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// -*- C++ -*-
// Copyright (C) 2007, 2008, 2009 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/>.
/** @file parallel/partition.h
* @brief Parallel implementation of std::partition(),
* std::nth_element(), and std::partial_sort().
* This file is a GNU parallel extension to the Standard C++ Library.
*/
// Written by Johannes Singler and Felix Putze.
#ifndef _GLIBCXX_PARALLEL_PARTITION_H
#define _GLIBCXX_PARALLEL_PARTITION_H 1
#include <parallel/basic_iterator.h>
#include <parallel/sort.h>
#include <parallel/random_number.h>
#include <bits/stl_algo.h>
#include <parallel/parallel.h>
/** @brief Decide whether to declare certain variables volatile. */
#define _GLIBCXX_VOLATILE volatile
namespace __gnu_parallel
{
/** @brief Parallel implementation of std::partition.
* @param __begin Begin iterator of input sequence to split.
* @param __end End iterator of input sequence to split.
* @param __pred Partition predicate, possibly including some kind of pivot.
* @param __num_threads Maximum number of threads to use for this task.
* @return Number of elements not fulfilling the predicate. */
template<typename _RAIter, typename _Predicate>
typename std::iterator_traits<_RAIter>::difference_type
__parallel_partition(_RAIter __begin, _RAIter __end,
_Predicate __pred, _ThreadIndex __num_threads)
{
typedef std::iterator_traits<_RAIter> _TraitsType;
typedef typename _TraitsType::value_type _ValueType;
typedef typename _TraitsType::difference_type _DifferenceType;
_DifferenceType __n = __end - __begin;
_GLIBCXX_CALL(__n)
const _Settings& __s = _Settings::get();
// Shared.
_GLIBCXX_VOLATILE _DifferenceType __left = 0, __right = __n - 1;
_GLIBCXX_VOLATILE _DifferenceType __leftover_left, __leftover_right;
_GLIBCXX_VOLATILE _DifferenceType __leftnew, __rightnew;
bool* __reserved_left = NULL, * __reserved_right = NULL;
_DifferenceType __chunk_size;
omp_lock_t __result_lock;
omp_init_lock(&__result_lock);
//at least two chunks per thread
if(__right - __left + 1 >= 2 * __num_threads * __chunk_size)
# pragma omp parallel num_threads(__num_threads)
{
# pragma omp single
{
__num_threads = omp_get_num_threads();
__reserved_left = new bool[__num_threads];
__reserved_right = new bool[__num_threads];
if (__s.partition_chunk_share > 0.0)
__chunk_size = std::max<_DifferenceType>(
__s.partition_chunk_size,
(double)__n * __s.partition_chunk_share /
(double)__num_threads);
else
__chunk_size = __s.partition_chunk_size;
}
while (__right - __left + 1 >= 2 * __num_threads * __chunk_size)
{
# pragma omp single
{
_DifferenceType __num_chunks
= (__right - __left + 1) / __chunk_size;
for (int __r = 0; __r < __num_threads; ++__r)
{
__reserved_left[__r] = false;
__reserved_right[__r] = false;
}
__leftover_left = 0;
__leftover_right = 0;
} //implicit barrier
// Private.
_DifferenceType __thread_left, __thread_left_border,
__thread_right, __thread_right_border;
__thread_left = __left + 1;
// Just to satisfy the condition below.
__thread_left_border = __thread_left - 1;
__thread_right = __n - 1;
__thread_right_border = __thread_right + 1;
bool __iam_finished = false;
while (!__iam_finished)
{
if (__thread_left > __thread_left_border)
{
omp_set_lock(&__result_lock);
if (__left + (__chunk_size - 1) > __right)
__iam_finished = true;
else
{
__thread_left = __left;
__thread_left_border = __left + (__chunk_size - 1);
__left += __chunk_size;
}
omp_unset_lock(&__result_lock);
}
if (__thread_right < __thread_right_border)
{
omp_set_lock(&__result_lock);
if (__left > __right - (__chunk_size - 1))
__iam_finished = true;
else
{
__thread_right = __right;
__thread_right_border = __right - (__chunk_size - 1);
__right -= __chunk_size;
}
omp_unset_lock(&__result_lock);
}
if (__iam_finished)
break;
// Swap as usual.
