,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
// Skip the beginning, if already unique.
__first = _GLIBCXX_STD_A::adjacent_find(__first, __last, __binary_pred);
if (__first == __last)
return __last;
// Do the real copy work.
_ForwardIterator __dest = __first;
++__first;
while (++__first != __last)
if (!bool(__binary_pred(*__dest, *__first)))
*++__dest = _GLIBCXX_MOVE(*__first);
return ++__dest;
}
/**
* This is an uglified unique_copy(_InputIterator, _InputIterator,
* _OutputIterator)
* overloaded for forward iterators and output iterator as result.
*/
template<typename _ForwardIterator, typename _OutputIterator>
_OutputIterator
__unique_copy(_ForwardIterator __first, _ForwardIterator __last,
_OutputIterator __result,
forward_iterator_tag, output_iterator_tag)
{
// concept requirements -- taken care of in dispatching function
_ForwardIterator __next = __first;
*__result = *__first;
while (++__next != __last)
if (!(*__first == *__next))
{
__first = __next;
*++__result = *__first;
}
return ++__result;
}
/**
* This is an uglified unique_copy(_InputIterator, _InputIterator,
* _OutputIterator)
* overloaded for input iterators and output iterator as result.
*/
template<typename _InputIterator, typename _OutputIterator>
_OutputIterator
__unique_copy(_InputIterator __first, _InputIterator __last,
_OutputIterator __result,
input_iterator_tag, output_iterator_tag)
{
// concept requirements -- taken care of in dispatching function
typename iterator_traits<_InputIterator>::value_type __value = *__first;
*__result = __value;
while (++__first != __last)
if (!(__value == *__first))
{
__value = *__first;
*++__result = __value;
}
return ++__result;
}
/**
* This is an uglified unique_copy(_InputIterator, _InputIterator,
* _OutputIterator)
* overloaded for input iterators and forward iterator as result.
*/
template<typename _InputIterator, typename _ForwardIterator>
_ForwardIterator
__unique_copy(_InputIterator __first, _InputIterator __last,
_ForwardIterator __result,
input_iterator_tag, forward_iterator_tag)
{
// concept requirements -- taken care of in dispatching function
*__result = *__first;
while (++__first != __last)
if (!(*__result == *__first))
*++__result = *__first;
return ++__result;
}
/**
* This is an uglified
* unique_copy(_InputIterator, _InputIterator, _OutputIterator,
* _BinaryPredicate)
* overloaded for forward iterators and output iterator as result.
*/
template<typename _ForwardIterator, typename _OutputIterator,
typename _BinaryPredicate>
_OutputIterator
__unique_copy(_ForwardIterator __first, _ForwardIterator __last,
_OutputIterator __result, _BinaryPredicate __binary_pred,
forward_iterator_tag, output_iterator_tag)
{
// concept requirements -- iterators already checked
__glibcxx_function_requires(_BinaryPredicateConcept<_BinaryPredicate,
typename iterator_traits<_ForwardIterator>::value_type,
typename iterator_traits<_ForwardIterator>::value_type>)
_ForwardIterator __next = __first;
*__result = *__first;
while (++__next != __last)
if (!bool(__binary_pred(*__first, *__next)))
{
__first = __next;
*++__result = *__first;
}
return ++__result;
}
/**
* This is an uglified
* unique_copy(_InputIterator, _InputIterator, _OutputIterator,
* _BinaryPredicate)
* overloaded for input iterators and output iterator as result.
*/
template<typename _InputIterator, typename _OutputIterator,
typename _BinaryPredicate>
_OutputIterator
__unique_copy(_InputIterator __first, _InputIterator __last,
_OutputIterator __result, _BinaryPredicate __binary_pred,
input_iterator_tag, output_iterator_tag)
{
// concept requirements -- iterators already checked
__glibcxx_function_requires(_BinaryPredicateConcept<_BinaryPredicate,
typename iterator_traits<_InputIterator>::value_type,
typename iterator_traits<_InputIterator>::value_type>)
typename iterator_traits<_InputIterator>::value_type __value = *__first;
*__result = __value;
while (++__first != __last)
if (!bool(__binary_pred(__value, *__first)))
{
__value = *__first;
*++__result = __value;
}
return ++__result;
}
/**
* This is an uglified
* unique_copy(_InputIterator, _InputIterator, _OutputIterator,
* _BinaryPredicate)
* overloaded for input iterators and forward iterator as result.
*/
template<typename _InputIterator, typename _ForwardIterator,
typename _BinaryPredicate>
_ForwardIterator
__unique_copy(_InputIterator __first, _InputIterator __last,
_ForwardIterator __result, _BinaryPredicate __binary_pred,
input_iterator_tag, forward_iterator_tag)
{
// concept requirements -- iterators already checked
__glibcxx_function_requires(_BinaryPredicateConcept<_BinaryPredicate,
typename iterator_traits<_ForwardIterator>::value_type,
typename iterator_traits<_InputIterator>::value_type>)
*__result = *__first;
while (++__first != __last)
if (!bool(__binary_pred(*__result, *__first)))
*++__result = *__first;
return ++__result;
}
/**
* This is an uglified reverse(_BidirectionalIterator,
* _BidirectionalIterator)
* overloaded for bidirectional iterators.
*/
template<typename _BidirectionalIterator>
void
__reverse(_BidirectionalIterator __first, _BidirectionalIterator __last,
bidirectional_iterator_tag)
{
while (true)
if (__first == __last || __first == --__last)
return;
else
{
std::iter_swap(__first, __last);
++__first;
}
}
/**
* This is an uglified reverse(_BidirectionalIterator,
* _BidirectionalIterator)
* overloaded for random access iterators.
*/
template<typename _RandomAccessIterator>
void
__reverse(_RandomAccessIterator __first, _RandomAccessIterator __last,
random_access_iterator_tag)
{
if (__first == __last)
return;
--__last;
while (__first < __last)
{
std::iter_swap(__first, __last);
++__first;
--__last;
}
}
/**
* @brief Reverse a sequence.
* @ingroup mutating_algorithms
* @param first A bidirectional iterator.
* @param last A bidirectional iterator.
* @return reverse() returns no value.
*
* Reverses the order of the elements in the range @p [first,last),
* so that the first element becomes the last etc.
* For every @c i such that @p 0<=i<=(last-first)/2), @p reverse()
* swaps @p *(first+i) and @p *(last-(i+1))
*/
template<typename _BidirectionalIterator>
inline void
reverse(_BidirectionalIterator __first, _BidirectionalIterator __last)
{
// concept requirements
__glibcxx_function_requires(_Mutable_BidirectionalIteratorConcept<
_BidirectionalIterator>)
__glibcxx_requires_valid_range(__first, __last);
std::__reverse(__first, __last, std::__iterator_category(__first));
}
/**
* @brief Copy a sequence, reversing its elements.
* @ingroup mutating_algorithms
* @param first A bidirectional iterator.
* @param last A bidirectional iterator.
* @param result An output iterator.
* @return An iterator designating the end of the resulting sequence.
*
* Copies the elements in the range @p [first,last) to the range
* @p [result,result+(last-first)) such that the order of the
* elements is reversed.
* For every @c i such that @p 0<=i<=(last-first), @p reverse_copy()
* performs the assignment @p *(result+(last-first)-i) = *(first+i).
* The ranges @p [first,last) and @p [result,result+(last-first))
* must not overlap.
*/
template<typename _BidirectionalIterator, typename _OutputIterator>
_OutputIterator
reverse_copy(_BidirectionalIterator __first, _BidirectionalIterator __last,
_OutputIterator __result)
{
// concept requirements
__glibcxx_function_requires(_BidirectionalIteratorConcept<
_BidirectionalIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_BidirectionalIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
while (__first != __last)
{
--__last;
*__result = *__last;
++__result;
}
return __result;
}
/**
* This is a helper function for the rotate algorithm specialized on RAIs.
* It returns the greatest common divisor of two integer values.
*/
template<typename _EuclideanRingElement>
_EuclideanRingElement
__gcd(_EuclideanRingElement __m, _EuclideanRingElement __n)
{
while (__n != 0)
{
_EuclideanRingElement __t = __m % __n;
__m = __n;
__n = __t;
}
return __m;
}
/// This is a helper function for the rotate algorithm.
template<typename _ForwardIterator>
void
__rotate(_ForwardIterator __first,
_ForwardIterator __middle,
_ForwardIterator __last,
forward_iterator_tag)
{
if (__first == __middle || __last == __middle)
return;
_ForwardIterator __first2 = __middle;
do
{
std::iter_swap(__first, __first2);
++__first;
++__first2;
if (__first == __middle)
__middle = __first2;
}
while (__first2 != __last);
__first2 = __middle;
while (__first2 != __last)
{
std::iter_swap(__first, __first2);
++__first;
++__first2;
if (__first == __middle)
__middle = __first2;
else if (__first2 == __last)
__first2 = __middle;
}
}
/// This is a helper function for the rotate algorithm.
template<typename _BidirectionalIterator>
void
__rotate(_BidirectionalIterator __first,
_BidirectionalIterator __middle,
_BidirectionalIterator __last,
bidirectional_iterator_tag)
{
// concept requirements
__glibcxx_function_requires(_Mutable_BidirectionalIteratorConcept<
_BidirectionalIterator>)
if (__first == __middle || __last == __middle)
return;
std::__reverse(__first, __middle, bidirectional_iterator_tag());
std::__reverse(__middle, __last, bidirectional_iterator_tag());
while (__first != __middle && __middle != __last)
{
std::iter_swap(__first, --__last);
++__first;
}
if (__first == __middle)
std::__reverse(__middle, __last, bidirectional_iterator_tag());
else
std::__reverse(__first, __middle, bidirectional_iterator_tag());
}
/// This is a helper function for the rotate algorithm.
template<typename _RandomAccessIterator>
void
__rotate(_RandomAccessIterator __first,
_RandomAccessIterator __middle,
_RandomAccessIterator __last,
random_access_iterator_tag)
{
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
if (__first == __middle || __last == __middle)
return;
typedef typename iterator_traits<_RandomAccessIterator>::difference_type
_Distance;
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
_Distance __n = __last - __first;
_Distance __k = __middle - __first;
if (__k == __n - __k)
{
std::swap_ranges(__first, __middle, __middle);
return;
}
_RandomAccessIterator __p = __first;
for (;;)
{
if (__k < __n - __k)
{
if (__is_pod(_ValueType) && __k == 1)
{
_ValueType __t = _GLIBCXX_MOVE(*__p);
_GLIBCXX_MOVE3(__p + 1, __p + __n, __p);
*(__p + __n - 1) = _GLIBCXX_MOVE(__t);
return;
}
_RandomAccessIterator __q = __p + __k;
for (_Distance __i = 0; __i < __n - __k; ++ __i)
{
std::iter_swap(__p, __q);
++__p;
++__q;
}
__n %= __k;
if (__n == 0)
return;
std::swap(__n, __k);
__k = __n - __k;
}
else
{
__k = __n - __k;
if (__is_pod(_ValueType) && __k == 1)
{
_ValueType __t = _GLIBCXX_MOVE(*(__p + __n - 1));
_GLIBCXX_MOVE_BACKWARD3(__p, __p + __n - 1, __p + __n);
*__p = _GLIBCXX_MOVE(__t);
return;
}
_RandomAccessIterator __q = __p + __n;
__p = __q - __k;
for (_Distance __i = 0; __i < __n - __k; ++ __i)
{
--__p;
--__q;
std::iter_swap(__p, __q);
}
__n %= __k;
if (__n == 0)
return;
std::swap(__n, __k);
}
}
}
/**
* @brief Rotate the elements of a sequence.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param middle A forward iterator.
* @param last A forward iterator.
* @return Nothing.
*
* Rotates the elements of the range @p [first,last) by @p (middle-first)
* positions so that the element at @p middle is moved to @p first, the
* element at @p middle+1 is moved to @first+1 and so on for each element
* in the range @p [first,last).
*
* This effectively swaps the ranges @p [first,middle) and
* @p [middle,last).
*
* Performs @p *(first+(n+(last-middle))%(last-first))=*(first+n) for
* each @p n in the range @p [0,last-first).
*/
template<typename _ForwardIterator>
inline void
rotate(_ForwardIterator __first, _ForwardIterator __middle,
_ForwardIterator __last)
{
// concept requirements
__glibcxx_function_requires(_Mutable_ForwardIteratorConcept<
_ForwardIterator>)
__glibcxx_requires_valid_range(__first, __middle);
__glibcxx_requires_valid_range(__middle, __last);
typedef typename iterator_traits<_ForwardIterator>::iterator_category
_IterType;
std::__rotate(__first, __middle, __last, _IterType());
}
/**
* @brief Copy a sequence, rotating its elements.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param middle A forward iterator.
* @param last A forward iterator.
* @param result An output iterator.
* @return An iterator designating the end of the resulting sequence.
*
* Copies the elements of the range @p [first,last) to the range
* beginning at @result, rotating the copied elements by @p (middle-first)
* positions so that the element at @p middle is moved to @p result, the
* element at @p middle+1 is moved to @result+1 and so on for each element
* in the range @p [first,last).
*
* Performs @p *(result+(n+(last-middle))%(last-first))=*(first+n) for
* each @p n in the range @p [0,last-first).
*/
template<typename _ForwardIterator, typename _OutputIterator>
_OutputIterator
rotate_copy(_ForwardIterator __first, _ForwardIterator __middle,
_ForwardIterator __last, _OutputIterator __result)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __middle);
__glibcxx_requires_valid_range(__middle, __last);
return std::copy(__first, __middle,
std::copy(__middle, __last, __result));
}
/// This is a helper function...
template<typename _ForwardIterator, typename _Predicate>
_ForwardIterator
__partition(_ForwardIterator __first, _ForwardIterator __last,
_Predicate __pred, forward_iterator_tag)
{
if (__first == __last)
return __first;
while (__pred(*__first))
if (++__first == __last)
return __first;
_ForwardIterator __next = __first;
while (++__next != __last)
if (__pred(*__next))
{
std::iter_swap(__first, __next);
++__first;
}
return __first;
}
/// This is a helper function...
template<typename _BidirectionalIterator, typename _Predicate>
_BidirectionalIterator
__partition(_BidirectionalIterator __first, _BidirectionalIterator __last,
_Predicate __pred, bidirectional_iterator_tag)
{
while (true)
{
while (true)
if (__first == __last)
return __first;
else if (__pred(*__first))
++__first;
else
break;
--__last;
while (true)
if (__first == __last)
return __first;
else if (!bool(__pred(*__last)))
--__last;
else
break;
std::iter_swap(__first, __last);
++__first;
}
}
// partition
/// This is a helper function...
template<typename _ForwardIterator, typename _Predicate, typename _Distance>
_ForwardIterator
__inplace_stable_partition(_ForwardIterator __first,
_ForwardIterator __last,
_Predicate __pred, _Distance __len)
{
if (__len == 1)
return __pred(*__first) ? __last : __first;
_ForwardIterator __middle = __first;
std::advance(__middle, __len / 2);
_ForwardIterator __begin = std::__inplace_stable_partition(__first,
__middle,
__pred,
__len / 2);
_ForwardIterator __end = std::__inplace_stable_partition(__middle, __last,
__pred,
__len
- __len / 2);
std::rotate(__begin, __middle, __end);
std::advance(__begin, std::distance(__middle, __end));
return __begin;
}
/// This is a helper function...
template<typename _ForwardIterator, typename _Pointer, typename _Predicate,
typename _Distance>
_ForwardIterator
__stable_partition_adaptive(_ForwardIterator __first,
_ForwardIterator __last,
_Predicate __pred, _Distance __len,
_Pointer __buffer,
_Distance __buffer_size)
{
if (__len <= __buffer_size)
{
_ForwardIterator __result1 = __first;
_Pointer __result2 = __buffer;
for (; __first != __last; ++__first)
if (__pred(*__first))
{
*__result1 = _GLIBCXX_MOVE(*__first);
++__result1;
}
else
{
*__result2 = _GLIBCXX_MOVE(*__first);
++__result2;
}
_GLIBCXX_MOVE3(__buffer, __result2, __result1);
return __result1;
}
else
{
_ForwardIterator __middle = __first;
std::advance(__middle, __len / 2);
_ForwardIterator __begin =
std::__stable_partition_adaptive(__first, __middle, __pred,
__len / 2, __buffer,
__buffer_size);
_ForwardIterator __end =
std::__stable_partition_adaptive(__middle, __last, __pred,
__len - __len / 2,
__buffer, __buffer_size);
std::rotate(__begin, __middle, __end);
std::advance(__begin, std::distance(__middle, __end));
return __begin;
}
}
/**
* @brief Move elements for which a predicate is true to the beginning
* of a sequence, preserving relative ordering.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param pred A predicate functor.
