arm-buildroot-linux-gnueabi/include/c++/4.9.1/parallel/multiseq_selection.h - toolchains/mindspeed - Git at Google

 // -*- C++ -*-

 // Copyright (C) 2007-2014 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/multiseq_selection.h
  *  @brief Functions to find elements of a certain global __rank in
  *  multiple sorted sequences.  Also serves for splitting such
  *  sequence sets.
  *
  *  The algorithm description can be found in
  *
  *  P. J. Varman, S. D. Scheufler, B. R. Iyer, and G. R. Ricard.
  *  Merging Multiple Lists on Hierarchical-Memory Multiprocessors.
  *  Journal of Parallel and Distributed Computing, 12(2):171–177, 1991.
  *
  *  This file is a GNU parallel extension to the Standard C++ Library.
  */

 // Written by Johannes Singler.

 #ifndef _GLIBCXX_PARALLEL_MULTISEQ_SELECTION_H
 #define _GLIBCXX_PARALLEL_MULTISEQ_SELECTION_H 1

 #include <vector>
 #include <queue>

 #include <bits/stl_algo.h>

 namespace __gnu_parallel
 {
   /** @brief Compare __a pair of types lexicographically, ascending. */
   template<typename _T1, typename _T2, typename _Compare>
     class _Lexicographic
     : public std::binary_function<std::pair<_T1, _T2>,
 				  std::pair<_T1, _T2>, bool>
     {
     private:
       _Compare& _M_comp;

     public:
       _Lexicographic(_Compare& __comp) : _M_comp(__comp) { }

       bool
       operator()(const std::pair<_T1, _T2>& __p1,
                  const std::pair<_T1, _T2>& __p2) const
       {
         if (_M_comp(__p1.first, __p2.first))
           return true;

         if (_M_comp(__p2.first, __p1.first))
           return false;

         // Firsts are equal.
         return __p1.second < __p2.second;
       }
     };

   /** @brief Compare __a pair of types lexicographically, descending. */
   template<typename _T1, typename _T2, typename _Compare>
     class _LexicographicReverse : public std::binary_function<_T1, _T2, bool>
     {
     private:
       _Compare& _M_comp;

     public:
       _LexicographicReverse(_Compare& __comp) : _M_comp(__comp) { }

       bool
       operator()(const std::pair<_T1, _T2>& __p1,
                  const std::pair<_T1, _T2>& __p2) const
       {
         if (_M_comp(__p2.first, __p1.first))
           return true;

         if (_M_comp(__p1.first, __p2.first))
           return false;

         // Firsts are equal.
         return __p2.second < __p1.second;
       }
     };

   /**
    *  @brief Splits several sorted sequences at a certain global __rank,
    *  resulting in a splitting point for each sequence.
    *  The sequences are passed via a sequence of random-access
    *  iterator pairs, none of the sequences may be empty.  If there
    *  are several equal elements across the split, the ones on the
    *  __left side will be chosen from sequences with smaller number.
    *  @param __begin_seqs Begin of the sequence of iterator pairs.
    *  @param __end_seqs End of the sequence of iterator pairs.
    *  @param __rank The global rank to partition at.
    *  @param __begin_offsets A random-access __sequence __begin where the
    *  __result will be stored in. Each element of the sequence is an
    *  iterator that points to the first element on the greater part of
    *  the respective __sequence.
    *  @param __comp The ordering functor, defaults to std::less<_Tp>.
    */
   template<typename _RanSeqs, typename _RankType, typename _RankIterator,
             typename _Compare>
     void
     multiseq_partition(_RanSeqs __begin_seqs, _RanSeqs __end_seqs,
                        _RankType __rank,
                        _RankIterator __begin_offsets,
                        _Compare __comp = std::less<
                        typename std::iterator_traits<typename
                        std::iterator_traits<_RanSeqs>::value_type::
                        first_type>::value_type>()) // std::less<_Tp>
     {
       _GLIBCXX_CALL(__end_seqs - __begin_seqs)

       typedef typename std::iterator_traits<_RanSeqs>::value_type::first_type
         _It;
       typedef typename std::iterator_traits<_RanSeqs>::difference_type
         _SeqNumber;
       typedef typename std::iterator_traits<_It>::difference_type
                _DifferenceType;
       typedef typename std::iterator_traits<_It>::value_type _ValueType;

       _Lexicographic<_ValueType, _SeqNumber, _Compare> __lcomp(__comp);
       _LexicographicReverse<_ValueType, _SeqNumber, _Compare> __lrcomp(__comp);

       // Number of sequences, number of elements in total (possibly
       // including padding).
       _DifferenceType __m = std::distance(__begin_seqs, __end_seqs), __nn = 0,
                       __nmax, __n, __r;

       for (_SeqNumber __i = 0; __i < __m; __i++)
         {
           __nn += std::distance(__begin_seqs[__i].first,
                                __begin_seqs[__i].second);
           _GLIBCXX_PARALLEL_ASSERT(
             std::distance(__begin_seqs[__i].first,
                           __begin_seqs[__i].second) > 0);
         }

       if (__rank == __nn)
         {
           for (_SeqNumber __i = 0; __i < __m; __i++)
             __begin_offsets[__i] = __begin_seqs[__i].second; // Very end.
           // Return __m - 1;
           return;
         }