while (__thread_left < __thread_right)
{
while (__pred(__begin[__thread_left])
&& __thread_left <= __thread_left_border)
++__thread_left;
while (!__pred(__begin[__thread_right])
&& __thread_right >= __thread_right_border)
--__thread_right;
if (__thread_left > __thread_left_border
|| __thread_right < __thread_right_border)
// Fetch new chunk(__s).
break;
std::swap(__begin[__thread_left], __begin[__thread_right]);
++__thread_left;
--__thread_right;
}
}
// Now swap the leftover chunks to the right places.
if (__thread_left <= __thread_left_border)
# pragma omp atomic
++__leftover_left;
if (__thread_right >= __thread_right_border)
# pragma omp atomic
++__leftover_right;
# pragma omp barrier
# pragma omp single
{
__leftnew = __left - __leftover_left * __chunk_size;
__rightnew = __right + __leftover_right * __chunk_size;
}
# pragma omp barrier
// <=> __thread_left_border + (__chunk_size - 1) >= __leftnew
if (__thread_left <= __thread_left_border
&& __thread_left_border >= __leftnew)
{
// Chunk already in place, reserve spot.
__reserved_left
[(__left - (__thread_left_border + 1)) / __chunk_size]
= true;
}
// <=> __thread_right_border - (__chunk_size - 1) <= __rightnew
if (__thread_right >= __thread_right_border
&& __thread_right_border <= __rightnew)
{
// Chunk already in place, reserve spot.
__reserved_right[((__thread_right_border - 1) - __right)
/ __chunk_size] = true;
}
# pragma omp barrier
if (__thread_left <= __thread_left_border
&& __thread_left_border < __leftnew)
{
// Find spot and swap.
_DifferenceType __swapstart = -1;
omp_set_lock(&__result_lock);
for (int __r = 0; __r < __leftover_left; ++__r)
if (!__reserved_left[__r])
{
__reserved_left[__r] = true;
__swapstart = __left - (__r + 1) * __chunk_size;
break;
}
omp_unset_lock(&__result_lock);
#if _GLIBCXX_ASSERTIONS
_GLIBCXX_PARALLEL_ASSERT(__swapstart != -1);
#endif
std::swap_ranges(__begin + __thread_left_border
- (__chunk_size - 1),
__begin + __thread_left_border + 1,
__begin + __swapstart);
}
if (__thread_right >= __thread_right_border
&& __thread_right_border > __rightnew)
{
// Find spot and swap
_DifferenceType __swapstart = -1;
omp_set_lock(&__result_lock);
for (int __r = 0; __r < __leftover_right; ++__r)
if (!__reserved_right[__r])
{
__reserved_right[__r] = true;
__swapstart = __right + __r * __chunk_size + 1;
break;
}
omp_unset_lock(&__result_lock);
#if _GLIBCXX_ASSERTIONS
_GLIBCXX_PARALLEL_ASSERT(__swapstart != -1);
#endif
std::swap_ranges(
__begin + __thread_right_border,
__begin + __thread_right_border + __chunk_size,
__begin + __swapstart);
}
#if _GLIBCXX_ASSERTIONS
# pragma omp barrier
# pragma omp single
{
for (int __r = 0; __r < __leftover_left; ++__r)
_GLIBCXX_PARALLEL_ASSERT(__reserved_left[__r]);
for (int __r = 0; __r < __leftover_right; ++__r)
_GLIBCXX_PARALLEL_ASSERT(__reserved_right[__r]);
}
# pragma omp barrier
#endif
# pragma omp barrier
__left = __leftnew;
__right = __rightnew;
}
# pragma omp flush(__left, __right)
} // end "recursion" //parallel
_DifferenceType __final_left = __left, __final_right = __right;
while (__final_left < __final_right)
{
// Go right until key is geq than pivot.
while (__pred(__begin[__final_left]) && __final_left < __final_right)
++__final_left;
// Go left until key is less than pivot.
while (!__pred(__begin[__final_right]) && __final_left < __final_right)
--__final_right;
if (__final_left == __final_right)
break;
std::swap(__begin[__final_left], __begin[__final_right]);
++__final_left;
--__final_right;
}
// All elements on the left side are < piv, all elements on the
// right are >= piv
delete[] __reserved_left;
delete[] __reserved_right;
omp_destroy_lock(&__result_lock);
// Element "between" __final_left and __final_right might not have
// been regarded yet
if (__final_left < __n && !__pred(__begin[__final_left]))
// Really swapped.
return __final_left;
else
return __final_left + 1;
}
/**
* @brief Parallel implementation of std::nth_element().