* @return An iterator @p middle such that @p pred(i) is true for each
* iterator @p i in the range @p [first,middle) and false for each @p i
* in the range @p [middle,last).
*
* Performs the same function as @p partition() with the additional
* guarantee that the relative ordering of elements in each group is
* preserved, so any two elements @p x and @p y in the range
* @p [first,last) such that @p pred(x)==pred(y) will have the same
* relative ordering after calling @p stable_partition().
*/
template<typename _ForwardIterator, typename _Predicate>
_ForwardIterator
stable_partition(_ForwardIterator __first, _ForwardIterator __last,
_Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_Mutable_ForwardIteratorConcept<
_ForwardIterator>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __first;
else
{
typedef typename iterator_traits<_ForwardIterator>::value_type
_ValueType;
typedef typename iterator_traits<_ForwardIterator>::difference_type
_DistanceType;
_Temporary_buffer<_ForwardIterator, _ValueType> __buf(__first,
__last);
if (__buf.size() > 0)
return
std::__stable_partition_adaptive(__first, __last, __pred,
_DistanceType(__buf.requested_size()),
__buf.begin(),
_DistanceType(__buf.size()));
else
return
std::__inplace_stable_partition(__first, __last, __pred,
_DistanceType(__buf.requested_size()));
}
}
/// This is a helper function for the sort routines.
template<typename _RandomAccessIterator>
void
__heap_select(_RandomAccessIterator __first,
_RandomAccessIterator __middle,
_RandomAccessIterator __last)
{
std::make_heap(__first, __middle);
for (_RandomAccessIterator __i = __middle; __i < __last; ++__i)
if (*__i < *__first)
std::__pop_heap(__first, __middle, __i);
}
/// This is a helper function for the sort routines.
template<typename _RandomAccessIterator, typename _Compare>
void
__heap_select(_RandomAccessIterator __first,
_RandomAccessIterator __middle,
_RandomAccessIterator __last, _Compare __comp)
{
std::make_heap(__first, __middle, __comp);
for (_RandomAccessIterator __i = __middle; __i < __last; ++__i)
if (__comp(*__i, *__first))
std::__pop_heap(__first, __middle, __i, __comp);
}
// partial_sort
/**
* @brief Copy the smallest elements of a sequence.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param result_first A random-access iterator.
* @param result_last Another random-access iterator.
* @return An iterator indicating the end of the resulting sequence.
*
* Copies and sorts the smallest N values from the range @p [first,last)
* to the range beginning at @p result_first, where the number of
* elements to be copied, @p N, is the smaller of @p (last-first) and
* @p (result_last-result_first).
* After the sort if @p i and @j are iterators in the range
* @p [result_first,result_first+N) such that @i precedes @j then
* @p *j<*i is false.
* The value returned is @p result_first+N.
*/
template<typename _InputIterator, typename _RandomAccessIterator>
_RandomAccessIterator
partial_sort_copy(_InputIterator __first, _InputIterator __last,
_RandomAccessIterator __result_first,
_RandomAccessIterator __result_last)
{
typedef typename iterator_traits<_InputIterator>::value_type
_InputValueType;
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_OutputValueType;
typedef typename iterator_traits<_RandomAccessIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_ConvertibleConcept<_InputValueType,
_OutputValueType>)
__glibcxx_function_requires(_LessThanOpConcept<_InputValueType,
_OutputValueType>)
__glibcxx_function_requires(_LessThanComparableConcept<_OutputValueType>)
__glibcxx_requires_valid_range(__first, __last);
__glibcxx_requires_valid_range(__result_first, __result_last);
if (__result_first == __result_last)
return __result_last;
_RandomAccessIterator __result_real_last = __result_first;
while(__first != __last && __result_real_last != __result_last)
{
*__result_real_last = *__first;
++__result_real_last;
++__first;
}
std::make_heap(__result_first, __result_real_last);
while (__first != __last)
{
if (*__first < *__result_first)
std::__adjust_heap(__result_first, _DistanceType(0),
_DistanceType(__result_real_last
- __result_first),
_InputValueType(*__first));
++__first;
}
std::sort_heap(__result_first, __result_real_last);
return __result_real_last;
}
/**
* @brief Copy the smallest elements of a sequence using a predicate for
* comparison.
* @ingroup sorting_algorithms
* @param first An input iterator.
* @param last Another input iterator.
* @param result_first A random-access iterator.
* @param result_last Another random-access iterator.
* @param comp A comparison functor.
* @return An iterator indicating the end of the resulting sequence.
*
* Copies and sorts the smallest N values from the range @p [first,last)
* to the range beginning at @p result_first, where the number of
* elements to be copied, @p N, is the smaller of @p (last-first) and
* @p (result_last-result_first).
* After the sort if @p i and @j are iterators in the range
* @p [result_first,result_first+N) such that @i precedes @j then
* @p comp(*j,*i) is false.
* The value returned is @p result_first+N.
*/
template<typename _InputIterator, typename _RandomAccessIterator, typename _Compare>
_RandomAccessIterator
partial_sort_copy(_InputIterator __first, _InputIterator __last,
_RandomAccessIterator __result_first,
_RandomAccessIterator __result_last,
_Compare __comp)
{
typedef typename iterator_traits<_InputIterator>::value_type
_InputValueType;
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_OutputValueType;
typedef typename iterator_traits<_RandomAccessIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_function_requires(_ConvertibleConcept<_InputValueType,
_OutputValueType>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_InputValueType, _OutputValueType>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_OutputValueType, _OutputValueType>)
__glibcxx_requires_valid_range(__first, __last);
__glibcxx_requires_valid_range(__result_first, __result_last);
if (__result_first == __result_last)
return __result_last;
_RandomAccessIterator __result_real_last = __result_first;
while(__first != __last && __result_real_last != __result_last)
{
*__result_real_last = *__first;
++__result_real_last;
++__first;
}
std::make_heap(__result_first, __result_real_last, __comp);
while (__first != __last)
{
if (__comp(*__first, *__result_first))
std::__adjust_heap(__result_first, _DistanceType(0),
_DistanceType(__result_real_last
- __result_first),
_InputValueType(*__first),
__comp);
++__first;
}
std::sort_heap(__result_first, __result_real_last, __comp);
return __result_real_last;
}
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator>
void
__unguarded_linear_insert(_RandomAccessIterator __last)
{
typename iterator_traits<_RandomAccessIterator>::value_type
__val = _GLIBCXX_MOVE(*__last);
_RandomAccessIterator __next = __last;
--__next;
while (__val < *__next)
{
*__last = _GLIBCXX_MOVE(*__next);
__last = __next;
--__next;
}
*__last = _GLIBCXX_MOVE(__val);
}
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator, typename _Compare>
void
__unguarded_linear_insert(_RandomAccessIterator __last,
_Compare __comp)
{
typename iterator_traits<_RandomAccessIterator>::value_type
__val = _GLIBCXX_MOVE(*__last);
_RandomAccessIterator __next = __last;
--__next;
while (__comp(__val, *__next))
{
*__last = _GLIBCXX_MOVE(*__next);
__last = __next;
--__next;
}
*__last = _GLIBCXX_MOVE(__val);
}
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator>
void
__insertion_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last)
{
if (__first == __last)
return;
for (_RandomAccessIterator __i = __first + 1; __i != __last; ++__i)
{
if (*__i < *__first)
{
typename iterator_traits<_RandomAccessIterator>::value_type
__val = _GLIBCXX_MOVE(*__i);
_GLIBCXX_MOVE_BACKWARD3(__first, __i, __i + 1);
*__first = _GLIBCXX_MOVE(__val);
}
else
std::__unguarded_linear_insert(__i);
}
}
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator, typename _Compare>
void
__insertion_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last, _Compare __comp)
{
if (__first == __last) return;
for (_RandomAccessIterator __i = __first + 1; __i != __last; ++__i)
{
if (__comp(*__i, *__first))
{
typename iterator_traits<_RandomAccessIterator>::value_type
__val = _GLIBCXX_MOVE(*__i);
_GLIBCXX_MOVE_BACKWARD3(__first, __i, __i + 1);
*__first = _GLIBCXX_MOVE(__val);
}
else
std::__unguarded_linear_insert(__i, __comp);
}
}
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator>
inline void
__unguarded_insertion_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
for (_RandomAccessIterator __i = __first; __i != __last; ++__i)
std::__unguarded_linear_insert(__i);
}
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator, typename _Compare>
inline void
__unguarded_insertion_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last, _Compare __comp)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
for (_RandomAccessIterator __i = __first; __i != __last; ++__i)
std::__unguarded_linear_insert(__i, __comp);
}
/**
* @doctodo
* This controls some aspect of the sort routines.
*/
enum { _S_threshold = 16 };
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator>
void
__final_insertion_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last)
{
if (__last - __first > int(_S_threshold))
{
std::__insertion_sort(__first, __first + int(_S_threshold));
std::__unguarded_insertion_sort(__first + int(_S_threshold), __last);
}
else
std::__insertion_sort(__first, __last);
}
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator, typename _Compare>
void
__final_insertion_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last, _Compare __comp)
{
if (__last - __first > int(_S_threshold))
{
std::__insertion_sort(__first, __first + int(_S_threshold), __comp);
std::__unguarded_insertion_sort(__first + int(_S_threshold), __last,
__comp);
}
else
std::__insertion_sort(__first, __last, __comp);
}
/// This is a helper function...
template<typename _RandomAccessIterator, typename _Tp>
_RandomAccessIterator
__unguarded_partition(_RandomAccessIterator __first,
_RandomAccessIterator __last, const _Tp& __pivot)
{
while (true)
{
while (*__first < __pivot)
++__first;
--__last;
while (__pivot < *__last)
--__last;
if (!(__first < __last))
return __first;
std::iter_swap(__first, __last);
++__first;
}
}
/// This is a helper function...
template<typename _RandomAccessIterator, typename _Tp, typename _Compare>
_RandomAccessIterator
__unguarded_partition(_RandomAccessIterator __first,
_RandomAccessIterator __last,
const _Tp& __pivot, _Compare __comp)
{
while (true)
{
while (__comp(*__first, __pivot))
++__first;
--__last;
while (__comp(__pivot, *__last))
--__last;
if (!(__first < __last))
return __first;
std::iter_swap(__first, __last);
++__first;
}
}
/// This is a helper function...
template<typename _RandomAccessIterator>
inline _RandomAccessIterator
__unguarded_partition_pivot(_RandomAccessIterator __first,
_RandomAccessIterator __last)
{
_RandomAccessIterator __mid = __first + (__last - __first) / 2;
std::__move_median_first(__first, __mid, (__last - 1));
return std::__unguarded_partition(__first + 1, __last, *__first);
}
/// This is a helper function...
template<typename _RandomAccessIterator, typename _Compare>
inline _RandomAccessIterator
__unguarded_partition_pivot(_RandomAccessIterator __first,
_RandomAccessIterator __last, _Compare __comp)
{
_RandomAccessIterator __mid = __first + (__last - __first) / 2;
std::__move_median_first(__first, __mid, (__last - 1), __comp);
return std::__unguarded_partition(__first + 1, __last, *__first, __comp);
}
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator, typename _Size>
void
__introsort_loop(_RandomAccessIterator __first,
_RandomAccessIterator __last,
_Size __depth_limit)
{
while (__last - __first > int(_S_threshold))
{
if (__depth_limit == 0)
{
_GLIBCXX_STD_A::partial_sort(__first, __last, __last);
return;
}
--__depth_limit;
_RandomAccessIterator __cut =
std::__unguarded_partition_pivot(__first, __last);
std::__introsort_loop(__cut, __last, __depth_limit);
__last = __cut;
}
}
/// This is a helper function for the sort routine.
template<typename _RandomAccessIterator, typename _Size, typename _Compare>
void
__introsort_loop(_RandomAccessIterator __first,
_RandomAccessIterator __last,
_Size __depth_limit, _Compare __comp)
{
while (__last - __first > int(_S_threshold))
{
if (__depth_limit == 0)
{
_GLIBCXX_STD_A::partial_sort(__first, __last, __last, __comp);
return;
}
--__depth_limit;
_RandomAccessIterator __cut =
std::__unguarded_partition_pivot(__first, __last, __comp);
std::__introsort_loop(__cut, __last, __depth_limit, __comp);
__last = __cut;
}
}
// sort
template<typename _RandomAccessIterator, typename _Size>
void
__introselect(_RandomAccessIterator __first, _RandomAccessIterator __nth,
_RandomAccessIterator __last, _Size __depth_limit)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
while (__last - __first > 3)
{
if (__depth_limit == 0)
{
std::__heap_select(__first, __nth + 1, __last);
// Place the nth largest element in its final position.
std::iter_swap(__first, __nth);
return;
}
--__depth_limit;
_RandomAccessIterator __cut =
std::__unguarded_partition_pivot(__first, __last);
if (__cut <= __nth)
__first = __cut;
else
__last = __cut;
}
std::__insertion_sort(__first, __last);
}
template<typename _RandomAccessIterator, typename _Size, typename _Compare>
void
__introselect(_RandomAccessIterator __first, _RandomAccessIterator __nth,
_RandomAccessIterator __last, _Size __depth_limit,
_Compare __comp)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
while (__last - __first > 3)
{
if (__depth_limit == 0)
{
std::__heap_select(__first, __nth + 1, __last, __comp);
// Place the nth largest element in its final position.
std::iter_swap(__first, __nth);
return;
}
--__depth_limit;
_RandomAccessIterator __cut =
std::__unguarded_partition_pivot(__first, __last, __comp);
if (__cut <= __nth)
__first = __cut;
else
__last = __cut;
}
std::__insertion_sort(__first, __last, __comp);
}
// nth_element
// lower_bound moved to stl_algobase.h
/**
* @brief Finds the first position in which @a val could be inserted
* without changing the ordering.
* @ingroup binary_search_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param val The search term.
* @param comp A functor to use for comparisons.
* @return An iterator pointing to the first element <em>not less
* than</em> @a val, or end() if every element is less
* than @a val.
* @ingroup binary_search_algorithms
*
* The comparison function should have the same effects on ordering as
* the function used for the initial sort.
*/
template<typename _ForwardIterator, typename _Tp, typename _Compare>
_ForwardIterator
lower_bound(_ForwardIterator __first, _ForwardIterator __last,
const _Tp& __val, _Compare __comp)
{
typedef typename iterator_traits<_ForwardIterator>::value_type
_ValueType;
typedef typename iterator_traits<_ForwardIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType, _Tp>)
__glibcxx_requires_partitioned_lower_pred(__first, __last,
__val, __comp);
_DistanceType __len = std::distance(__first, __last);
while (__len > 0)
{
_DistanceType __half = __len >> 1;
_ForwardIterator __middle = __first;
std::advance(__middle, __half);
if (__comp(*__middle, __val))
{
__first = __middle;
++__first;
__len = __len - __half - 1;
}
else
__len = __half;
}
return __first;
}
/**
* @brief Finds the last position in which @a val could be inserted
* without changing the ordering.