       _GLIBCXX_PARALLEL_ASSERT(__m != 0);
       _GLIBCXX_PARALLEL_ASSERT(__nn != 0);
       _GLIBCXX_PARALLEL_ASSERT(__rank >= 0);
       _GLIBCXX_PARALLEL_ASSERT(__rank < __nn);

       _DifferenceType* __ns = new _DifferenceType[__m];
       _DifferenceType* __a = new _DifferenceType[__m];
       _DifferenceType* __b = new _DifferenceType[__m];
       _DifferenceType __l;

       __ns[0] = std::distance(__begin_seqs[0].first, __begin_seqs[0].second);
       __nmax = __ns[0];
       for (_SeqNumber __i = 0; __i < __m; __i++)
         {
           __ns[__i] = std::distance(__begin_seqs[__i].first,
                                     __begin_seqs[__i].second);
           __nmax = std::max(__nmax, __ns[__i]);
         }

       __r = __rd_log2(__nmax) + 1;

       // Pad all lists to this length, at least as long as any ns[__i],
       // equality iff __nmax = 2^__k - 1.
       __l = (1ULL << __r) - 1;

       for (_SeqNumber __i = 0; __i < __m; __i++)
         {
           __a[__i] = 0;
           __b[__i] = __l;
         }
       __n = __l / 2;

       // Invariants:
       // 0 <= __a[__i] <= __ns[__i], 0 <= __b[__i] <= __l

 #define __S(__i) (__begin_seqs[__i].first)

       // Initial partition.
       std::vector<std::pair<_ValueType, _SeqNumber> > __sample;

       for (_SeqNumber __i = 0; __i < __m; __i++)
         if (__n < __ns[__i])    //__sequence long enough
           __sample.push_back(std::make_pair(__S(__i)[__n], __i));
       __gnu_sequential::sort(__sample.begin(), __sample.end(), __lcomp);

       for (_SeqNumber __i = 0; __i < __m; __i++)       //conceptual infinity
         if (__n >= __ns[__i])   //__sequence too short, conceptual infinity
           __sample.push_back(
             std::make_pair(__S(__i)[0] /*__dummy element*/, __i));

       _DifferenceType __localrank = __rank / __l;

       _SeqNumber __j;
       for (__j = 0;
            __j < __localrank && ((__n + 1) <= __ns[__sample[__j].second]);
            ++__j)
         __a[__sample[__j].second] += __n + 1;
       for (; __j < __m; __j++)
         __b[__sample[__j].second] -= __n + 1;

       // Further refinement.
       while (__n > 0)
         {
           __n /= 2;

           _SeqNumber __lmax_seq = -1;  // to avoid warning
           const _ValueType* __lmax = 0; // impossible to avoid the warning?
           for (_SeqNumber __i = 0; __i < __m; __i++)
             {
               if (__a[__i] > 0)
                 {
                   if (!__lmax)
                     {
                       __lmax = &(__S(__i)[__a[__i] - 1]);
                       __lmax_seq = __i;
                     }
                   else
                     {
                       // Max, favor rear sequences.
                       if (!__comp(__S(__i)[__a[__i] - 1], *__lmax))
                         {
                           __lmax = &(__S(__i)[__a[__i] - 1]);
                           __lmax_seq = __i;
                         }
                     }
                 }
             }

           _SeqNumber __i;
           for (__i = 0; __i < __m; __i++)
             {
               _DifferenceType __middle = (__b[__i] + __a[__i]) / 2;
               if (__lmax && __middle < __ns[__i] &&
                   __lcomp(std::make_pair(__S(__i)[__middle], __i),
                         std::make_pair(*__lmax, __lmax_seq)))
                 __a[__i] = std::min(__a[__i] + __n + 1, __ns[__i]);
               else
                 __b[__i] -= __n + 1;
             }

           _DifferenceType __leftsize = 0;
           for (_SeqNumber __i = 0; __i < __m; __i++)
               __leftsize += __a[__i] / (__n + 1);

           _DifferenceType __skew = __rank / (__n + 1) - __leftsize;

           if (__skew > 0)
             {
               // Move to the left, find smallest.
               std::priority_queue<std::pair<_ValueType, _SeqNumber>,
                 std::vector<std::pair<_ValueType, _SeqNumber> >,
                 _LexicographicReverse<_ValueType, _SeqNumber, _Compare> >
                 __pq(__lrcomp);

               for (_SeqNumber __i = 0; __i < __m; __i++)
                 if (__b[__i] < __ns[__i])
                   __pq.push(std::make_pair(__S(__i)[__b[__i]], __i));

               for (; __skew != 0 && !__pq.empty(); --__skew)
                 {
                   _SeqNumber __source = __pq.top().second;
                   __pq.pop();

                   __a[__source]
                       = std::min(__a[__source] + __n + 1, __ns[__source]);
                   __b[__source] += __n + 1;

                   if (__b[__source] < __ns[__source])
                     __pq.push(
                       std::make_pair(__S(__source)[__b[__source]], __source));
                 }
             }
           else if (__skew < 0)
             {
               // Move to the right, find greatest.
               std::priority_queue<std::pair<_ValueType, _SeqNumber>,
                 std::vector<std::pair<_ValueType, _SeqNumber> >,
                 _Lexicographic<_ValueType, _SeqNumber, _Compare> >
                   __pq(__lcomp);

               for (_SeqNumber __i = 0; __i < __m; __i++)
                 if (__a[__i] > 0)
                   __pq.push(std::make_pair(__S(__i)[__a[__i] - 1], __i));

               for (; __skew != 0; ++__skew)
                 {
                   _SeqNumber __source = __pq.top().second;
                   __pq.pop();

                   __a[__source] -= __n + 1;
                   __b[__source] -= __n + 1;

                   if (__a[__source] > 0)
                     __pq.push(std::make_pair(
                         __S(__source)[__a[__source] - 1], __source));
                 }
             }
         }

       // Postconditions:
       // __a[__i] == __b[__i] in most cases, except when __a[__i] has been
       // clamped because of having reached the boundary

       // Now return the result, calculate the offset.