* @param __begin Begin iterator of input sequence.
* @param __nth _Iterator of element that must be in position afterwards.
* @param __end End iterator of input sequence.
* @param __comp Comparator.
*/
template<typename _RAIter, typename _Compare>
void
__parallel_nth_element(_RAIter __begin, _RAIter __nth,
_RAIter __end, _Compare __comp)
{
typedef std::iterator_traits<_RAIter> _TraitsType;
typedef typename _TraitsType::value_type _ValueType;
typedef typename _TraitsType::difference_type _DifferenceType;
_GLIBCXX_CALL(__end - __begin)
_RAIter __split;
_RandomNumber __rng;
_DifferenceType __minimum_length =
std::max<_DifferenceType>(2, _Settings::get().partition_minimal_n);
// Break if input range to small.
while (static_cast<_SequenceIndex>(__end - __begin) >= __minimum_length)
{
_DifferenceType __n = __end - __begin;
_RAIter __pivot_pos = __begin + __rng(__n);
// Swap __pivot_pos value to end.
if (__pivot_pos != (__end - 1))
std::swap(*__pivot_pos, *(__end - 1));
__pivot_pos = __end - 1;
// _Compare must have first_value_type, second_value_type,
// result_type
// _Compare ==
// __gnu_parallel::_Lexicographic<S, int, __gnu_parallel::_Less<S, S> >
// __pivot_pos == std::pair<S, int>*
__gnu_parallel::binder2nd<_Compare, _ValueType, _ValueType, bool>
__pred(__comp, *__pivot_pos);
// Divide, leave pivot unchanged in last place.
_RAIter __split_pos1, __split_pos2;
__split_pos1 = __begin
+ __parallel_partition(__begin, __end - 1, __pred,
__get_max_threads());
// Left side: < __pivot_pos; __right side: >= __pivot_pos
// Swap pivot back to middle.
if (__split_pos1 != __pivot_pos)
std::swap(*__split_pos1, *__pivot_pos);
__pivot_pos = __split_pos1;
// In case all elements are equal, __split_pos1 == 0
if ((__split_pos1 + 1 - __begin) < (__n >> 7)
|| (__end - __split_pos1) < (__n >> 7))
{
// Very unequal split, one part smaller than one 128th
// elements not strictly larger than the pivot.
__gnu_parallel::__unary_negate<__gnu_parallel::
__binder1st<_Compare, _ValueType, _ValueType, bool>, _ValueType>
__pred(__gnu_parallel::__binder1st<_Compare, _ValueType,
_ValueType, bool>(__comp, *__pivot_pos));
// Find other end of pivot-equal range.
__split_pos2 = __gnu_sequential::partition(__split_pos1 + 1,
__end, __pred);
}
else
// Only skip the pivot.
__split_pos2 = __split_pos1 + 1;
// Compare iterators.
if (__split_pos2 <= __nth)
__begin = __split_pos2;
else if (__nth < __split_pos1)
__end = __split_pos1;
else
break;
}
// Only at most _Settings::partition_minimal_n __elements __left.
__gnu_sequential::sort(__begin, __end, __comp);
}
/** @brief Parallel implementation of std::partial_sort().
* @param __begin Begin iterator of input sequence.
* @param __middle Sort until this position.
* @param __end End iterator of input sequence.
* @param __comp Comparator. */
template<typename _RAIter, typename _Compare>
void
__parallel_partial_sort(_RAIter __begin,
_RAIter __middle,
_RAIter __end, _Compare __comp)
{
__parallel_nth_element(__begin, __middle, __end, __comp);
std::sort(__begin, __middle, __comp);
}
} //namespace __gnu_parallel
#undef _GLIBCXX_VOLATILE
#endif /* _GLIBCXX_PARALLEL_PARTITION_H */
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