* @ingroup binary_search_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param val The search term.
* @return An iterator pointing to the first element greater than @a val,
* or end() if no elements are greater than @a val.
* @ingroup binary_search_algorithms
*/
template<typename _ForwardIterator, typename _Tp>
_ForwardIterator
upper_bound(_ForwardIterator __first, _ForwardIterator __last,
const _Tp& __val)
{
typedef typename iterator_traits<_ForwardIterator>::value_type
_ValueType;
typedef typename iterator_traits<_ForwardIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_LessThanOpConcept<_Tp, _ValueType>)
__glibcxx_requires_partitioned_upper(__first, __last, __val);
_DistanceType __len = std::distance(__first, __last);
while (__len > 0)
{
_DistanceType __half = __len >> 1;
_ForwardIterator __middle = __first;
std::advance(__middle, __half);
if (__val < *__middle)
__len = __half;
else
{
__first = __middle;
++__first;
__len = __len - __half - 1;
}
}
return __first;
}
/**
* @brief Finds the last position in which @a val could be inserted
* without changing the ordering.
* @ingroup binary_search_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param val The search term.
* @param comp A functor to use for comparisons.
* @return An iterator pointing to the first element greater than @a val,
* or end() if no elements are greater than @a val.
* @ingroup binary_search_algorithms
*
* The comparison function should have the same effects on ordering as
* the function used for the initial sort.
*/
template<typename _ForwardIterator, typename _Tp, typename _Compare>
_ForwardIterator
upper_bound(_ForwardIterator __first, _ForwardIterator __last,
const _Tp& __val, _Compare __comp)
{
typedef typename iterator_traits<_ForwardIterator>::value_type
_ValueType;
typedef typename iterator_traits<_ForwardIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_Tp, _ValueType>)
__glibcxx_requires_partitioned_upper_pred(__first, __last,
__val, __comp);
_DistanceType __len = std::distance(__first, __last);
while (__len > 0)
{
_DistanceType __half = __len >> 1;
_ForwardIterator __middle = __first;
std::advance(__middle, __half);
if (__comp(__val, *__middle))
__len = __half;
else
{
__first = __middle;
++__first;
__len = __len - __half - 1;
}
}
return __first;
}
/**
* @brief Finds the largest subrange in which @a val could be inserted
* at any place in it without changing the ordering.
* @ingroup binary_search_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param val The search term.
* @return An pair of iterators defining the subrange.
* @ingroup binary_search_algorithms
*
* This is equivalent to
* @code
* std::make_pair(lower_bound(first, last, val),
* upper_bound(first, last, val))
* @endcode
* but does not actually call those functions.
*/
template<typename _ForwardIterator, typename _Tp>
pair<_ForwardIterator, _ForwardIterator>
equal_range(_ForwardIterator __first, _ForwardIterator __last,
const _Tp& __val)
{
typedef typename iterator_traits<_ForwardIterator>::value_type
_ValueType;
typedef typename iterator_traits<_ForwardIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType, _Tp>)
__glibcxx_function_requires(_LessThanOpConcept<_Tp, _ValueType>)
__glibcxx_requires_partitioned_lower(__first, __last, __val);
__glibcxx_requires_partitioned_upper(__first, __last, __val);
_DistanceType __len = std::distance(__first, __last);
while (__len > 0)
{
_DistanceType __half = __len >> 1;
_ForwardIterator __middle = __first;
std::advance(__middle, __half);
if (*__middle < __val)
{
__first = __middle;
++__first;
__len = __len - __half - 1;
}
else if (__val < *__middle)
__len = __half;
else
{
_ForwardIterator __left = std::lower_bound(__first, __middle,
__val);
std::advance(__first, __len);
_ForwardIterator __right = std::upper_bound(++__middle, __first,
__val);
return pair<_ForwardIterator, _ForwardIterator>(__left, __right);
}
}
return pair<_ForwardIterator, _ForwardIterator>(__first, __first);
}
/**
* @brief Finds the largest subrange in which @a val could be inserted
* at any place in it without changing the ordering.
* @param first An iterator.
* @param last Another iterator.
* @param val The search term.
* @param comp A functor to use for comparisons.
* @return An pair of iterators defining the subrange.
* @ingroup binary_search_algorithms
*
* This is equivalent to
* @code
* std::make_pair(lower_bound(first, last, val, comp),
* upper_bound(first, last, val, comp))
* @endcode
* but does not actually call those functions.
*/
template<typename _ForwardIterator, typename _Tp, typename _Compare>
pair<_ForwardIterator, _ForwardIterator>
equal_range(_ForwardIterator __first, _ForwardIterator __last,
const _Tp& __val, _Compare __comp)
{
typedef typename iterator_traits<_ForwardIterator>::value_type
_ValueType;
typedef typename iterator_traits<_ForwardIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType, _Tp>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_Tp, _ValueType>)
__glibcxx_requires_partitioned_lower_pred(__first, __last,
__val, __comp);
__glibcxx_requires_partitioned_upper_pred(__first, __last,
__val, __comp);
_DistanceType __len = std::distance(__first, __last);
while (__len > 0)
{
_DistanceType __half = __len >> 1;
_ForwardIterator __middle = __first;
std::advance(__middle, __half);
if (__comp(*__middle, __val))
{
__first = __middle;
++__first;
__len = __len - __half - 1;
}
else if (__comp(__val, *__middle))
__len = __half;
else
{
_ForwardIterator __left = std::lower_bound(__first, __middle,
__val, __comp);
std::advance(__first, __len);
_ForwardIterator __right = std::upper_bound(++__middle, __first,
__val, __comp);
return pair<_ForwardIterator, _ForwardIterator>(__left, __right);
}
}
return pair<_ForwardIterator, _ForwardIterator>(__first, __first);
}
/**
* @brief Determines whether an element exists in a range.
* @ingroup binary_search_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param val The search term.
* @return True if @a val (or its equivalent) is in [@a first,@a last ].
*
* Note that this does not actually return an iterator to @a val. For
* that, use std::find or a container's specialized find member functions.
*/
template<typename _ForwardIterator, typename _Tp>
bool
binary_search(_ForwardIterator __first, _ForwardIterator __last,
const _Tp& __val)
{
typedef typename iterator_traits<_ForwardIterator>::value_type
_ValueType;
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_LessThanOpConcept<_Tp, _ValueType>)
__glibcxx_requires_partitioned_lower(__first, __last, __val);
__glibcxx_requires_partitioned_upper(__first, __last, __val);
_ForwardIterator __i = std::lower_bound(__first, __last, __val);
return __i != __last && !(__val < *__i);
}
/**
* @brief Determines whether an element exists in a range.
* @ingroup binary_search_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param val The search term.
* @param comp A functor to use for comparisons.
* @return True if @a val (or its equivalent) is in [@a first,@a last ].
*
* Note that this does not actually return an iterator to @a val. For
* that, use std::find or a container's specialized find member functions.
*
* The comparison function should have the same effects on ordering as
* the function used for the initial sort.
*/
template<typename _ForwardIterator, typename _Tp, typename _Compare>
bool
binary_search(_ForwardIterator __first, _ForwardIterator __last,
const _Tp& __val, _Compare __comp)
{
typedef typename iterator_traits<_ForwardIterator>::value_type
_ValueType;
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_Tp, _ValueType>)
__glibcxx_requires_partitioned_lower_pred(__first, __last,
__val, __comp);
__glibcxx_requires_partitioned_upper_pred(__first, __last,
__val, __comp);
_ForwardIterator __i = std::lower_bound(__first, __last, __val, __comp);
return __i != __last && !bool(__comp(__val, *__i));
}
// merge
/// This is a helper function for the merge routines.
template<typename _BidirectionalIterator1, typename _BidirectionalIterator2,
typename _BidirectionalIterator3>
_BidirectionalIterator3
__merge_backward(_BidirectionalIterator1 __first1,
_BidirectionalIterator1 __last1,
_BidirectionalIterator2 __first2,
_BidirectionalIterator2 __last2,
_BidirectionalIterator3 __result)
{
if (__first1 == __last1)
return std::copy_backward(__first2, __last2, __result);
if (__first2 == __last2)
return std::copy_backward(__first1, __last1, __result);
--__last1;
--__last2;
while (true)
{
if (*__last2 < *__last1)
{
*--__result = *__last1;
if (__first1 == __last1)
return std::copy_backward(__first2, ++__last2, __result);
--__last1;
}
else
{
*--__result = *__last2;
if (__first2 == __last2)
return std::copy_backward(__first1, ++__last1, __result);
--__last2;
}
}
}
/// This is a helper function for the merge routines.
template<typename _BidirectionalIterator1, typename _BidirectionalIterator2,
typename _BidirectionalIterator3, typename _Compare>
_BidirectionalIterator3
__merge_backward(_BidirectionalIterator1 __first1,
_BidirectionalIterator1 __last1,
_BidirectionalIterator2 __first2,
_BidirectionalIterator2 __last2,
_BidirectionalIterator3 __result,
_Compare __comp)
{
if (__first1 == __last1)
return std::copy_backward(__first2, __last2, __result);
if (__first2 == __last2)
return std::copy_backward(__first1, __last1, __result);
--__last1;
--__last2;
while (true)
{
if (__comp(*__last2, *__last1))
{
*--__result = *__last1;
if (__first1 == __last1)
return std::copy_backward(__first2, ++__last2, __result);
--__last1;
}
else
{
*--__result = *__last2;
if (__first2 == __last2)
return std::copy_backward(__first1, ++__last1, __result);
--__last2;
}
}
}
/// This is a helper function for the merge routines.
template<typename _BidirectionalIterator1, typename _BidirectionalIterator2,
typename _Distance>
_BidirectionalIterator1
__rotate_adaptive(_BidirectionalIterator1 __first,
_BidirectionalIterator1 __middle,
_BidirectionalIterator1 __last,
_Distance __len1, _Distance __len2,
_BidirectionalIterator2 __buffer,
_Distance __buffer_size)
{
_BidirectionalIterator2 __buffer_end;
if (__len1 > __len2 && __len2 <= __buffer_size)
{
__buffer_end = _GLIBCXX_MOVE3(__middle, __last, __buffer);
_GLIBCXX_MOVE_BACKWARD3(__first, __middle, __last);
return _GLIBCXX_MOVE3(__buffer, __buffer_end, __first);
}
else if (__len1 <= __buffer_size)
{
__buffer_end = _GLIBCXX_MOVE3(__first, __middle, __buffer);
_GLIBCXX_MOVE3(__middle, __last, __first);
return _GLIBCXX_MOVE_BACKWARD3(__buffer, __buffer_end, __last);
}
else
{
std::rotate(__first, __middle, __last);
std::advance(__first, std::distance(__middle, __last));
return __first;
}
}
/// This is a helper function for the merge routines.
template<typename _BidirectionalIterator, typename _Distance,
typename _Pointer>
void
__merge_adaptive(_BidirectionalIterator __first,
_BidirectionalIterator __middle,
_BidirectionalIterator __last,
_Distance __len1, _Distance __len2,
_Pointer __buffer, _Distance __buffer_size)
{
if (__len1 <= __len2 && __len1 <= __buffer_size)
{
_Pointer __buffer_end = _GLIBCXX_MOVE3(__first, __middle, __buffer);
_GLIBCXX_STD_A::merge(_GLIBCXX_MAKE_MOVE_ITERATOR(__buffer),
_GLIBCXX_MAKE_MOVE_ITERATOR(__buffer_end),
_GLIBCXX_MAKE_MOVE_ITERATOR(__middle),
_GLIBCXX_MAKE_MOVE_ITERATOR(__last),
__first);
}
else if (__len2 <= __buffer_size)
{
_Pointer __buffer_end = _GLIBCXX_MOVE3(__middle, __last, __buffer);
std::__merge_backward(_GLIBCXX_MAKE_MOVE_ITERATOR(__first),
_GLIBCXX_MAKE_MOVE_ITERATOR(__middle),
_GLIBCXX_MAKE_MOVE_ITERATOR(__buffer),
_GLIBCXX_MAKE_MOVE_ITERATOR(__buffer_end),
__last);
}
else
{
_BidirectionalIterator __first_cut = __first;
_BidirectionalIterator __second_cut = __middle;
_Distance __len11 = 0;
_Distance __len22 = 0;
if (__len1 > __len2)
{
__len11 = __len1 / 2;
std::advance(__first_cut, __len11);
__second_cut = std::lower_bound(__middle, __last,
*__first_cut);
__len22 = std::distance(__middle, __second_cut);
}
else
{
__len22 = __len2 / 2;
std::advance(__second_cut, __len22);
__first_cut = std::upper_bound(__first, __middle,
*__second_cut);
__len11 = std::distance(__first, __first_cut);
}
_BidirectionalIterator __new_middle =
std::__rotate_adaptive(__first_cut, __middle, __second_cut,
__len1 - __len11, __len22, __buffer,
__buffer_size);
std::__merge_adaptive(__first, __first_cut, __new_middle, __len11,
__len22, __buffer, __buffer_size);
std::__merge_adaptive(__new_middle, __second_cut, __last,
__len1 - __len11,
__len2 - __len22, __buffer, __buffer_size);
}
}
/// This is a helper function for the merge routines.
template<typename _BidirectionalIterator, typename _Distance,
typename _Pointer, typename _Compare>
void
__merge_adaptive(_BidirectionalIterator __first,
_BidirectionalIterator __middle,
_BidirectionalIterator __last,
_Distance __len1, _Distance __len2,
_Pointer __buffer, _Distance __buffer_size,
_Compare __comp)
{
if (__len1 <= __len2 && __len1 <= __buffer_size)
{
_Pointer __buffer_end = _GLIBCXX_MOVE3(__first, __middle, __buffer);
_GLIBCXX_STD_A::merge(_GLIBCXX_MAKE_MOVE_ITERATOR(__buffer),
_GLIBCXX_MAKE_MOVE_ITERATOR(__buffer_end),
_GLIBCXX_MAKE_MOVE_ITERATOR(__middle),
_GLIBCXX_MAKE_MOVE_ITERATOR(__last),
__first, __comp);
}
else if (__len2 <= __buffer_size)
{
_Pointer __buffer_end = _GLIBCXX_MOVE3(__middle, __last, __buffer);
std::__merge_backward(_GLIBCXX_MAKE_MOVE_ITERATOR(__first),
_GLIBCXX_MAKE_MOVE_ITERATOR(__middle),
_GLIBCXX_MAKE_MOVE_ITERATOR(__buffer),
_GLIBCXX_MAKE_MOVE_ITERATOR(__buffer_end),
__last,__comp);
}
else
{
_BidirectionalIterator __first_cut = __first;
_BidirectionalIterator __second_cut = __middle;
_Distance __len11 = 0;
_Distance __len22 = 0;
if (__len1 > __len2)
{
__len11 = __len1 / 2;
std::advance(__first_cut, __len11);
__second_cut = std::lower_bound(__middle, __last, *__first_cut,
__comp);
__len22 = std::distance(__middle, __second_cut);
}
else
{
__len22 = __len2 / 2;
std::advance(__second_cut, __len22);
__first_cut = std::upper_bound(__first, __middle, *__second_cut,
__comp);
__len11 = std::distance(__first, __first_cut);
}
_BidirectionalIterator __new_middle =
std::__rotate_adaptive(__first_cut, __middle, __second_cut,
__len1 - __len11, __len22, __buffer,
__buffer_size);
std::__merge_adaptive(__first, __first_cut, __new_middle, __len11,
__len22, __buffer, __buffer_size, __comp);
std::__merge_adaptive(__new_middle, __second_cut, __last,
__len1 - __len11,
__len2 - __len22, __buffer,
__buffer_size, __comp);
}
}
/// This is a helper function for the merge routines.