       // Compare the keys on both edges of the border.

       // Maximum of left edge, minimum of right edge.
       _ValueType* __maxleft = 0;
       _ValueType* __minright = 0;
       for (_SeqNumber __i = 0; __i < __m; __i++)
         {
           if (__a[__i] > 0)
             {
               if (!__maxleft)
                 __maxleft = &(__S(__i)[__a[__i] - 1]);
               else
                 {
                   // Max, favor rear sequences.
                   if (!__comp(__S(__i)[__a[__i] - 1], *__maxleft))
                     __maxleft = &(__S(__i)[__a[__i] - 1]);
                 }
             }
           if (__b[__i] < __ns[__i])
             {
               if (!__minright)
                 __minright = &(__S(__i)[__b[__i]]);
               else
                 {
                   // Min, favor fore sequences.
                   if (__comp(__S(__i)[__b[__i]], *__minright))
                     __minright = &(__S(__i)[__b[__i]]);
                 }
             }
         }

       _SeqNumber __seq = 0;
       for (_SeqNumber __i = 0; __i < __m; __i++)
         __begin_offsets[__i] = __S(__i) + __a[__i];

       delete[] __ns;
       delete[] __a;
       delete[] __b;
     }


   /**
    *  @brief Selects the element at a certain global __rank from several
    *  sorted sequences.
    *
    *  The sequences are passed via a sequence of random-access
    *  iterator pairs, none of the sequences may be empty.
    *  @param __begin_seqs Begin of the sequence of iterator pairs.
    *  @param __end_seqs End of the sequence of iterator pairs.
    *  @param __rank The global rank to partition at.
    *  @param __offset The rank of the selected element in the global
    *  subsequence of elements equal to the selected element. If the
    *  selected element is unique, this number is 0.
    *  @param __comp The ordering functor, defaults to std::less.
    */
   template<typename _Tp, typename _RanSeqs, typename _RankType,
            typename _Compare>
     _Tp
     multiseq_selection(_RanSeqs __begin_seqs, _RanSeqs __end_seqs,
                        _RankType __rank,
                        _RankType& __offset, _Compare __comp = std::less<_Tp>())
     {
       _GLIBCXX_CALL(__end_seqs - __begin_seqs)

       typedef typename std::iterator_traits<_RanSeqs>::value_type::first_type
         _It;
       typedef typename std::iterator_traits<_RanSeqs>::difference_type
         _SeqNumber;
       typedef typename std::iterator_traits<_It>::difference_type
         _DifferenceType;

       _Lexicographic<_Tp, _SeqNumber, _Compare> __lcomp(__comp);
       _LexicographicReverse<_Tp, _SeqNumber, _Compare> __lrcomp(__comp);

       // Number of sequences, number of elements in total (possibly
       // including padding).
       _DifferenceType __m = std::distance(__begin_seqs, __end_seqs);
       _DifferenceType __nn = 0;
       _DifferenceType __nmax, __n, __r;

       for (_SeqNumber __i = 0; __i < __m; __i++)
         __nn += std::distance(__begin_seqs[__i].first,
 			      __begin_seqs[__i].second);

       if (__m == 0 || __nn == 0 || __rank < 0 || __rank >= __nn)
         {
           // result undefined if there is no data or __rank is outside bounds
           throw std::exception();
         }


       _DifferenceType* __ns = new _DifferenceType[__m];
       _DifferenceType* __a = new _DifferenceType[__m];
       _DifferenceType* __b = new _DifferenceType[__m];
       _DifferenceType __l;

       __ns[0] = std::distance(__begin_seqs[0].first, __begin_seqs[0].second);
       __nmax = __ns[0];
       for (_SeqNumber __i = 0; __i < __m; ++__i)
         {
           __ns[__i] = std::distance(__begin_seqs[__i].first,
                                     __begin_seqs[__i].second);
           __nmax = std::max(__nmax, __ns[__i]);
         }

       __r = __rd_log2(__nmax) + 1;

       // Pad all lists to this length, at least as long as any ns[__i],
       // equality iff __nmax = 2^__k - 1
       __l = __round_up_to_pow2(__r) - 1;

       for (_SeqNumber __i = 0; __i < __m; ++__i)
         {
           __a[__i] = 0;
           __b[__i] = __l;
         }
       __n = __l / 2;

       // Invariants:
       // 0 <= __a[__i] <= __ns[__i], 0 <= __b[__i] <= __l

 #define __S(__i) (__begin_seqs[__i].first)

       // Initial partition.
       std::vector<std::pair<_Tp, _SeqNumber> > __sample;

       for (_SeqNumber __i = 0; __i < __m; __i++)
         if (__n < __ns[__i])
           __sample.push_back(std::make_pair(__S(__i)[__n], __i));
       __gnu_sequential::sort(__sample.begin(), __sample.end(),
                              __lcomp, sequential_tag());

       // Conceptual infinity.
       for (_SeqNumber __i = 0; __i < __m; __i++)
         if (__n >= __ns[__i])
           __sample.push_back(
             std::make_pair(__S(__i)[0] /*__dummy element*/, __i));

       _DifferenceType __localrank = __rank / __l;

       _SeqNumber __j;
       for (__j = 0;
            __j < __localrank && ((__n + 1) <= __ns[__sample[__j].second]);
            ++__j)
         __a[__sample[__j].second] += __n + 1;
       for (; __j < __m; ++__j)
         __b[__sample[__j].second] -= __n + 1;

       // Further refinement.
       while (__n > 0)
         {
           __n /= 2;

           const _Tp* __lmax = 0;
           for (_SeqNumber __i = 0; __i < __m; ++__i)
             {
               if (__a[__i] > 0)
                 {
                   if (!__lmax)
                     __lmax = &(__S(__i)[__a[__i] - 1]);
                   else
                     {
                       if (__comp(*__lmax, __S(__i)[__a[__i] - 1]))      //max
                         __lmax = &(__S(__i)[__a[__i] - 1]);
                     }
                 }
             }

           _SeqNumber __i;
           for (__i = 0; __i < __m; __i++)
             {
               _DifferenceType __middle = (__b[__i] + __a[__i]) / 2;
               if (__lmax && __middle < __ns[__i]
                   && __comp(__S(__i)[__middle], *__lmax))
                 __a[__i] = std::min(__a[__i] + __n + 1, __ns[__i]);
               else
                 __b[__i] -= __n + 1;
             }

           _DifferenceType __leftsize = 0;
           for (_SeqNumber __i = 0; __i < __m; ++__i)
               __leftsize += __a[__i] / (__n + 1);

           _DifferenceType __skew = __rank / (__n + 1) - __leftsize;

           if (__skew > 0)
             {
               // Move to the left, find smallest.
               std::priority_queue<std::pair<_Tp, _SeqNumber>,
                 std::vector<std::pair<_Tp, _SeqNumber> >,
                 _LexicographicReverse<_Tp, _SeqNumber, _Compare> >
                   __pq(__lrcomp);

               for (_SeqNumber __i = 0; __i < __m; ++__i)
                 if (__b[__i] < __ns[__i])
                   __pq.push(std::make_pair(__S(__i)[__b[__i]], __i));

               for (; __skew != 0 && !__pq.empty(); --__skew)
                 {
                   _SeqNumber __source = __pq.top().second;
                   __pq.pop();

                   __a[__source]
                       = std::min(__a[__source] + __n + 1, __ns[__source]);
                   __b[__source] += __n + 1;

                   if (__b[__source] < __ns[__source])
                     __pq.push(
                       std::make_pair(__S(__source)[__b[__source]], __source));
                 }
             }
           else if (__skew < 0)
             {
               // Move to the right, find greatest.
               std::priority_queue<std::pair<_Tp, _SeqNumber>,
                 std::vector<std::pair<_Tp, _SeqNumber> >,
                 _Lexicographic<_Tp, _SeqNumber, _Compare> > __pq(__lcomp);

               for (_SeqNumber __i = 0; __i < __m; ++__i)
                 if (__a[__i] > 0)
                   __pq.push(std::make_pair(__S(__i)[__a[__i] - 1], __i));

               for (; __skew != 0; ++__skew)
                 {
                   _SeqNumber __source = __pq.top().second;
                   __pq.pop();

                   __a[__source] -= __n + 1;
                   __b[__source] -= __n + 1;

                   if (__a[__source] > 0)
                     __pq.push(std::make_pair(
                         __S(__source)[__a[__source] - 1], __source));
                 }
             }
         }

       // Postconditions:
       // __a[__i] == __b[__i] in most cases, except when __a[__i] has been
       // clamped because of having reached the boundary

       // Now return the result, calculate the offset.

       // Compare the keys on both edges of the border.

       // Maximum of left edge, minimum of right edge.
       bool __maxleftset = false, __minrightset = false;

       // Impossible to avoid the warning?
       _Tp __maxleft, __minright;
       for (_SeqNumber __i = 0; __i < __m; ++__i)
         {
           if (__a[__i] > 0)
             {
               if (!__maxleftset)
                 {
                   __maxleft = __S(__i)[__a[__i] - 1];
                   __maxleftset = true;
                 }
               else
                 {
                   // Max.
                   if (__comp(__maxleft, __S(__i)[__a[__i] - 1]))
                     __maxleft = __S(__i)[__a[__i] - 1];
                 }
             }
           if (__b[__i] < __ns[__i])
             {
               if (!__minrightset)
                 {
                   __minright = __S(__i)[__b[__i]];
                   __minrightset = true;
                 }
               else
                 {
                   // Min.
                   if (__comp(__S(__i)[__b[__i]], __minright))
                     __minright = __S(__i)[__b[__i]];
                 }
             }
       }

       // Minright is the __splitter, in any case.