template<typename _BidirectionalIterator, typename _Distance>
void
__merge_without_buffer(_BidirectionalIterator __first,
_BidirectionalIterator __middle,
_BidirectionalIterator __last,
_Distance __len1, _Distance __len2)
{
if (__len1 == 0 || __len2 == 0)
return;
if (__len1 + __len2 == 2)
{
if (*__middle < *__first)
std::iter_swap(__first, __middle);
return;
}
_BidirectionalIterator __first_cut = __first;
_BidirectionalIterator __second_cut = __middle;
_Distance __len11 = 0;
_Distance __len22 = 0;
if (__len1 > __len2)
{
__len11 = __len1 / 2;
std::advance(__first_cut, __len11);
__second_cut = std::lower_bound(__middle, __last, *__first_cut);
__len22 = std::distance(__middle, __second_cut);
}
else
{
__len22 = __len2 / 2;
std::advance(__second_cut, __len22);
__first_cut = std::upper_bound(__first, __middle, *__second_cut);
__len11 = std::distance(__first, __first_cut);
}
std::rotate(__first_cut, __middle, __second_cut);
_BidirectionalIterator __new_middle = __first_cut;
std::advance(__new_middle, std::distance(__middle, __second_cut));
std::__merge_without_buffer(__first, __first_cut, __new_middle,
__len11, __len22);
std::__merge_without_buffer(__new_middle, __second_cut, __last,
__len1 - __len11, __len2 - __len22);
}
/// This is a helper function for the merge routines.
template<typename _BidirectionalIterator, typename _Distance,
typename _Compare>
void
__merge_without_buffer(_BidirectionalIterator __first,
_BidirectionalIterator __middle,
_BidirectionalIterator __last,
_Distance __len1, _Distance __len2,
_Compare __comp)
{
if (__len1 == 0 || __len2 == 0)
return;
if (__len1 + __len2 == 2)
{
if (__comp(*__middle, *__first))
std::iter_swap(__first, __middle);
return;
}
_BidirectionalIterator __first_cut = __first;
_BidirectionalIterator __second_cut = __middle;
_Distance __len11 = 0;
_Distance __len22 = 0;
if (__len1 > __len2)
{
__len11 = __len1 / 2;
std::advance(__first_cut, __len11);
__second_cut = std::lower_bound(__middle, __last, *__first_cut,
__comp);
__len22 = std::distance(__middle, __second_cut);
}
else
{
__len22 = __len2 / 2;
std::advance(__second_cut, __len22);
__first_cut = std::upper_bound(__first, __middle, *__second_cut,
__comp);
__len11 = std::distance(__first, __first_cut);
}
std::rotate(__first_cut, __middle, __second_cut);
_BidirectionalIterator __new_middle = __first_cut;
std::advance(__new_middle, std::distance(__middle, __second_cut));
std::__merge_without_buffer(__first, __first_cut, __new_middle,
__len11, __len22, __comp);
std::__merge_without_buffer(__new_middle, __second_cut, __last,
__len1 - __len11, __len2 - __len22, __comp);
}
/**
* @brief Merges two sorted ranges in place.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param middle Another iterator.
* @param last Another iterator.
* @return Nothing.
*
* Merges two sorted and consecutive ranges, [first,middle) and
* [middle,last), and puts the result in [first,last). The output will
* be sorted. The sort is @e stable, that is, for equivalent
* elements in the two ranges, elements from the first range will always
* come before elements from the second.
*
* If enough additional memory is available, this takes (last-first)-1
* comparisons. Otherwise an NlogN algorithm is used, where N is
* distance(first,last).
*/
template<typename _BidirectionalIterator>
void
inplace_merge(_BidirectionalIterator __first,
_BidirectionalIterator __middle,
_BidirectionalIterator __last)
{
typedef typename iterator_traits<_BidirectionalIterator>::value_type
_ValueType;
typedef typename iterator_traits<_BidirectionalIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_Mutable_BidirectionalIteratorConcept<
_BidirectionalIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<_ValueType>)
__glibcxx_requires_sorted(__first, __middle);
__glibcxx_requires_sorted(__middle, __last);
if (__first == __middle || __middle == __last)
return;
_DistanceType __len1 = std::distance(__first, __middle);
_DistanceType __len2 = std::distance(__middle, __last);
_Temporary_buffer<_BidirectionalIterator, _ValueType> __buf(__first,
__last);
if (__buf.begin() == 0)
std::__merge_without_buffer(__first, __middle, __last, __len1, __len2);
else
std::__merge_adaptive(__first, __middle, __last, __len1, __len2,
__buf.begin(), _DistanceType(__buf.size()));
}
/**
* @brief Merges two sorted ranges in place.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param middle Another iterator.
* @param last Another iterator.
* @param comp A functor to use for comparisons.
* @return Nothing.
*
* Merges two sorted and consecutive ranges, [first,middle) and
* [middle,last), and puts the result in [first,last). The output will
* be sorted. The sort is @e stable, that is, for equivalent
* elements in the two ranges, elements from the first range will always
* come before elements from the second.
*
* If enough additional memory is available, this takes (last-first)-1
* comparisons. Otherwise an NlogN algorithm is used, where N is
* distance(first,last).
*
* The comparison function should have the same effects on ordering as
* the function used for the initial sort.
*/
template<typename _BidirectionalIterator, typename _Compare>
void
inplace_merge(_BidirectionalIterator __first,
_BidirectionalIterator __middle,
_BidirectionalIterator __last,
_Compare __comp)
{
typedef typename iterator_traits<_BidirectionalIterator>::value_type
_ValueType;
typedef typename iterator_traits<_BidirectionalIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_Mutable_BidirectionalIteratorConcept<
_BidirectionalIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType, _ValueType>)
__glibcxx_requires_sorted_pred(__first, __middle, __comp);
__glibcxx_requires_sorted_pred(__middle, __last, __comp);
if (__first == __middle || __middle == __last)
return;
const _DistanceType __len1 = std::distance(__first, __middle);
const _DistanceType __len2 = std::distance(__middle, __last);
_Temporary_buffer<_BidirectionalIterator, _ValueType> __buf(__first,
__last);
if (__buf.begin() == 0)
std::__merge_without_buffer(__first, __middle, __last, __len1,
__len2, __comp);
else
std::__merge_adaptive(__first, __middle, __last, __len1, __len2,
__buf.begin(), _DistanceType(__buf.size()),
__comp);
}
template<typename _RandomAccessIterator1, typename _RandomAccessIterator2,
typename _Distance>
void
__merge_sort_loop(_RandomAccessIterator1 __first,
_RandomAccessIterator1 __last,
_RandomAccessIterator2 __result,
_Distance __step_size)
{
const _Distance __two_step = 2 * __step_size;
while (__last - __first >= __two_step)
{
__result = _GLIBCXX_STD_A::merge(
_GLIBCXX_MAKE_MOVE_ITERATOR(__first),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first + __step_size),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first + __step_size),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first + __two_step),
__result);
__first += __two_step;
}
__step_size = std::min(_Distance(__last - __first), __step_size);
_GLIBCXX_STD_A::merge(_GLIBCXX_MAKE_MOVE_ITERATOR(__first),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first +
__step_size),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first +
__step_size),
_GLIBCXX_MAKE_MOVE_ITERATOR(__last),
__result);
}
template<typename _RandomAccessIterator1, typename _RandomAccessIterator2,
typename _Distance, typename _Compare>
void
__merge_sort_loop(_RandomAccessIterator1 __first,
_RandomAccessIterator1 __last,
_RandomAccessIterator2 __result, _Distance __step_size,
_Compare __comp)
{
const _Distance __two_step = 2 * __step_size;
while (__last - __first >= __two_step)
{
__result = _GLIBCXX_STD_A::merge(
_GLIBCXX_MAKE_MOVE_ITERATOR(__first),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first + __step_size),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first + __step_size),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first + __two_step),
__result, __comp);
__first += __two_step;
}
__step_size = std::min(_Distance(__last - __first), __step_size);
_GLIBCXX_STD_A::merge(_GLIBCXX_MAKE_MOVE_ITERATOR(__first),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first +
__step_size),
_GLIBCXX_MAKE_MOVE_ITERATOR(__first +
__step_size),
_GLIBCXX_MAKE_MOVE_ITERATOR(__last),
__result, __comp);
}
template<typename _RandomAccessIterator, typename _Distance>
void
__chunk_insertion_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last,
_Distance __chunk_size)
{
while (__last - __first >= __chunk_size)
{
std::__insertion_sort(__first, __first + __chunk_size);
__first += __chunk_size;
}
std::__insertion_sort(__first, __last);
}
template<typename _RandomAccessIterator, typename _Distance,
typename _Compare>
void
__chunk_insertion_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last,
_Distance __chunk_size, _Compare __comp)
{
while (__last - __first >= __chunk_size)
{
std::__insertion_sort(__first, __first + __chunk_size, __comp);
__first += __chunk_size;
}
std::__insertion_sort(__first, __last, __comp);
}
enum { _S_chunk_size = 7 };
template<typename _RandomAccessIterator, typename _Pointer>
void
__merge_sort_with_buffer(_RandomAccessIterator __first,
_RandomAccessIterator __last,
_Pointer __buffer)
{
typedef typename iterator_traits<_RandomAccessIterator>::difference_type
_Distance;
const _Distance __len = __last - __first;
const _Pointer __buffer_last = __buffer + __len;
_Distance __step_size = _S_chunk_size;
std::__chunk_insertion_sort(__first, __last, __step_size);
while (__step_size < __len)
{
std::__merge_sort_loop(__first, __last, __buffer, __step_size);
__step_size *= 2;
std::__merge_sort_loop(__buffer, __buffer_last, __first, __step_size);
__step_size *= 2;
}
}
template<typename _RandomAccessIterator, typename _Pointer, typename _Compare>
void
__merge_sort_with_buffer(_RandomAccessIterator __first,
_RandomAccessIterator __last,
_Pointer __buffer, _Compare __comp)
{
typedef typename iterator_traits<_RandomAccessIterator>::difference_type
_Distance;
const _Distance __len = __last - __first;
const _Pointer __buffer_last = __buffer + __len;
_Distance __step_size = _S_chunk_size;
std::__chunk_insertion_sort(__first, __last, __step_size, __comp);
while (__step_size < __len)
{
std::__merge_sort_loop(__first, __last, __buffer,
__step_size, __comp);
__step_size *= 2;
std::__merge_sort_loop(__buffer, __buffer_last, __first,
__step_size, __comp);
__step_size *= 2;
}
}
template<typename _RandomAccessIterator, typename _Pointer,
typename _Distance>
void
__stable_sort_adaptive(_RandomAccessIterator __first,
_RandomAccessIterator __last,
_Pointer __buffer, _Distance __buffer_size)
{
const _Distance __len = (__last - __first + 1) / 2;
const _RandomAccessIterator __middle = __first + __len;
if (__len > __buffer_size)
{
std::__stable_sort_adaptive(__first, __middle,
__buffer, __buffer_size);
std::__stable_sort_adaptive(__middle, __last,
__buffer, __buffer_size);
}
else
{
std::__merge_sort_with_buffer(__first, __middle, __buffer);
std::__merge_sort_with_buffer(__middle, __last, __buffer);
}
std::__merge_adaptive(__first, __middle, __last,
_Distance(__middle - __first),
_Distance(__last - __middle),
__buffer, __buffer_size);
}
template<typename _RandomAccessIterator, typename _Pointer,
typename _Distance, typename _Compare>
void
__stable_sort_adaptive(_RandomAccessIterator __first,
_RandomAccessIterator __last,
_Pointer __buffer, _Distance __buffer_size,
_Compare __comp)
{
const _Distance __len = (__last - __first + 1) / 2;
const _RandomAccessIterator __middle = __first + __len;
if (__len > __buffer_size)
{
std::__stable_sort_adaptive(__first, __middle, __buffer,
__buffer_size, __comp);
std::__stable_sort_adaptive(__middle, __last, __buffer,
__buffer_size, __comp);
}
else
{
std::__merge_sort_with_buffer(__first, __middle, __buffer, __comp);
std::__merge_sort_with_buffer(__middle, __last, __buffer, __comp);
}
std::__merge_adaptive(__first, __middle, __last,
_Distance(__middle - __first),
_Distance(__last - __middle),
__buffer, __buffer_size,
__comp);
}
/// This is a helper function for the stable sorting routines.
template<typename _RandomAccessIterator>
void
__inplace_stable_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last)
{
if (__last - __first < 15)
{
std::__insertion_sort(__first, __last);
return;
}
_RandomAccessIterator __middle = __first + (__last - __first) / 2;
std::__inplace_stable_sort(__first, __middle);
std::__inplace_stable_sort(__middle, __last);
std::__merge_without_buffer(__first, __middle, __last,
__middle - __first,
__last - __middle);
}
/// This is a helper function for the stable sorting routines.
template<typename _RandomAccessIterator, typename _Compare>
void
__inplace_stable_sort(_RandomAccessIterator __first,
_RandomAccessIterator __last, _Compare __comp)
{
if (__last - __first < 15)
{
std::__insertion_sort(__first, __last, __comp);
return;
}
_RandomAccessIterator __middle = __first + (__last - __first) / 2;
std::__inplace_stable_sort(__first, __middle, __comp);
std::__inplace_stable_sort(__middle, __last, __comp);
std::__merge_without_buffer(__first, __middle, __last,
__middle - __first,
__last - __middle,
__comp);
}
// stable_sort
// Set algorithms: includes, set_union, set_intersection, set_difference,
// set_symmetric_difference. All of these algorithms have the precondition
// that their input ranges are sorted and the postcondition that their output
// ranges are sorted.
/**
* @brief Determines whether all elements of a sequence exists in a range.
* @param first1 Start of search range.
* @param last1 End of search range.
* @param first2 Start of sequence
* @param last2 End of sequence.
* @return True if each element in [first2,last2) is contained in order
* within [first1,last1). False otherwise.
* @ingroup set_algorithms
*
* This operation expects both [first1,last1) and [first2,last2) to be
* sorted. Searches for the presence of each element in [first2,last2)
* within [first1,last1). The iterators over each range only move forward,
* so this is a linear algorithm. If an element in [first2,last2) is not
* found before the search iterator reaches @a last2, false is returned.
*/
template<typename _InputIterator1, typename _InputIterator2>
bool
includes(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType1, _ValueType2>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set(__first1, __last1, __first2);
__glibcxx_requires_sorted_set(__first2, __last2, __first1);
while (__first1 != __last1 && __first2 != __last2)
if (*__first2 < *__first1)
return false;
else if(*__first1 < *__first2)
++__first1;
else
++__first1, ++__first2;
return __first2 == __last2;
}
/**
* @brief Determines whether all elements of a sequence exists in a range
* using comparison.
* @ingroup set_algorithms
* @param first1 Start of search range.
* @param last1 End of search range.
* @param first2 Start of sequence
* @param last2 End of sequence.
* @param comp Comparison function to use.
* @return True if each element in [first2,last2) is contained in order
* within [first1,last1) according to comp. False otherwise.
* @ingroup set_algorithms
*
* This operation expects both [first1,last1) and [first2,last2) to be
* sorted. Searches for the presence of each element in [first2,last2)
* within [first1,last1), using comp to decide. The iterators over each
* range only move forward, so this is a linear algorithm. If an element
* in [first2,last2) is not found before the search iterator reaches @a
* last2, false is returned.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _Compare>
bool
includes(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_Compare __comp)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType1, _ValueType2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set_pred(__first1, __last1, __first2, __comp);
__glibcxx_requires_sorted_set_pred(__first2, __last2, __first1, __comp);
while (__first1 != __last1 && __first2 != __last2)
if (__comp(*__first2, *__first1))
return false;
else if(__comp(*__first1, *__first2))
++__first1;
else
++__first1, ++__first2;
return __first2 == __last2;
}
// nth_element
// merge
// set_difference
// set_intersection
// set_union
// stable_sort
// set_symmetric_difference
// min_element
// max_element
/**
* @brief Permute range into the next @a dictionary ordering.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @return False if wrapped to first permutation, true otherwise.
*
* Treats all permutations of the range as a set of @a dictionary sorted
* sequences. Permutes the current sequence into the next one of this set.
* Returns true if there are more sequences to generate. If the sequence
* is the largest of the set, the smallest is generated and false returned.
*/
template<typename _BidirectionalIterator>
bool
next_permutation(_BidirectionalIterator __first,
_BidirectionalIterator __last)
{
// concept requirements
__glibcxx_function_requires(_BidirectionalIteratorConcept<
_BidirectionalIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<
typename iterator_traits<_BidirectionalIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return false;
_BidirectionalIterator __i = __first;
++__i;
if (__i == __last)
return false;
__i = __last;
--__i;
for(;;)
{
_BidirectionalIterator __ii = __i;
--__i;
if (*__i < *__ii)
{
_BidirectionalIterator __j = __last;
while (!(*__i < *--__j))
{}
std::iter_swap(__i, __j);
std::reverse(__ii, __last);
return true;
}
if (__i == __first)
{
std::reverse(__first, __last);
return false;
}
}
}
/**
* @brief Permute range into the next @a dictionary ordering using
* comparison functor.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @param comp A comparison functor.
* @return False if wrapped to first permutation, true otherwise.
*
* Treats all permutations of the range [first,last) as a set of
* @a dictionary sorted sequences ordered by @a comp. Permutes the current
* sequence into the next one of this set. Returns true if there are more
* sequences to generate. If the sequence is the largest of the set, the
* smallest is generated and false returned.
*/
template<typename _BidirectionalIterator, typename _Compare>
bool
next_permutation(_BidirectionalIterator __first,
_BidirectionalIterator __last, _Compare __comp)
{
// concept requirements
__glibcxx_function_requires(_BidirectionalIteratorConcept<
_BidirectionalIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
typename iterator_traits<_BidirectionalIterator>::value_type,
typename iterator_traits<_BidirectionalIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return false;
_BidirectionalIterator __i = __first;
++__i;
if (__i == __last)
return false;
__i = __last;
--__i;
for(;;)
{
_BidirectionalIterator __ii = __i;
--__i;
if (__comp(*__i, *__ii))
{
_BidirectionalIterator __j = __last;
while (!bool(__comp(*__i, *--__j)))
{}
std::iter_swap(__i, __j);
std::reverse(__ii, __last);
return true;
}
if (__i == __first)
{
std::reverse(__first, __last);
return false;
}
}
}
/**
* @brief Permute range into the previous @a dictionary ordering.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @return False if wrapped to last permutation, true otherwise.
*
* Treats all permutations of the range as a set of @a dictionary sorted
* sequences. Permutes the current sequence into the previous one of this
* set. Returns true if there are more sequences to generate. If the
* sequence is the smallest of the set, the largest is generated and false
* returned.
*/
template<typename _BidirectionalIterator>
bool
prev_permutation(_BidirectionalIterator __first,
_BidirectionalIterator __last)
{
// concept requirements
__glibcxx_function_requires(_BidirectionalIteratorConcept<
_BidirectionalIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<
typename iterator_traits<_BidirectionalIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return false;
_BidirectionalIterator __i = __first;
++__i;
if (__i == __last)
return false;
__i = __last;
--__i;
for(;;)
{
_BidirectionalIterator __ii = __i;
--__i;
if (*__ii < *__i)
{
_BidirectionalIterator __j = __last;
while (!(*--__j < *__i))
{}
std::iter_swap(__i, __j);
std::reverse(__ii, __last);
return true;
}
if (__i == __first)
{
std::reverse(__first, __last);
return false;
}
}
}
/**
* @brief Permute range into the previous @a dictionary ordering using
* comparison functor.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @param comp A comparison functor.
* @return False if wrapped to last permutation, true otherwise.
*
* Treats all permutations of the range [first,last) as a set of
* @a dictionary sorted sequences ordered by @a comp. Permutes the current
* sequence into the previous one of this set. Returns true if there are
* more sequences to generate. If the sequence is the smallest of the set,
* the largest is generated and false returned.
*/
template<typename _BidirectionalIterator, typename _Compare>
bool
prev_permutation(_BidirectionalIterator __first,
_BidirectionalIterator __last, _Compare __comp)
{
// concept requirements
__glibcxx_function_requires(_BidirectionalIteratorConcept<
_BidirectionalIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
typename iterator_traits<_BidirectionalIterator>::value_type,
typename iterator_traits<_BidirectionalIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return false;
_BidirectionalIterator __i = __first;
++__i;
if (__i == __last)
return false;
__i = __last;
--__i;
for(;;)
{
_BidirectionalIterator __ii = __i;
--__i;
if (__comp(*__ii, *__i))
{
_BidirectionalIterator __j = __last;
while (!bool(__comp(*--__j, *__i)))
{}
std::iter_swap(__i, __j);
std::reverse(__ii, __last);
return true;
}
if (__i == __first)
{
std::reverse(__first, __last);
return false;
}
}
}
// replace
// replace_if
/**
* @brief Copy a sequence, replacing each element of one value with another
* value.
* @param first An input iterator.
* @param last An input iterator.
* @param result An output iterator.
* @param old_value The value to be replaced.
* @param new_value The replacement value.
* @return The end of the output sequence, @p result+(last-first).
*
* Copies each element in the input range @p [first,last) to the
* output range @p [result,result+(last-first)) replacing elements
* equal to @p old_value with @p new_value.
*/
template<typename _InputIterator, typename _OutputIterator, typename _Tp>
_OutputIterator
replace_copy(_InputIterator __first, _InputIterator __last,
_OutputIterator __result,
const _Tp& __old_value, const _Tp& __new_value)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_InputIterator>::value_type, _Tp>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first, ++__result)
if (*__first == __old_value)
*__result = __new_value;
else
*__result = *__first;
return __result;
}
/**
* @brief Copy a sequence, replacing each value for which a predicate
* returns true with another value.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param result An output iterator.
* @param pred A predicate.
* @param new_value The replacement value.
* @return The end of the output sequence, @p result+(last-first).
*
* Copies each element in the range @p [first,last) to the range
* @p [result,result+(last-first)) replacing elements for which
* @p pred returns true with @p new_value.
*/
template<typename _InputIterator, typename _OutputIterator,
typename _Predicate, typename _Tp>
_OutputIterator
replace_copy_if(_InputIterator __first, _InputIterator __last,
_OutputIterator __result,
_Predicate __pred, const _Tp& __new_value)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first, ++__result)
if (__pred(*__first))
*__result = __new_value;
else
*__result = *__first;
return __result;
}
#ifdef __GXX_EXPERIMENTAL_CXX0X__
/**
* @brief Determines whether the elements of a sequence are sorted.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param last Another iterator.
* @return True if the elements are sorted, false otherwise.
*/
template<typename _ForwardIterator>
inline bool
is_sorted(_ForwardIterator __first, _ForwardIterator __last)
{ return std::is_sorted_until(__first, __last) == __last; }
/**
* @brief Determines whether the elements of a sequence are sorted
* according to a comparison functor.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param comp A comparison functor.
* @return True if the elements are sorted, false otherwise.
*/
template<typename _ForwardIterator, typename _Compare>
inline bool
is_sorted(_ForwardIterator __first, _ForwardIterator __last,
_Compare __comp)
{ return std::is_sorted_until(__first, __last, __comp) == __last; }
/**
* @brief Determines the end of a sorted sequence.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param last Another iterator.
* @return An iterator pointing to the last iterator i in [first, last)
* for which the range [first, i) is sorted.
*/
template<typename _ForwardIterator>
_ForwardIterator
is_sorted_until(_ForwardIterator __first, _ForwardIterator __last)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __last;
_ForwardIterator __next = __first;
for (++__next; __next != __last; __first = __next, ++__next)
if (*__next < *__first)
return __next;
return __next;
}
/**
* @brief Determines the end of a sorted sequence using comparison functor.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param comp A comparison functor.
* @return An iterator pointing to the last iterator i in [first, last)
* for which the range [first, i) is sorted.
*/
template<typename _ForwardIterator, typename _Compare>
_ForwardIterator
is_sorted_until(_ForwardIterator __first, _ForwardIterator __last,
_Compare __comp)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
typename iterator_traits<_ForwardIterator>::value_type,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __last;
_ForwardIterator __next = __first;
for (++__next; __next != __last; __first = __next, ++__next)
if (__comp(*__next, *__first))
return __next;
return __next;
}
/**
* @brief Determines min and max at once as an ordered pair.
* @ingroup sorting_algorithms
* @param a A thing of arbitrary type.
* @param b Another thing of arbitrary type.
* @return A pair(b, a) if b is smaller than a, pair(a, b) otherwise.
*/
template<typename _Tp>
inline pair<const _Tp&, const _Tp&>
minmax(const _Tp& __a, const _Tp& __b)
{
// concept requirements
__glibcxx_function_requires(_LessThanComparableConcept<_Tp>)
return __b < __a ? pair<const _Tp&, const _Tp&>(__b, __a)
: pair<const _Tp&, const _Tp&>(__a, __b);
}
/**
* @brief Determines min and max at once as an ordered pair.
* @ingroup sorting_algorithms
* @param a A thing of arbitrary type.
* @param b Another thing of arbitrary type.
* @param comp A @link comparison_functor comparison functor@endlink.
* @return A pair(b, a) if b is smaller than a, pair(a, b) otherwise.
*/
template<typename _Tp, typename _Compare>
inline pair<const _Tp&, const _Tp&>
minmax(const _Tp& __a, const _Tp& __b, _Compare __comp)
{
return __comp(__b, __a) ? pair<const _Tp&, const _Tp&>(__b, __a)
: pair<const _Tp&, const _Tp&>(__a, __b);
}
/**
* @brief Return a pair of iterators pointing to the minimum and maximum
* elements in a range.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @return make_pair(m, M), where m is the first iterator i in
* [first, last) such that no other element in the range is
* smaller, and where M is the last iterator i in [first, last)
* such that no other element in the range is larger.
*/
template<typename _ForwardIterator>
pair<_ForwardIterator, _ForwardIterator>
minmax_element(_ForwardIterator __first, _ForwardIterator __last)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
_ForwardIterator __next = __first;
if (__first == __last
|| ++__next == __last)
return std::make_pair(__first, __first);
_ForwardIterator __min, __max;
if (*__next < *__first)
{
__min = __next;
__max = __first;
}
else
{
__min = __first;
__max = __next;
}
__first = __next;
++__first;
while (__first != __last)
{
__next = __first;
if (++__next == __last)
{
if (*__first < *__min)
__min = __first;
else if (!(*__first < *__max))
__max = __first;
break;
}
if (*__next < *__first)
{
if (*__next < *__min)
__min = __next;
if (!(*__first < *__max))
__max = __first;
}
else
{
if (*__first < *__min)
__min = __first;
if (!(*__next < *__max))
__max = __next;
}
__first = __next;
++__first;
}
return std::make_pair(__min, __max);
}
/**
* @brief Return a pair of iterators pointing to the minimum and maximum
* elements in a range.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @param comp Comparison functor.
* @return make_pair(m, M), where m is the first iterator i in
* [first, last) such that no other element in the range is
* smaller, and where M is the last iterator i in [first, last)
* such that no other element in the range is larger.
*/
template<typename _ForwardIterator, typename _Compare>
pair<_ForwardIterator, _ForwardIterator>
minmax_element(_ForwardIterator __first, _ForwardIterator __last,
_Compare __comp)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
typename iterator_traits<_ForwardIterator>::value_type,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
_ForwardIterator __next = __first;
if (__first == __last
|| ++__next == __last)
return std::make_pair(__first, __first);
_ForwardIterator __min, __max;
if (__comp(*__next, *__first))
{
__min = __next;
__max = __first;
}
else
{
__min = __first;
__max = __next;
}
__first = __next;
++__first;
while (__first != __last)
{
__next = __first;
if (++__next == __last)
{
if (__comp(*__first, *__min))
__min = __first;
else if (!__comp(*__first, *__max))
__max = __first;
break;
}
if (__comp(*__next, *__first))
{
if (__comp(*__next, *__min))
__min = __next;
if (!__comp(*__first, *__max))
__max = __first;
}
else
{
if (__comp(*__first, *__min))
__min = __first;
if (!__comp(*__next, *__max))
__max = __next;
}
__first = __next;
++__first;
}
return std::make_pair(__min, __max);
}
// N2722 + DR 915.
template<typename _Tp>
inline _Tp
min(initializer_list<_Tp> __l)
{ return *std::min_element(__l.begin(), __l.end()); }
template<typename _Tp, typename _Compare>
inline _Tp
min(initializer_list<_Tp> __l, _Compare __comp)
{ return *std::min_element(__l.begin(), __l.end(), __comp); }
template<typename _Tp>
inline _Tp
max(initializer_list<_Tp> __l)
{ return *std::max_element(__l.begin(), __l.end()); }
template<typename _Tp, typename _Compare>
inline _Tp
max(initializer_list<_Tp> __l, _Compare __comp)
{ return *std::max_element(__l.begin(), __l.end(), __comp); }
template<typename _Tp>
inline pair<_Tp, _Tp>
minmax(initializer_list<_Tp> __l)
{
pair<const _Tp*, const _Tp*> __p =
std::minmax_element(__l.begin(), __l.end());
return std::make_pair(*__p.first, *__p.second);
}
template<typename _Tp, typename _Compare>
inline pair<_Tp, _Tp>
minmax(initializer_list<_Tp> __l, _Compare __comp)
{
pair<const _Tp*, const _Tp*> __p =
std::minmax_element(__l.begin(), __l.end(), __comp);
return std::make_pair(*__p.first, *__p.second);
}
/**
* @brief Checks whether a permutaion of the second sequence is equal
* to the first sequence.
* @ingroup non_mutating_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @return true if there exists a permutation of the elements in the range
* [first2, first2 + (last1 - first1)), beginning with
* ForwardIterator2 begin, such that equal(first1, last1, begin)
* returns true; otherwise, returns false.
*/
template<typename _ForwardIterator1, typename _ForwardIterator2>
bool
is_permutation(_ForwardIterator1 __first1, _ForwardIterator1 __last1,
_ForwardIterator2 __first2)
{
// Efficiently compare identical prefixes: O(N) if sequences
// have the same elements in the same order.
for (; __first1 != __last1; ++__first1, ++__first2)
if (!(*__first1 == *__first2))
break;
if (__first1 == __last1)
return true;
// Establish __last2 assuming equal ranges by iterating over the
// rest of the list.
_ForwardIterator2 __last2 = __first2;
std::advance(__last2, std::distance(__first1, __last1));
for (_ForwardIterator1 __scan = __first1; __scan != __last1; ++__scan)
{
if (__scan != _GLIBCXX_STD_A::find(__first1, __scan, *__scan))
continue; // We've seen this one before.
auto __matches = std::count(__first2, __last2, *__scan);
if (0 == __matches
|| std::count(__scan, __last1, *__scan) != __matches)
return false;
}
return true;
}
/**
* @brief Checks whether a permutation of the second sequence is equal
* to the first sequence.
* @ingroup non_mutating_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @param pred A binary predicate.
* @return true if there exists a permutation of the elements in the range
* [first2, first2 + (last1 - first1)), beginning with
* ForwardIterator2 begin, such that equal(first1, last1, begin,
* pred) returns true; otherwise, returns false.