       if (!__maxleftset || __comp(__minright, __maxleft))
         {
           // Good luck, everything is split unambiguously.
           __offset = 0;
         }
       else
         {
           // We have to calculate an offset.
           __offset = 0;

           for (_SeqNumber __i = 0; __i < __m; ++__i)
             {
               _DifferenceType lb
                 = std::lower_bound(__S(__i), __S(__i) + __ns[__i],
                                    __minright,
                                    __comp) - __S(__i);
               __offset += __a[__i] - lb;
             }
         }

       delete[] __ns;
       delete[] __a;
       delete[] __b;

       return __minright;
     }
 }

 #undef __S

 #endif /* _GLIBCXX_PARALLEL_MULTISEQ_SELECTION_H */
	// -- C++ --

	// Copyright (C) 2007-2014 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/multiseq_selection.h
	* @brief Functions to find elements of a certain global __rank in
	* multiple sorted sequences. Also serves for splitting such
	* sequence sets.
	*
	* The algorithm description can be found in
	*
	* P. J. Varman, S. D. Scheufler, B. R. Iyer, and G. R. Ricard.
	* Merging Multiple Lists on Hierarchical-Memory Multiprocessors.
	* Journal of Parallel and Distributed Computing, 12(2):171–177, 1991.
	*
	* This file is a GNU parallel extension to the Standard C++ Library.
	*/

	// Written by Johannes Singler.

	#ifndef _GLIBCXX_PARALLEL_MULTISEQ_SELECTION_H
	#define _GLIBCXX_PARALLEL_MULTISEQ_SELECTION_H 1

	#include <vector>
	#include <queue>

	#include <bits/stl_algo.h>

	namespace __gnu_parallel
	{
	/** @brief Compare __a pair of types lexicographically, ascending. */
	template<typename _T1, typename _T2, typename _Compare>
	class _Lexicographic
	: public std::binary_function<std::pair<_T1, _T2>,
	std::pair<_T1, _T2>, bool>
	{
	private:
	_Compare& _M_comp;

	public:
	_Lexicographic(_Compare& __comp) : _M_comp(__comp) { }

	bool
	operator()(const std::pair<_T1, _T2>& __p1,
	const std::pair<_T1, _T2>& __p2) const
	{
	if (_M_comp(__p1.first, __p2.first))
	return true;

	if (_M_comp(__p2.first, __p1.first))
	return false;

	// Firsts are equal.
	return __p1.second < __p2.second;
	}
	};

	/** @brief Compare __a pair of types lexicographically, descending. */
	template<typename _T1, typename _T2, typename _Compare>
	class _LexicographicReverse : public std::binary_function<_T1, _T2, bool>
	{
	private:
	_Compare& _M_comp;

	public:
	_LexicographicReverse(_Compare& __comp) : _M_comp(__comp) { }

	bool
	operator()(const std::pair<_T1, _T2>& __p1,
	const std::pair<_T1, _T2>& __p2) const
	{
	if (_M_comp(__p2.first, __p1.first))
	return true;

	if (_M_comp(__p1.first, __p2.first))
	return false;

	// Firsts are equal.
	return __p2.second < __p1.second;
	}
	};

	/**
	* @brief Splits several sorted sequences at a certain global __rank,
	* resulting in a splitting point for each sequence.
	* The sequences are passed via a sequence of random-access
	* iterator pairs, none of the sequences may be empty. If there
	* are several equal elements across the split, the ones on the
	* __left side will be chosen from sequences with smaller number.
	* @param __begin_seqs Begin of the sequence of iterator pairs.
	* @param __end_seqs End of the sequence of iterator pairs.
	* @param __rank The global rank to partition at.
	* @param __begin_offsets A random-access __sequence __begin where the
	* __result will be stored in. Each element of the sequence is an
	* iterator that points to the first element on the greater part of
	* the respective __sequence.
	* @param __comp The ordering functor, defaults to std::less<_Tp>.
	*/
	template<typename _RanSeqs, typename _RankType, typename _RankIterator,
	typename _Compare>
	void
	multiseq_partition(_RanSeqs __begin_seqs, _RanSeqs __end_seqs,
	_RankType __rank,
	_RankIterator __begin_offsets,
	_Compare __comp = std::less<
	typename std::iterator_traits<typename
	std::iterator_traits<_RanSeqs>::value_type::
	first_type>::value_type>()) // std::less<_Tp>
	{
	_GLIBCXX_CALL(__end_seqs - __begin_seqs)

	typedef typename std::iterator_traits<_RanSeqs>::value_type::first_type
	_It;
	typedef typename std::iterator_traits<_RanSeqs>::difference_type
	_SeqNumber;
	typedef typename std::iterator_traits<_It>::difference_type
	_DifferenceType;
	typedef typename std::iterator_traits<_It>::value_type _ValueType;

	_Lexicographic<_ValueType, _SeqNumber, _Compare> __lcomp(__comp);
	_LexicographicReverse<_ValueType, _SeqNumber, _Compare> __lrcomp(__comp);

	// Number of sequences, number of elements in total (possibly
	// including padding).
	_DifferenceType __m = std::distance(__begin_seqs, __end_seqs), __nn = 0,
	__nmax, __n, __r;

	for (_SeqNumber __i = 0; __i < __m; __i++)
	{
	__nn += std::distance(__begin_seqs[__i].first,
	__begin_seqs[__i].second);
	_GLIBCXX_PARALLEL_ASSERT(
	std::distance(__begin_seqs[__i].first,
	__begin_seqs[__i].second) > 0);
	}

	if (__rank == __nn)
	{
	for (_SeqNumber __i = 0; __i < __m; __i++)
	__begin_offsets[__i] = __begin_seqs[__i].second; // Very end.
	// Return __m - 1;
	return;
	}