*/
template<typename _ForwardIterator1, typename _ForwardIterator2,
typename _BinaryPredicate>
bool
is_permutation(_ForwardIterator1 __first1, _ForwardIterator1 __last1,
_ForwardIterator2 __first2, _BinaryPredicate __pred)
{
// Efficiently compare identical prefixes: O(N) if sequences
// have the same elements in the same order.
for (; __first1 != __last1; ++__first1, ++__first2)
if (!bool(__pred(*__first1, *__first2)))
break;
if (__first1 == __last1)
return true;
// Establish __last2 assuming equal ranges by iterating over the
// rest of the list.
_ForwardIterator2 __last2 = __first2;
std::advance(__last2, std::distance(__first1, __last1));
for (_ForwardIterator1 __scan = __first1; __scan != __last1; ++__scan)
{
using std::placeholders::_1;
if (__scan != _GLIBCXX_STD_A::find_if(__first1, __scan,
std::bind(__pred, _1, *__scan)))
continue; // We've seen this one before.
auto __matches = std::count_if(__first2, __last2,
std::bind(__pred, _1, *__scan));
if (0 == __matches
|| std::count_if(__scan, __last1,
std::bind(__pred, _1, *__scan)) != __matches)
return false;
}
return true;
}
#ifdef _GLIBCXX_USE_C99_STDINT_TR1
/**
* @brief Shuffle the elements of a sequence using a uniform random
* number generator.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param g A UniformRandomNumberGenerator (26.5.1.3).
* @return Nothing.
*
* Reorders the elements in the range @p [first,last) using @p g to
* provide random numbers.
*/
template<typename _RandomAccessIterator,
typename _UniformRandomNumberGenerator>
void
shuffle(_RandomAccessIterator __first, _RandomAccessIterator __last,
_UniformRandomNumberGenerator&& __g)
{
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return;
typedef typename iterator_traits<_RandomAccessIterator>::difference_type
_DistanceType;
typedef typename std::make_unsigned<_DistanceType>::type __ud_type;
typedef typename std::uniform_int_distribution<__ud_type> __distr_type;
typedef typename __distr_type::param_type __p_type;
__distr_type __d;
for (_RandomAccessIterator __i = __first + 1; __i != __last; ++__i)
std::iter_swap(__i, __first + __d(__g, __p_type(0, __i - __first)));
}
#endif
#endif // __GXX_EXPERIMENTAL_CXX0X__
_GLIBCXX_END_NAMESPACE_VERSION
_GLIBCXX_BEGIN_NAMESPACE_ALGO
/**
* @brief Apply a function to every element of a sequence.
* @ingroup non_mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param f A unary function object.
* @return @p f (std::move(@p f) in C++0x).
*
* Applies the function object @p f to each element in the range
* @p [first,last). @p f must not modify the order of the sequence.
* If @p f has a return value it is ignored.
*/
template<typename _InputIterator, typename _Function>
_Function
for_each(_InputIterator __first, _InputIterator __last, _Function __f)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first)
__f(*__first);
return _GLIBCXX_MOVE(__f);
}
/**
* @brief Find the first occurrence of a value in a sequence.
* @ingroup non_mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param val The value to find.
* @return The first iterator @c i in the range @p [first,last)
* such that @c *i == @p val, or @p last if no such iterator exists.
*/
template<typename _InputIterator, typename _Tp>
inline _InputIterator
find(_InputIterator __first, _InputIterator __last,
const _Tp& __val)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_InputIterator>::value_type, _Tp>)
__glibcxx_requires_valid_range(__first, __last);
return std::__find(__first, __last, __val,
std::__iterator_category(__first));
}
/**
* @brief Find the first element in a sequence for which a
* predicate is true.
* @ingroup non_mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param pred A predicate.
* @return The first iterator @c i in the range @p [first,last)
* such that @p pred(*i) is true, or @p last if no such iterator exists.
*/
template<typename _InputIterator, typename _Predicate>
inline _InputIterator
find_if(_InputIterator __first, _InputIterator __last,
_Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
return std::__find_if(__first, __last, __pred,
std::__iterator_category(__first));
}
/**
* @brief Find element from a set in a sequence.
* @ingroup non_mutating_algorithms
* @param first1 Start of range to search.
* @param last1 End of range to search.
* @param first2 Start of match candidates.
* @param last2 End of match candidates.
* @return The first iterator @c i in the range
* @p [first1,last1) such that @c *i == @p *(i2) such that i2 is an
* iterator in [first2,last2), or @p last1 if no such iterator exists.
*
* Searches the range @p [first1,last1) for an element that is equal to
* some element in the range [first2,last2). If found, returns an iterator
* in the range [first1,last1), otherwise returns @p last1.
*/
template<typename _InputIterator, typename _ForwardIterator>
_InputIterator
find_first_of(_InputIterator __first1, _InputIterator __last1,
_ForwardIterator __first2, _ForwardIterator __last2)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_InputIterator>::value_type,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first1, __last1);
__glibcxx_requires_valid_range(__first2, __last2);
for (; __first1 != __last1; ++__first1)
for (_ForwardIterator __iter = __first2; __iter != __last2; ++__iter)
if (*__first1 == *__iter)
return __first1;
return __last1;
}
/**
* @brief Find element from a set in a sequence using a predicate.
* @ingroup non_mutating_algorithms
* @param first1 Start of range to search.
* @param last1 End of range to search.
* @param first2 Start of match candidates.
* @param last2 End of match candidates.
* @param comp Predicate to use.
* @return The first iterator @c i in the range
* @p [first1,last1) such that @c comp(*i, @p *(i2)) is true and i2 is an
* iterator in [first2,last2), or @p last1 if no such iterator exists.
*
* Searches the range @p [first1,last1) for an element that is
* equal to some element in the range [first2,last2). If found,
* returns an iterator in the range [first1,last1), otherwise
* returns @p last1.
*/
template<typename _InputIterator, typename _ForwardIterator,
typename _BinaryPredicate>
_InputIterator
find_first_of(_InputIterator __first1, _InputIterator __last1,
_ForwardIterator __first2, _ForwardIterator __last2,
_BinaryPredicate __comp)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_BinaryPredicate,
typename iterator_traits<_InputIterator>::value_type,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first1, __last1);
__glibcxx_requires_valid_range(__first2, __last2);
for (; __first1 != __last1; ++__first1)
for (_ForwardIterator __iter = __first2; __iter != __last2; ++__iter)
if (__comp(*__first1, *__iter))
return __first1;
return __last1;
}
/**
* @brief Find two adjacent values in a sequence that are equal.
* @ingroup non_mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @return The first iterator @c i such that @c i and @c i+1 are both
* valid iterators in @p [first,last) and such that @c *i == @c *(i+1),
* or @p last if no such iterator exists.
*/
template<typename _ForwardIterator>
_ForwardIterator
adjacent_find(_ForwardIterator __first, _ForwardIterator __last)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_EqualityComparableConcept<
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __last;
_ForwardIterator __next = __first;
while(++__next != __last)
{
if (*__first == *__next)
return __first;
__first = __next;
}
return __last;
}
/**
* @brief Find two adjacent values in a sequence using a predicate.
* @ingroup non_mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param binary_pred A binary predicate.
* @return The first iterator @c i such that @c i and @c i+1 are both
* valid iterators in @p [first,last) and such that
* @p binary_pred(*i,*(i+1)) is true, or @p last if no such iterator
* exists.
*/
template<typename _ForwardIterator, typename _BinaryPredicate>
_ForwardIterator
adjacent_find(_ForwardIterator __first, _ForwardIterator __last,
_BinaryPredicate __binary_pred)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_BinaryPredicate,
typename iterator_traits<_ForwardIterator>::value_type,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __last;
_ForwardIterator __next = __first;
while(++__next != __last)
{
if (__binary_pred(*__first, *__next))
return __first;
__first = __next;
}
return __last;
}
/**
* @brief Count the number of copies of a value in a sequence.
* @ingroup non_mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param value The value to be counted.
* @return The number of iterators @c i in the range @p [first,last)
* for which @c *i == @p value
*/
template<typename _InputIterator, typename _Tp>
typename iterator_traits<_InputIterator>::difference_type
count(_InputIterator __first, _InputIterator __last, const _Tp& __value)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_InputIterator>::value_type, _Tp>)
__glibcxx_requires_valid_range(__first, __last);
typename iterator_traits<_InputIterator>::difference_type __n = 0;
for (; __first != __last; ++__first)
if (*__first == __value)
++__n;
return __n;
}
/**
* @brief Count the elements of a sequence for which a predicate is true.
* @ingroup non_mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param pred A predicate.
* @return The number of iterators @c i in the range @p [first,last)
* for which @p pred(*i) is true.
*/
template<typename _InputIterator, typename _Predicate>
typename iterator_traits<_InputIterator>::difference_type
count_if(_InputIterator __first, _InputIterator __last, _Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
typename iterator_traits<_InputIterator>::difference_type __n = 0;
for (; __first != __last; ++__first)
if (__pred(*__first))
++__n;
return __n;
}
/**
* @brief Search a sequence for a matching sub-sequence.
* @ingroup non_mutating_algorithms
* @param first1 A forward iterator.
* @param last1 A forward iterator.
* @param first2 A forward iterator.
* @param last2 A forward iterator.
* @return The first iterator @c i in the range
* @p [first1,last1-(last2-first2)) such that @c *(i+N) == @p *(first2+N)
* for each @c N in the range @p [0,last2-first2), or @p last1 if no
* such iterator exists.
*
* Searches the range @p [first1,last1) for a sub-sequence that compares
* equal value-by-value with the sequence given by @p [first2,last2) and
* returns an iterator to the first element of the sub-sequence, or
* @p last1 if the sub-sequence is not found.
*
* Because the sub-sequence must lie completely within the range
* @p [first1,last1) it must start at a position less than
* @p last1-(last2-first2) where @p last2-first2 is the length of the
* sub-sequence.
* This means that the returned iterator @c i will be in the range
* @p [first1,last1-(last2-first2))
*/
template<typename _ForwardIterator1, typename _ForwardIterator2>
_ForwardIterator1
search(_ForwardIterator1 __first1, _ForwardIterator1 __last1,
_ForwardIterator2 __first2, _ForwardIterator2 __last2)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator1>)
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator2>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_ForwardIterator1>::value_type,
typename iterator_traits<_ForwardIterator2>::value_type>)
__glibcxx_requires_valid_range(__first1, __last1);
__glibcxx_requires_valid_range(__first2, __last2);
// Test for empty ranges
if (__first1 == __last1 || __first2 == __last2)
return __first1;
// Test for a pattern of length 1.
_ForwardIterator2 __p1(__first2);
if (++__p1 == __last2)
return _GLIBCXX_STD_A::find(__first1, __last1, *__first2);
// General case.
_ForwardIterator2 __p;
_ForwardIterator1 __current = __first1;
for (;;)
{
__first1 = _GLIBCXX_STD_A::find(__first1, __last1, *__first2);
if (__first1 == __last1)
return __last1;
__p = __p1;
__current = __first1;
if (++__current == __last1)
return __last1;
while (*__current == *__p)
{
if (++__p == __last2)
return __first1;
if (++__current == __last1)
return __last1;
}
++__first1;
}
return __first1;
}
/**
* @brief Search a sequence for a matching sub-sequence using a predicate.
* @ingroup non_mutating_algorithms
* @param first1 A forward iterator.
* @param last1 A forward iterator.
* @param first2 A forward iterator.
* @param last2 A forward iterator.
* @param predicate A binary predicate.
* @return The first iterator @c i in the range
* @p [first1,last1-(last2-first2)) such that
* @p predicate(*(i+N),*(first2+N)) is true for each @c N in the range
* @p [0,last2-first2), or @p last1 if no such iterator exists.
*
* Searches the range @p [first1,last1) for a sub-sequence that compares
* equal value-by-value with the sequence given by @p [first2,last2),
* using @p predicate to determine equality, and returns an iterator
* to the first element of the sub-sequence, or @p last1 if no such
* iterator exists.
*
* @see search(_ForwardIter1, _ForwardIter1, _ForwardIter2, _ForwardIter2)
*/
template<typename _ForwardIterator1, typename _ForwardIterator2,
typename _BinaryPredicate>
_ForwardIterator1
search(_ForwardIterator1 __first1, _ForwardIterator1 __last1,
_ForwardIterator2 __first2, _ForwardIterator2 __last2,
_BinaryPredicate __predicate)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator1>)
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_BinaryPredicate,
typename iterator_traits<_ForwardIterator1>::value_type,
typename iterator_traits<_ForwardIterator2>::value_type>)
__glibcxx_requires_valid_range(__first1, __last1);
__glibcxx_requires_valid_range(__first2, __last2);
// Test for empty ranges
if (__first1 == __last1 || __first2 == __last2)
return __first1;
// Test for a pattern of length 1.
_ForwardIterator2 __p1(__first2);
if (++__p1 == __last2)
{
while (__first1 != __last1
&& !bool(__predicate(*__first1, *__first2)))
++__first1;
return __first1;
}
// General case.
_ForwardIterator2 __p;
_ForwardIterator1 __current = __first1;
for (;;)
{
while (__first1 != __last1
&& !bool(__predicate(*__first1, *__first2)))
++__first1;
if (__first1 == __last1)
return __last1;
__p = __p1;
__current = __first1;
if (++__current == __last1)
return __last1;
while (__predicate(*__current, *__p))
{
if (++__p == __last2)
return __first1;
if (++__current == __last1)
return __last1;
}
++__first1;
}
return __first1;
}
/**
* @brief Search a sequence for a number of consecutive values.
* @ingroup non_mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param count The number of consecutive values.
* @param val The value to find.
* @return The first iterator @c i in the range @p [first,last-count)
* such that @c *(i+N) == @p val for each @c N in the range @p [0,count),
* or @p last if no such iterator exists.
*
* Searches the range @p [first,last) for @p count consecutive elements
* equal to @p val.
*/
template<typename _ForwardIterator, typename _Integer, typename _Tp>
_ForwardIterator
search_n(_ForwardIterator __first, _ForwardIterator __last,
_Integer __count, const _Tp& __val)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_ForwardIterator>::value_type, _Tp>)
__glibcxx_requires_valid_range(__first, __last);
if (__count <= 0)
return __first;
if (__count == 1)
return _GLIBCXX_STD_A::find(__first, __last, __val);
return std::__search_n(__first, __last, __count, __val,
std::__iterator_category(__first));
}
/**
* @brief Search a sequence for a number of consecutive values using a
* predicate.
* @ingroup non_mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param count The number of consecutive values.
* @param val The value to find.
* @param binary_pred A binary predicate.
* @return The first iterator @c i in the range @p [first,last-count)
* such that @p binary_pred(*(i+N),val) is true for each @c N in the
* range @p [0,count), or @p last if no such iterator exists.
*
* Searches the range @p [first,last) for @p count consecutive elements
* for which the predicate returns true.
*/
template<typename _ForwardIterator, typename _Integer, typename _Tp,
typename _BinaryPredicate>
_ForwardIterator
search_n(_ForwardIterator __first, _ForwardIterator __last,
_Integer __count, const _Tp& __val,
_BinaryPredicate __binary_pred)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_BinaryPredicate,
typename iterator_traits<_ForwardIterator>::value_type, _Tp>)
__glibcxx_requires_valid_range(__first, __last);
if (__count <= 0)
return __first;
if (__count == 1)
{
while (__first != __last && !bool(__binary_pred(*__first, __val)))
++__first;
return __first;
}
return std::__search_n(__first, __last, __count, __val, __binary_pred,
std::__iterator_category(__first));
}
/**
* @brief Perform an operation on a sequence.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param result An output iterator.
* @param unary_op A unary operator.
* @return An output iterator equal to @p result+(last-first).