	_GLIBCXX_PARALLEL_ASSERT(__m != 0);
	_GLIBCXX_PARALLEL_ASSERT(__nn != 0);
	_GLIBCXX_PARALLEL_ASSERT(__rank >= 0);
	_GLIBCXX_PARALLEL_ASSERT(__rank < __nn);

	_DifferenceType* __ns = new _DifferenceType[__m];
	_DifferenceType* __a = new _DifferenceType[__m];
	_DifferenceType* __b = new _DifferenceType[__m];
	_DifferenceType __l;

	__ns[0] = std::distance(__begin_seqs[0].first, __begin_seqs[0].second);
	__nmax = __ns[0];
	for (_SeqNumber __i = 0; __i < __m; __i++)
	{
	__ns[__i] = std::distance(__begin_seqs[__i].first,
	__begin_seqs[__i].second);
	__nmax = std::max(__nmax, __ns[__i]);
	}

	__r = __rd_log2(__nmax) + 1;

	// Pad all lists to this length, at least as long as any ns[__i],
	// equality iff __nmax = 2^__k - 1.
	__l = (1ULL << __r) - 1;

	for (_SeqNumber __i = 0; __i < __m; __i++)
	{
	__a[__i] = 0;
	__b[__i] = __l;
	}
	__n = __l / 2;

	// Invariants:
	// 0 <= __a[__i] <= __ns[__i], 0 <= __b[__i] <= __l

	#define __S(__i) (__begin_seqs[__i].first)

	// Initial partition.
	std::vector<std::pair<_ValueType, _SeqNumber> > __sample;

	for (_SeqNumber __i = 0; __i < __m; __i++)
	if (__n < __ns[__i]) //__sequence long enough
	__sample.push_back(std::make_pair(__S(__i)[__n], __i));
	__gnu_sequential::sort(__sample.begin(), __sample.end(), __lcomp);

	for (_SeqNumber __i = 0; __i < __m; __i++) //conceptual infinity
	if (__n >= __ns[__i]) //__sequence too short, conceptual infinity
	__sample.push_back(
	std::make_pair(__S(__i)[0] /__dummy element/, __i));

	_DifferenceType __localrank = __rank / __l;

	_SeqNumber __j;
	for (__j = 0;
	__j < __localrank && ((__n + 1) <= __ns[__sample[__j].second]);
	++__j)
	__a[__sample[__j].second] += __n + 1;
	for (; __j < __m; __j++)
	__b[__sample[__j].second] -= __n + 1;

	// Further refinement.
	while (__n > 0)
	{
	__n /= 2;

	_SeqNumber __lmax_seq = -1; // to avoid warning
	const _ValueType* __lmax = 0; // impossible to avoid the warning?
	for (_SeqNumber __i = 0; __i < __m; __i++)
	{
	if (__a[__i] > 0)
	{
	if (!__lmax)
	{
	__lmax = &(__S(__i)[__a[__i] - 1]);
	__lmax_seq = __i;
	}
	else
	{
	// Max, favor rear sequences.
	if (!__comp(__S(__i)[__a[__i] - 1], *__lmax))
	{
	__lmax = &(__S(__i)[__a[__i] - 1]);
	__lmax_seq = __i;
	}
	}
	}
	}

	_SeqNumber __i;
	for (__i = 0; __i < __m; __i++)
	{
	_DifferenceType __middle = (__b[__i] + __a[__i]) / 2;
	if (__lmax && __middle < __ns[__i] &&
	__lcomp(std::make_pair(__S(__i)[__middle], __i),
	std::make_pair(*__lmax, __lmax_seq)))
	__a[__i] = std::min(__a[__i] + __n + 1, __ns[__i]);
	else
	__b[__i] -= __n + 1;
	}

	_DifferenceType __leftsize = 0;
	for (_SeqNumber __i = 0; __i < __m; __i++)
	__leftsize += __a[__i] / (__n + 1);

	_DifferenceType __skew = __rank / (__n + 1) - __leftsize;

	if (__skew > 0)
	{
	// Move to the left, find smallest.
	std::priority_queue<std::pair<_ValueType, _SeqNumber>,
	std::vector<std::pair<_ValueType, _SeqNumber> >,
	_LexicographicReverse<_ValueType, _SeqNumber, _Compare> >
	__pq(__lrcomp);

	for (_SeqNumber __i = 0; __i < __m; __i++)
	if (__b[__i] < __ns[__i])
	__pq.push(std::make_pair(__S(__i)[__b[__i]], __i));

	for (; __skew != 0 && !__pq.empty(); --__skew)
	{
	_SeqNumber __source = __pq.top().second;
	__pq.pop();

	__a[__source]
	= std::min(__a[__source] + __n + 1, __ns[__source]);
	__b[__source] += __n + 1;

	if (__b[__source] < __ns[__source])
	__pq.push(
	std::make_pair(__S(__source)[__b[__source]], __source));
	}
	}
	else if (__skew < 0)
	{
	// Move to the right, find greatest.
	std::priority_queue<std::pair<_ValueType, _SeqNumber>,
	std::vector<std::pair<_ValueType, _SeqNumber> >,
	_Lexicographic<_ValueType, _SeqNumber, _Compare> >
	__pq(__lcomp);

	for (_SeqNumber __i = 0; __i < __m; __i++)
	if (__a[__i] > 0)
	__pq.push(std::make_pair(__S(__i)[__a[__i] - 1], __i));

	for (; __skew != 0; ++__skew)
	{
	_SeqNumber __source = __pq.top().second;
	__pq.pop();

	__a[__source] -= __n + 1;
	__b[__source] -= __n + 1;

	if (__a[__source] > 0)
	__pq.push(std::make_pair(
	__S(__source)[__a[__source] - 1], __source));
	}
	}
	}

	// Postconditions:
	// __a[__i] == __b[__i] in most cases, except when __a[__i] has been
	// clamped because of having reached the boundary

	// Now return the result, calculate the offset.

	// Compare the keys on both edges of the border.

	// Maximum of left edge, minimum of right edge.
	_ValueType* __maxleft = 0;
	_ValueType* __minright = 0;
	for (_SeqNumber __i = 0; __i < __m; __i++)
	{
	if (__a[__i] > 0)
	{
	if (!__maxleft)
	__maxleft = &(__S(__i)[__a[__i] - 1]);
	else
	{
	// Max, favor rear sequences.
	if (!__comp(__S(__i)[__a[__i] - 1], *__maxleft))
	__maxleft = &(__S(__i)[__a[__i] - 1]);
	}
	}
	if (__b[__i] < __ns[__i])
	{
	if (!__minright)
	__minright = &(__S(__i)[__b[__i]]);
	else
	{
	// Min, favor fore sequences.
	if (__comp(__S(__i)[__b[__i]], *__minright))
	__minright = &(__S(__i)[__b[__i]]);
	}
	}
	}

	_SeqNumber __seq = 0;
	for (_SeqNumber __i = 0; __i < __m; __i++)
	__begin_offsets[__i] = __S(__i) + __a[__i];

	delete[] __ns;
	delete[] __a;
	delete[] __b;
	}


	/**
	* @brief Selects the element at a certain global __rank from several
	* sorted sequences.
	*
	* The sequences are passed via a sequence of random-access
	* iterator pairs, none of the sequences may be empty.
	* @param __begin_seqs Begin of the sequence of iterator pairs.
	* @param __end_seqs End of the sequence of iterator pairs.
	* @param __rank The global rank to partition at.
	* @param __offset The rank of the selected element in the global
	* subsequence of elements equal to the selected element. If the
	* selected element is unique, this number is 0.
	* @param __comp The ordering functor, defaults to std::less.
	*/
	template<typename _Tp, typename _RanSeqs, typename _RankType,
	typename _Compare>
	_Tp
	multiseq_selection(_RanSeqs __begin_seqs, _RanSeqs __end_seqs,
	_RankType __rank,
	_RankType& __offset, _Compare __comp = std::less<_Tp>())
	{
	_GLIBCXX_CALL(__end_seqs - __begin_seqs)

	typedef typename std::iterator_traits<_RanSeqs>::value_type::first_type
	_It;
	typedef typename std::iterator_traits<_RanSeqs>::difference_type
	_SeqNumber;
	typedef typename std::iterator_traits<_It>::difference_type
	_DifferenceType;

	_Lexicographic<_Tp, _SeqNumber, _Compare> __lcomp(__comp);
	_LexicographicReverse<_Tp, _SeqNumber, _Compare> __lrcomp(__comp);

	// Number of sequences, number of elements in total (possibly
	// including padding).
	_DifferenceType __m = std::distance(__begin_seqs, __end_seqs);
	_DifferenceType __nn = 0;
	_DifferenceType __nmax, __n, __r;

	for (_SeqNumber __i = 0; __i < __m; __i++)
	__nn += std::distance(__begin_seqs[__i].first,
	__begin_seqs[__i].second);

	if (__m == 0 \|\| __nn == 0 \|\| __rank < 0 \|\| __rank >= __nn)
	{
	// result undefined if there is no data or __rank is outside bounds
	throw std::exception();
	}


	_DifferenceType* __ns = new _DifferenceType[__m];
	_DifferenceType* __a = new _DifferenceType[__m];
	_DifferenceType* __b = new _DifferenceType[__m];
	_DifferenceType __l;

	__ns[0] = std::distance(__begin_seqs[0].first, __begin_seqs[0].second);
	__nmax = __ns[0];
	for (_SeqNumber __i = 0; __i < __m; ++__i)
	{
	__ns[__i] = std::distance(__begin_seqs[__i].first,
	__begin_seqs[__i].second);
	__nmax = std::max(__nmax, __ns[__i]);
	}

	__r = __rd_log2(__nmax) + 1;

	// Pad all lists to this length, at least as long as any ns[__i],
	// equality iff __nmax = 2^__k - 1
	__l = __round_up_to_pow2(__r) - 1;

	for (_SeqNumber __i = 0; __i < __m; ++__i)
	{
	__a[__i] = 0;
	__b[__i] = __l;
	}
	__n = __l / 2;

	// Invariants:
	// 0 <= __a[__i] <= __ns[__i], 0 <= __b[__i] <= __l

	#define __S(__i) (__begin_seqs[__i].first)

	// Initial partition.
	std::vector<std::pair<_Tp, _SeqNumber> > __sample;

	for (_SeqNumber __i = 0; __i < __m; __i++)
	if (__n < __ns[__i])
	__sample.push_back(std::make_pair(__S(__i)[__n], __i));
	__gnu_sequential::sort(__sample.begin(), __sample.end(),
	__lcomp, sequential_tag());

	// Conceptual infinity.
	for (_SeqNumber __i = 0; __i < __m; __i++)
	if (__n >= __ns[__i])
	__sample.push_back(
	std::make_pair(__S(__i)[0] /__dummy element/, __i));