*
* Applies the operator to each element in the input range and assigns
* the results to successive elements of the output sequence.
* Evaluates @p *(result+N)=unary_op(*(first+N)) for each @c N in the
* range @p [0,last-first).
*
* @p unary_op must not alter its argument.
*/
template<typename _InputIterator, typename _OutputIterator,
typename _UnaryOperation>
_OutputIterator
transform(_InputIterator __first, _InputIterator __last,
_OutputIterator __result, _UnaryOperation __unary_op)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
// "the type returned by a _UnaryOperation"
__typeof__(__unary_op(*__first))>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first, ++__result)
*__result = __unary_op(*__first);
return __result;
}
/**
* @brief Perform an operation on corresponding elements of two sequences.
* @ingroup mutating_algorithms
* @param first1 An input iterator.
* @param last1 An input iterator.
* @param first2 An input iterator.
* @param result An output iterator.
* @param binary_op A binary operator.
* @return An output iterator equal to @p result+(last-first).
*
* Applies the operator to the corresponding elements in the two
* input ranges and assigns the results to successive elements of the
* output sequence.
* Evaluates @p *(result+N)=binary_op(*(first1+N),*(first2+N)) for each
* @c N in the range @p [0,last1-first1).
*
* @p binary_op must not alter either of its arguments.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator, typename _BinaryOperation>
_OutputIterator
transform(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _OutputIterator __result,
_BinaryOperation __binary_op)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
// "the type returned by a _BinaryOperation"
__typeof__(__binary_op(*__first1,*__first2))>)
__glibcxx_requires_valid_range(__first1, __last1);
for (; __first1 != __last1; ++__first1, ++__first2, ++__result)
*__result = __binary_op(*__first1, *__first2);
return __result;
}
/**
* @brief Replace each occurrence of one value in a sequence with another
* value.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param old_value The value to be replaced.
* @param new_value The replacement value.
* @return replace() returns no value.
*
* For each iterator @c i in the range @p [first,last) if @c *i ==
* @p old_value then the assignment @c *i = @p new_value is performed.
*/
template<typename _ForwardIterator, typename _Tp>
void
replace(_ForwardIterator __first, _ForwardIterator __last,
const _Tp& __old_value, const _Tp& __new_value)
{
// concept requirements
__glibcxx_function_requires(_Mutable_ForwardIteratorConcept<
_ForwardIterator>)
__glibcxx_function_requires(_EqualOpConcept<
typename iterator_traits<_ForwardIterator>::value_type, _Tp>)
__glibcxx_function_requires(_ConvertibleConcept<_Tp,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first)
if (*__first == __old_value)
*__first = __new_value;
}
/**
* @brief Replace each value in a sequence for which a predicate returns
* true with another value.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param pred A predicate.
* @param new_value The replacement value.
* @return replace_if() returns no value.
*
* For each iterator @c i in the range @p [first,last) if @p pred(*i)
* is true then the assignment @c *i = @p new_value is performed.
*/
template<typename _ForwardIterator, typename _Predicate, typename _Tp>
void
replace_if(_ForwardIterator __first, _ForwardIterator __last,
_Predicate __pred, const _Tp& __new_value)
{
// concept requirements
__glibcxx_function_requires(_Mutable_ForwardIteratorConcept<
_ForwardIterator>)
__glibcxx_function_requires(_ConvertibleConcept<_Tp,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first)
if (__pred(*__first))
*__first = __new_value;
}
/**
* @brief Assign the result of a function object to each value in a
* sequence.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param gen A function object taking no arguments and returning
* std::iterator_traits<_ForwardIterator>::value_type
* @return generate() returns no value.
*
* Performs the assignment @c *i = @p gen() for each @c i in the range
* @p [first,last).
*/
template<typename _ForwardIterator, typename _Generator>
void
generate(_ForwardIterator __first, _ForwardIterator __last,
_Generator __gen)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_GeneratorConcept<_Generator,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
for (; __first != __last; ++__first)
*__first = __gen();
}
/**
* @brief Assign the result of a function object to each value in a
* sequence.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param n The length of the sequence.
* @param gen A function object taking no arguments and returning
* std::iterator_traits<_ForwardIterator>::value_type
* @return The end of the sequence, @p first+n
*
* Performs the assignment @c *i = @p gen() for each @c i in the range
* @p [first,first+n).
*
* _GLIBCXX_RESOLVE_LIB_DEFECTS
* DR 865. More algorithms that throw away information
*/
template<typename _OutputIterator, typename _Size, typename _Generator>
_OutputIterator
generate_n(_OutputIterator __first, _Size __n, _Generator __gen)
{
// concept requirements
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
// "the type returned by a _Generator"
__typeof__(__gen())>)
for (; __n > 0; --__n, ++__first)
*__first = __gen();
return __first;
}
/**
* @brief Copy a sequence, removing consecutive duplicate values.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param result An output iterator.
* @return An iterator designating the end of the resulting sequence.
*
* Copies each element in the range @p [first,last) to the range
* beginning at @p result, except that only the first element is copied
* from groups of consecutive elements that compare equal.
* unique_copy() is stable, so the relative order of elements that are
* copied is unchanged.
*
* _GLIBCXX_RESOLVE_LIB_DEFECTS
* DR 241. Does unique_copy() require CopyConstructible and Assignable?
*
* _GLIBCXX_RESOLVE_LIB_DEFECTS
* DR 538. 241 again: Does unique_copy() require CopyConstructible and
* Assignable?
*/
template<typename _InputIterator, typename _OutputIterator>
inline _OutputIterator
unique_copy(_InputIterator __first, _InputIterator __last,
_OutputIterator __result)
{
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_function_requires(_EqualityComparableConcept<
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __result;
return std::__unique_copy(__first, __last, __result,
std::__iterator_category(__first),
std::__iterator_category(__result));
}
/**
* @brief Copy a sequence, removing consecutive values using a predicate.
* @ingroup mutating_algorithms
* @param first An input iterator.
* @param last An input iterator.
* @param result An output iterator.
* @param binary_pred A binary predicate.
* @return An iterator designating the end of the resulting sequence.
*
* Copies each element in the range @p [first,last) to the range
* beginning at @p result, except that only the first element is copied
* from groups of consecutive elements for which @p binary_pred returns
* true.
* unique_copy() is stable, so the relative order of elements that are
* copied is unchanged.
*
* _GLIBCXX_RESOLVE_LIB_DEFECTS
* DR 241. Does unique_copy() require CopyConstructible and Assignable?
*/
template<typename _InputIterator, typename _OutputIterator,
typename _BinaryPredicate>
inline _OutputIterator
unique_copy(_InputIterator __first, _InputIterator __last,
_OutputIterator __result,
_BinaryPredicate __binary_pred)
{
// concept requirements -- predicates checked later
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
typename iterator_traits<_InputIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __result;
return std::__unique_copy(__first, __last, __result, __binary_pred,
std::__iterator_category(__first),
std::__iterator_category(__result));
}
/**
* @brief Randomly shuffle the elements of a sequence.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @return Nothing.
*
* Reorder the elements in the range @p [first,last) using a random
* distribution, so that every possible ordering of the sequence is
* equally likely.
*/
template<typename _RandomAccessIterator>
inline void
random_shuffle(_RandomAccessIterator __first, _RandomAccessIterator __last)
{
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_requires_valid_range(__first, __last);
if (__first != __last)
for (_RandomAccessIterator __i = __first + 1; __i != __last; ++__i)
std::iter_swap(__i, __first + (std::rand() % ((__i - __first) + 1)));
}
/**
* @brief Shuffle the elements of a sequence using a random number
* generator.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param rand The RNG functor or function.
* @return Nothing.
*
* Reorders the elements in the range @p [first,last) using @p rand to
* provide a random distribution. Calling @p rand(N) for a positive
* integer @p N should return a randomly chosen integer from the
* range [0,N).
*/
template<typename _RandomAccessIterator, typename _RandomNumberGenerator>
void
random_shuffle(_RandomAccessIterator __first, _RandomAccessIterator __last,
#ifdef __GXX_EXPERIMENTAL_CXX0X__
_RandomNumberGenerator&& __rand)
#else
_RandomNumberGenerator& __rand)
#endif
{
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return;
for (_RandomAccessIterator __i = __first + 1; __i != __last; ++__i)
std::iter_swap(__i, __first + __rand((__i - __first) + 1));
}
/**
* @brief Move elements for which a predicate is true to the beginning
* of a sequence.
* @ingroup mutating_algorithms
* @param first A forward iterator.
* @param last A forward iterator.
* @param pred A predicate functor.
* @return An iterator @p middle such that @p pred(i) is true for each
* iterator @p i in the range @p [first,middle) and false for each @p i
* in the range @p [middle,last).
*
* @p pred must not modify its operand. @p partition() does not preserve
* the relative ordering of elements in each group, use
* @p stable_partition() if this is needed.
*/
template<typename _ForwardIterator, typename _Predicate>
inline _ForwardIterator
partition(_ForwardIterator __first, _ForwardIterator __last,
_Predicate __pred)
{
// concept requirements
__glibcxx_function_requires(_Mutable_ForwardIteratorConcept<
_ForwardIterator>)
__glibcxx_function_requires(_UnaryPredicateConcept<_Predicate,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
return std::__partition(__first, __last, __pred,
std::__iterator_category(__first));
}
/**
* @brief Sort the smallest elements of a sequence.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param middle Another iterator.
* @param last Another iterator.
* @return Nothing.
*
* Sorts the smallest @p (middle-first) elements in the range
* @p [first,last) and moves them to the range @p [first,middle). The
* order of the remaining elements in the range @p [middle,last) is
* undefined.
* After the sort if @p i and @j are iterators in the range
* @p [first,middle) such that @i precedes @j and @k is an iterator in
* the range @p [middle,last) then @p *j<*i and @p *k<*i are both false.
*/
template<typename _RandomAccessIterator>
inline void
partial_sort(_RandomAccessIterator __first,
_RandomAccessIterator __middle,
_RandomAccessIterator __last)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<_ValueType>)
__glibcxx_requires_valid_range(__first, __middle);
__glibcxx_requires_valid_range(__middle, __last);
std::__heap_select(__first, __middle, __last);
std::sort_heap(__first, __middle);
}
/**
* @brief Sort the smallest elements of a sequence using a predicate
* for comparison.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param middle Another iterator.
* @param last Another iterator.
* @param comp A comparison functor.
* @return Nothing.
*
* Sorts the smallest @p (middle-first) elements in the range
* @p [first,last) and moves them to the range @p [first,middle). The
* order of the remaining elements in the range @p [middle,last) is
* undefined.
* After the sort if @p i and @j are iterators in the range
* @p [first,middle) such that @i precedes @j and @k is an iterator in
* the range @p [middle,last) then @p *comp(j,*i) and @p comp(*k,*i)
* are both false.
*/
template<typename _RandomAccessIterator, typename _Compare>
inline void
partial_sort(_RandomAccessIterator __first,
_RandomAccessIterator __middle,
_RandomAccessIterator __last,
_Compare __comp)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType, _ValueType>)
__glibcxx_requires_valid_range(__first, __middle);
__glibcxx_requires_valid_range(__middle, __last);
std::__heap_select(__first, __middle, __last, __comp);
std::sort_heap(__first, __middle, __comp);
}
/**
* @brief Sort a sequence just enough to find a particular position.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param nth Another iterator.
* @param last Another iterator.
* @return Nothing.
*
* Rearranges the elements in the range @p [first,last) so that @p *nth
* is the same element that would have been in that position had the
* whole sequence been sorted.
* whole sequence been sorted. The elements either side of @p *nth are
* not completely sorted, but for any iterator @i in the range
* @p [first,nth) and any iterator @j in the range @p [nth,last) it
* holds that @p *j<*i is false.
*/
template<typename _RandomAccessIterator>
inline void
nth_element(_RandomAccessIterator __first, _RandomAccessIterator __nth,
_RandomAccessIterator __last)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<_ValueType>)
__glibcxx_requires_valid_range(__first, __nth);
__glibcxx_requires_valid_range(__nth, __last);
if (__first == __last || __nth == __last)
return;
std::__introselect(__first, __nth, __last,
std::__lg(__last - __first) * 2);
}
/**
* @brief Sort a sequence just enough to find a particular position
* using a predicate for comparison.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param nth Another iterator.
* @param last Another iterator.
* @param comp A comparison functor.
* @return Nothing.
*
* Rearranges the elements in the range @p [first,last) so that @p *nth
* is the same element that would have been in that position had the
* whole sequence been sorted. The elements either side of @p *nth are
* not completely sorted, but for any iterator @i in the range
* @p [first,nth) and any iterator @j in the range @p [nth,last) it
* holds that @p comp(*j,*i) is false.
*/
template<typename _RandomAccessIterator, typename _Compare>
inline void
nth_element(_RandomAccessIterator __first, _RandomAccessIterator __nth,
_RandomAccessIterator __last, _Compare __comp)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType, _ValueType>)
__glibcxx_requires_valid_range(__first, __nth);
__glibcxx_requires_valid_range(__nth, __last);
if (__first == __last || __nth == __last)
return;
std::__introselect(__first, __nth, __last,
std::__lg(__last - __first) * 2, __comp);
}
/**
* @brief Sort the elements of a sequence.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param last Another iterator.
* @return Nothing.
*
* Sorts the elements in the range @p [first,last) in ascending order,
* such that @p *(i+1)<*i is false for each iterator @p i in the range
* @p [first,last-1).
*
* The relative ordering of equivalent elements is not preserved, use
* @p stable_sort() if this is needed.
*/
template<typename _RandomAccessIterator>
inline void
sort(_RandomAccessIterator __first, _RandomAccessIterator __last)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<_ValueType>)
__glibcxx_requires_valid_range(__first, __last);
if (__first != __last)
{
std::__introsort_loop(__first, __last,
std::__lg(__last - __first) * 2);
std::__final_insertion_sort(__first, __last);
}
}
/**
* @brief Sort the elements of a sequence using a predicate for comparison.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param comp A comparison functor.
* @return Nothing.
*
* Sorts the elements in the range @p [first,last) in ascending order,
* such that @p comp(*(i+1),*i) is false for every iterator @p i in the
* range @p [first,last-1).
*
* The relative ordering of equivalent elements is not preserved, use
* @p stable_sort() if this is needed.
*/
template<typename _RandomAccessIterator, typename _Compare>
inline void
sort(_RandomAccessIterator __first, _RandomAccessIterator __last,
_Compare __comp)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare, _ValueType,
_ValueType>)
__glibcxx_requires_valid_range(__first, __last);
if (__first != __last)
{
std::__introsort_loop(__first, __last,
std::__lg(__last - __first) * 2, __comp);
std::__final_insertion_sort(__first, __last, __comp);
}
}
/**
* @brief Merges two sorted ranges.
* @ingroup sorting_algorithms
* @param first1 An iterator.
* @param first2 Another iterator.
* @param last1 Another iterator.
* @param last2 Another iterator.
* @param result An iterator pointing to the end of the merged range.
* @return An iterator pointing to the first element <em>not less
* than</em> @a val.
*
* Merges the ranges [first1,last1) and [first2,last2) into the sorted range
* [result, result + (last1-first1) + (last2-first2)). Both input ranges
* must be sorted, and the output range must not overlap with either of
* the input ranges. The sort is @e stable, that is, for equivalent
* elements in the two ranges, elements from the first range will always
* come before elements from the second.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator>
_OutputIterator
merge(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType2>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set(__first1, __last1, __first2);
__glibcxx_requires_sorted_set(__first2, __last2, __first1);
while (__first1 != __last1 && __first2 != __last2)
{
if (*__first2 < *__first1)
{
*__result = *__first2;
++__first2;
}
else
{
*__result = *__first1;
++__first1;
}
++__result;
}
return std::copy(__first2, __last2, std::copy(__first1, __last1,
__result));
}
/**
* @brief Merges two sorted ranges.
* @ingroup sorting_algorithms
* @param first1 An iterator.
* @param first2 Another iterator.
* @param last1 Another iterator.
* @param last2 Another iterator.
* @param result An iterator pointing to the end of the merged range.
* @param comp A functor to use for comparisons.
* @return An iterator pointing to the first element "not less
* than" @a val.
*
* Merges the ranges [first1,last1) and [first2,last2) into the sorted range
* [result, result + (last1-first1) + (last2-first2)). Both input ranges
* must be sorted, and the output range must not overlap with either of
* the input ranges. The sort is @e stable, that is, for equivalent
* elements in the two ranges, elements from the first range will always
* come before elements from the second.
*
* The comparison function should have the same effects on ordering as
* the function used for the initial sort.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator, typename _Compare>
_OutputIterator
merge(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result, _Compare __comp)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set_pred(__first1, __last1, __first2, __comp);
__glibcxx_requires_sorted_set_pred(__first2, __last2, __first1, __comp);
while (__first1 != __last1 && __first2 != __last2)
{
if (__comp(*__first2, *__first1))
{
*__result = *__first2;
++__first2;
}
else
{
*__result = *__first1;
++__first1;
}
++__result;
}
return std::copy(__first2, __last2, std::copy(__first1, __last1,
__result));
}
/**
* @brief Sort the elements of a sequence, preserving the relative order
* of equivalent elements.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param last Another iterator.
* @return Nothing.
*
* Sorts the elements in the range @p [first,last) in ascending order,
* such that @p *(i+1)<*i is false for each iterator @p i in the range
* @p [first,last-1).
*
* The relative ordering of equivalent elements is preserved, so any two
* elements @p x and @p y in the range @p [first,last) such that
* @p x<y is false and @p y<x is false will have the same relative
* ordering after calling @p stable_sort().
*/
template<typename _RandomAccessIterator>
inline void
stable_sort(_RandomAccessIterator __first, _RandomAccessIterator __last)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
typedef typename iterator_traits<_RandomAccessIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<_ValueType>)
__glibcxx_requires_valid_range(__first, __last);
_Temporary_buffer<_RandomAccessIterator, _ValueType> __buf(__first,
__last);
if (__buf.begin() == 0)
std::__inplace_stable_sort(__first, __last);
else
std::__stable_sort_adaptive(__first, __last, __buf.begin(),
_DistanceType(__buf.size()));
}
/**
* @brief Sort the elements of a sequence using a predicate for comparison,
* preserving the relative order of equivalent elements.
* @ingroup sorting_algorithms
* @param first An iterator.
* @param last Another iterator.
* @param comp A comparison functor.
* @return Nothing.
*
* Sorts the elements in the range @p [first,last) in ascending order,
* such that @p comp(*(i+1),*i) is false for each iterator @p i in the
* range @p [first,last-1).
*
* The relative ordering of equivalent elements is preserved, so any two
* elements @p x and @p y in the range @p [first,last) such that
* @p comp(x,y) is false and @p comp(y,x) is false will have the same
* relative ordering after calling @p stable_sort().
*/
template<typename _RandomAccessIterator, typename _Compare>
inline void
stable_sort(_RandomAccessIterator __first, _RandomAccessIterator __last,
_Compare __comp)
{
typedef typename iterator_traits<_RandomAccessIterator>::value_type
_ValueType;
typedef typename iterator_traits<_RandomAccessIterator>::difference_type
_DistanceType;
// concept requirements
__glibcxx_function_requires(_Mutable_RandomAccessIteratorConcept<
_RandomAccessIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType,
_ValueType>)
__glibcxx_requires_valid_range(__first, __last);
_Temporary_buffer<_RandomAccessIterator, _ValueType> __buf(__first,
__last);
if (__buf.begin() == 0)
std::__inplace_stable_sort(__first, __last, __comp);
else
std::__stable_sort_adaptive(__first, __last, __buf.begin(),
_DistanceType(__buf.size()), __comp);
}
/**
* @brief Return the union of two sorted ranges.
* @ingroup set_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @param last2 End of second range.
* @return End of the output range.
* @ingroup set_algorithms
*
* This operation iterates over both ranges, copying elements present in
* each range in order to the output range. Iterators increment for each
* range. When the current element of one range is less than the other,
* that element is copied and the iterator advanced. If an element is
* contained in both ranges, the element from the first range is copied and
* both ranges advance. The output range may not overlap either input
* range.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator>
_OutputIterator
set_union(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType2>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType1, _ValueType2>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set(__first1, __last1, __first2);
__glibcxx_requires_sorted_set(__first2, __last2, __first1);
while (__first1 != __last1 && __first2 != __last2)
{
if (*__first1 < *__first2)
{
*__result = *__first1;
++__first1;
}
else if (*__first2 < *__first1)
{
*__result = *__first2;
++__first2;
}
else
{
*__result = *__first1;
++__first1;
++__first2;
}
++__result;
}
return std::copy(__first2, __last2, std::copy(__first1, __last1,
__result));
}
/**
* @brief Return the union of two sorted ranges using a comparison functor.
* @ingroup set_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @param last2 End of second range.
* @param comp The comparison functor.
* @return End of the output range.
* @ingroup set_algorithms
*
* This operation iterates over both ranges, copying elements present in
* each range in order to the output range. Iterators increment for each
* range. When the current element of one range is less than the other
* according to @a comp, that element is copied and the iterator advanced.
* If an equivalent element according to @a comp is contained in both
* ranges, the element from the first range is copied and both ranges
* advance. The output range may not overlap either input range.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator, typename _Compare>
_OutputIterator
set_union(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result, _Compare __comp)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType1, _ValueType2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set_pred(__first1, __last1, __first2, __comp);
__glibcxx_requires_sorted_set_pred(__first2, __last2, __first1, __comp);
while (__first1 != __last1 && __first2 != __last2)
{
if (__comp(*__first1, *__first2))
{
*__result = *__first1;
++__first1;
}
else if (__comp(*__first2, *__first1))
{
*__result = *__first2;
++__first2;
}
else
{
*__result = *__first1;
++__first1;
++__first2;
}
++__result;
}
return std::copy(__first2, __last2, std::copy(__first1, __last1,
__result));
}
/**
* @brief Return the intersection of two sorted ranges.
* @ingroup set_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @param last2 End of second range.
* @return End of the output range.
* @ingroup set_algorithms
*
* This operation iterates over both ranges, copying elements present in
* both ranges in order to the output range. Iterators increment for each
* range. When the current element of one range is less than the other,
* that iterator advances. If an element is contained in both ranges, the
* element from the first range is copied and both ranges advance. The
* output range may not overlap either input range.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator>
_OutputIterator
set_intersection(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType1, _ValueType2>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set(__first1, __last1, __first2);
__glibcxx_requires_sorted_set(__first2, __last2, __first1);
while (__first1 != __last1 && __first2 != __last2)
if (*__first1 < *__first2)
++__first1;
else if (*__first2 < *__first1)
++__first2;
else
{
*__result = *__first1;
++__first1;
++__first2;
++__result;
}
return __result;
}
/**
* @brief Return the intersection of two sorted ranges using comparison
* functor.
* @ingroup set_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @param last2 End of second range.
* @param comp The comparison functor.
* @return End of the output range.
* @ingroup set_algorithms
*
* This operation iterates over both ranges, copying elements present in
* both ranges in order to the output range. Iterators increment for each
* range. When the current element of one range is less than the other
* according to @a comp, that iterator advances. If an element is
* contained in both ranges according to @a comp, the element from the
* first range is copied and both ranges advance. The output range may not
* overlap either input range.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator, typename _Compare>
_OutputIterator
set_intersection(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result, _Compare __comp)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType1, _ValueType2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set_pred(__first1, __last1, __first2, __comp);
__glibcxx_requires_sorted_set_pred(__first2, __last2, __first1, __comp);
while (__first1 != __last1 && __first2 != __last2)
if (__comp(*__first1, *__first2))
++__first1;
else if (__comp(*__first2, *__first1))
++__first2;
else
{
*__result = *__first1;
++__first1;
++__first2;
++__result;
}
return __result;
}
/**
* @brief Return the difference of two sorted ranges.
* @ingroup set_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @param last2 End of second range.
* @return End of the output range.
* @ingroup set_algorithms
*
* This operation iterates over both ranges, copying elements present in
* the first range but not the second in order to the output range.
* Iterators increment for each range. When the current element of the
* first range is less than the second, that element is copied and the
* iterator advances. If the current element of the second range is less,
* the iterator advances, but no element is copied. If an element is
* contained in both ranges, no elements are copied and both ranges
* advance. The output range may not overlap either input range.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator>
_OutputIterator
set_difference(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType1, _ValueType2>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set(__first1, __last1, __first2);
__glibcxx_requires_sorted_set(__first2, __last2, __first1);
while (__first1 != __last1 && __first2 != __last2)
if (*__first1 < *__first2)
{
*__result = *__first1;
++__first1;
++__result;
}
else if (*__first2 < *__first1)
++__first2;
else
{
++__first1;
++__first2;
}
return std::copy(__first1, __last1, __result);
}
/**
* @brief Return the difference of two sorted ranges using comparison
* functor.
* @ingroup set_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @param last2 End of second range.
* @param comp The comparison functor.
* @return End of the output range.
* @ingroup set_algorithms
*
* This operation iterates over both ranges, copying elements present in
* the first range but not the second in order to the output range.
* Iterators increment for each range. When the current element of the
* first range is less than the second according to @a comp, that element
* is copied and the iterator advances. If the current element of the
* second range is less, no element is copied and the iterator advances.
* If an element is contained in both ranges according to @a comp, no
* elements are copied and both ranges advance. The output range may not
* overlap either input range.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator, typename _Compare>
_OutputIterator
set_difference(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result, _Compare __comp)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType1, _ValueType2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set_pred(__first1, __last1, __first2, __comp);
__glibcxx_requires_sorted_set_pred(__first2, __last2, __first1, __comp);
while (__first1 != __last1 && __first2 != __last2)
if (__comp(*__first1, *__first2))
{
*__result = *__first1;
++__first1;
++__result;
}
else if (__comp(*__first2, *__first1))
++__first2;
else
{
++__first1;
++__first2;
}
return std::copy(__first1, __last1, __result);
}
/**
* @brief Return the symmetric difference of two sorted ranges.
* @ingroup set_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @param last2 End of second range.
* @return End of the output range.
* @ingroup set_algorithms
*
* This operation iterates over both ranges, copying elements present in
* one range but not the other in order to the output range. Iterators
* increment for each range. When the current element of one range is less
* than the other, that element is copied and the iterator advances. If an
* element is contained in both ranges, no elements are copied and both
* ranges advance. The output range may not overlap either input range.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator>
_OutputIterator
set_symmetric_difference(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType2>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType1, _ValueType2>)
__glibcxx_function_requires(_LessThanOpConcept<_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set(__first1, __last1, __first2);
__glibcxx_requires_sorted_set(__first2, __last2, __first1);
while (__first1 != __last1 && __first2 != __last2)
if (*__first1 < *__first2)
{
*__result = *__first1;
++__first1;
++__result;
}
else if (*__first2 < *__first1)
{
*__result = *__first2;
++__first2;
++__result;
}
else
{
++__first1;
++__first2;
}
return std::copy(__first2, __last2, std::copy(__first1,
__last1, __result));
}
/**
* @brief Return the symmetric difference of two sorted ranges using
* comparison functor.
* @ingroup set_algorithms
* @param first1 Start of first range.
* @param last1 End of first range.
* @param first2 Start of second range.
* @param last2 End of second range.
* @param comp The comparison functor.
* @return End of the output range.
* @ingroup set_algorithms
*
* This operation iterates over both ranges, copying elements present in
* one range but not the other in order to the output range. Iterators
* increment for each range. When the current element of one range is less
* than the other according to @a comp, that element is copied and the
* iterator advances. If an element is contained in both ranges according
* to @a comp, no elements are copied and both ranges advance. The output
* range may not overlap either input range.
*/
template<typename _InputIterator1, typename _InputIterator2,
typename _OutputIterator, typename _Compare>
_OutputIterator
set_symmetric_difference(_InputIterator1 __first1, _InputIterator1 __last1,
_InputIterator2 __first2, _InputIterator2 __last2,
_OutputIterator __result,
_Compare __comp)
{
typedef typename iterator_traits<_InputIterator1>::value_type
_ValueType1;
typedef typename iterator_traits<_InputIterator2>::value_type
_ValueType2;
// concept requirements
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator1>)
__glibcxx_function_requires(_InputIteratorConcept<_InputIterator2>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType1>)
__glibcxx_function_requires(_OutputIteratorConcept<_OutputIterator,
_ValueType2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType1, _ValueType2>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
_ValueType2, _ValueType1>)
__glibcxx_requires_sorted_set_pred(__first1, __last1, __first2, __comp);
__glibcxx_requires_sorted_set_pred(__first2, __last2, __first1, __comp);
while (__first1 != __last1 && __first2 != __last2)
if (__comp(*__first1, *__first2))
{
*__result = *__first1;
++__first1;
++__result;
}
else if (__comp(*__first2, *__first1))
{
*__result = *__first2;
++__first2;
++__result;
}
else
{
++__first1;
++__first2;
}
return std::copy(__first2, __last2,
std::copy(__first1, __last1, __result));
}
/**
* @brief Return the minimum element in a range.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @return Iterator referencing the first instance of the smallest value.
*/
template<typename _ForwardIterator>
_ForwardIterator
min_element(_ForwardIterator __first, _ForwardIterator __last)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __first;
_ForwardIterator __result = __first;
while (++__first != __last)
if (*__first < *__result)
__result = __first;
return __result;
}
/**
* @brief Return the minimum element in a range using comparison functor.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @param comp Comparison functor.
* @return Iterator referencing the first instance of the smallest value
* according to comp.
*/
template<typename _ForwardIterator, typename _Compare>
_ForwardIterator
min_element(_ForwardIterator __first, _ForwardIterator __last,
_Compare __comp)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
typename iterator_traits<_ForwardIterator>::value_type,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __first;
_ForwardIterator __result = __first;
while (++__first != __last)
if (__comp(*__first, *__result))
__result = __first;
return __result;
}
/**
* @brief Return the maximum element in a range.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @return Iterator referencing the first instance of the largest value.
*/
template<typename _ForwardIterator>
_ForwardIterator
max_element(_ForwardIterator __first, _ForwardIterator __last)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_LessThanComparableConcept<
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last)
return __first;
_ForwardIterator __result = __first;
while (++__first != __last)
if (*__result < *__first)
__result = __first;
return __result;
}
/**
* @brief Return the maximum element in a range using comparison functor.
* @ingroup sorting_algorithms
* @param first Start of range.
* @param last End of range.
* @param comp Comparison functor.
* @return Iterator referencing the first instance of the largest value
* according to comp.
*/
template<typename _ForwardIterator, typename _Compare>
_ForwardIterator
max_element(_ForwardIterator __first, _ForwardIterator __last,
_Compare __comp)
{
// concept requirements
__glibcxx_function_requires(_ForwardIteratorConcept<_ForwardIterator>)
__glibcxx_function_requires(_BinaryPredicateConcept<_Compare,
typename iterator_traits<_ForwardIterator>::value_type,
typename iterator_traits<_ForwardIterator>::value_type>)
__glibcxx_requires_valid_range(__first, __last);
if (__first == __last) return __first;
_ForwardIterator __result = __first;
while (++__first != __last)
if (__comp(*__result, *__first))
__result = __first;
return __result;
}
_GLIBCXX_END_NAMESPACE_ALGO
} // namespace std
#endif /* _STL_ALGO_H */
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