	_DifferenceType __localrank = __rank / __l;

	_SeqNumber __j;
	for (__j = 0;
	__j < __localrank && ((__n + 1) <= __ns[__sample[__j].second]);
	++__j)
	__a[__sample[__j].second] += __n + 1;
	for (; __j < __m; ++__j)
	__b[__sample[__j].second] -= __n + 1;

	// Further refinement.
	while (__n > 0)
	{
	__n /= 2;

	const _Tp* __lmax = 0;
	for (_SeqNumber __i = 0; __i < __m; ++__i)
	{
	if (__a[__i] > 0)
	{
	if (!__lmax)
	__lmax = &(__S(__i)[__a[__i] - 1]);
	else
	{
	if (__comp(*__lmax, __S(__i)[__a[__i] - 1])) //max
	__lmax = &(__S(__i)[__a[__i] - 1]);
	}
	}
	}

	_SeqNumber __i;
	for (__i = 0; __i < __m; __i++)
	{
	_DifferenceType __middle = (__b[__i] + __a[__i]) / 2;
	if (__lmax && __middle < __ns[__i]
	&& __comp(__S(__i)[__middle], *__lmax))
	__a[__i] = std::min(__a[__i] + __n + 1, __ns[__i]);
	else
	__b[__i] -= __n + 1;
	}

	_DifferenceType __leftsize = 0;
	for (_SeqNumber __i = 0; __i < __m; ++__i)
	__leftsize += __a[__i] / (__n + 1);

	_DifferenceType __skew = __rank / (__n + 1) - __leftsize;

	if (__skew > 0)
	{
	// Move to the left, find smallest.
	std::priority_queue<std::pair<_Tp, _SeqNumber>,
	std::vector<std::pair<_Tp, _SeqNumber> >,
	_LexicographicReverse<_Tp, _SeqNumber, _Compare> >
	__pq(__lrcomp);

	for (_SeqNumber __i = 0; __i < __m; ++__i)
	if (__b[__i] < __ns[__i])
	__pq.push(std::make_pair(__S(__i)[__b[__i]], __i));

	for (; __skew != 0 && !__pq.empty(); --__skew)
	{
	_SeqNumber __source = __pq.top().second;
	__pq.pop();

	__a[__source]
	= std::min(__a[__source] + __n + 1, __ns[__source]);
	__b[__source] += __n + 1;

	if (__b[__source] < __ns[__source])
	__pq.push(
	std::make_pair(__S(__source)[__b[__source]], __source));
	}
	}
	else if (__skew < 0)
	{
	// Move to the right, find greatest.
	std::priority_queue<std::pair<_Tp, _SeqNumber>,
	std::vector<std::pair<_Tp, _SeqNumber> >,
	_Lexicographic<_Tp, _SeqNumber, _Compare> > __pq(__lcomp);

	for (_SeqNumber __i = 0; __i < __m; ++__i)
	if (__a[__i] > 0)
	__pq.push(std::make_pair(__S(__i)[__a[__i] - 1], __i));

	for (; __skew != 0; ++__skew)
	{
	_SeqNumber __source = __pq.top().second;
	__pq.pop();

	__a[__source] -= __n + 1;
	__b[__source] -= __n + 1;

	if (__a[__source] > 0)
	__pq.push(std::make_pair(
	__S(__source)[__a[__source] - 1], __source));
	}
	}
	}

	// Postconditions:
	// __a[__i] == __b[__i] in most cases, except when __a[__i] has been
	// clamped because of having reached the boundary

	// Now return the result, calculate the offset.

	// Compare the keys on both edges of the border.

	// Maximum of left edge, minimum of right edge.
	bool __maxleftset = false, __minrightset = false;

	// Impossible to avoid the warning?
	_Tp __maxleft, __minright;
	for (_SeqNumber __i = 0; __i < __m; ++__i)
	{
	if (__a[__i] > 0)
	{
	if (!__maxleftset)
	{
	__maxleft = __S(__i)[__a[__i] - 1];
	__maxleftset = true;
	}
	else
	{
	// Max.
	if (__comp(__maxleft, __S(__i)[__a[__i] - 1]))
	__maxleft = __S(__i)[__a[__i] - 1];
	}
	}
	if (__b[__i] < __ns[__i])
	{
	if (!__minrightset)
	{
	__minright = __S(__i)[__b[__i]];
	__minrightset = true;
	}
	else
	{
	// Min.
	if (__comp(__S(__i)[__b[__i]], __minright))
	__minright = __S(__i)[__b[__i]];
	}
	}
	}

	// Minright is the __splitter, in any case.

	if (!__maxleftset \|\| __comp(__minright, __maxleft))
	{
	// Good luck, everything is split unambiguously.
	__offset = 0;
	}
	else
	{
	// We have to calculate an offset.
	__offset = 0;

	for (_SeqNumber __i = 0; __i < __m; ++__i)
	{
	_DifferenceType lb
	= std::lower_bound(__S(__i), __S(__i) + __ns[__i],
	__minright,
	__comp) - __S(__i);
	__offset += __a[__i] - lb;
	}
	}

	delete[] __ns;
	delete[] __a;
	delete[] __b;

	return __minright;
	}
	}

	#undef __S

	#endif /* _GLIBCXX_PARALLEL_MULTISEQ_SELECTION_H */