usr/arc-buildroot-linux-uclibc/include/c++/6.2.1/parallel/base.h - toolchains/quantenna - Git at Google

 // -*- C++ -*-

 // Copyright (C) 2007-2016 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/base.h
  *  @brief Sequential helper functions.
  *  This file is a GNU parallel extension to the Standard C++ Library.
  */

 // Written by Johannes Singler.

 #ifndef _GLIBCXX_PARALLEL_BASE_H
 #define _GLIBCXX_PARALLEL_BASE_H 1

 #include <bits/c++config.h>
 #include <bits/stl_function.h>
 #include <omp.h>
 #include <parallel/features.h>
 #include <parallel/basic_iterator.h>
 #include <parallel/parallel.h>

 // Parallel mode namespaces.

 /**
  * @namespace std::__parallel
  * @brief GNU parallel code, replaces standard behavior with parallel behavior.
  */
 namespace std _GLIBCXX_VISIBILITY(default)
 {
   namespace __parallel { }
 }

 /**
  * @namespace __gnu_parallel
  * @brief GNU parallel code for public use.
  */
 namespace __gnu_parallel
 {
   // Import all the parallel versions of components in namespace std.
   using namespace std::__parallel;
 }

 /**
  * @namespace __gnu_sequential
  * @brief GNU sequential classes for public use.
  */
 namespace __gnu_sequential
 {
   // Import whatever is the serial version.
 #ifdef _GLIBCXX_PARALLEL
   using namespace std::_GLIBCXX_STD_A;
 #else
   using namespace std;
 #endif
 }


 namespace __gnu_parallel
 {
   // NB: Including this file cannot produce (unresolved) symbols from
   // the OpenMP runtime unless the parallel mode is actually invoked
   // and active, which imples that the OpenMP runtime is actually
   // going to be linked in.
   inline _ThreadIndex
   __get_max_threads()
   {
     _ThreadIndex __i = omp_get_max_threads();
     return __i > 1 ? __i : 1;
   }


   inline bool
   __is_parallel(const _Parallelism __p) { return __p != sequential; }


   /** @brief Calculates the rounded-down logarithm of @c __n for base 2.
    *  @param __n Argument.
    *  @return Returns 0 for any argument <1.
    */
   template<typename _Size>
     inline _Size
     __rd_log2(_Size __n)
     {
       _Size __k;
       for (__k = 0; __n > 1; __n >>= 1)
         ++__k;
       return __k;
     }

   /** @brief Encode two integers into one gnu_parallel::_CASable.
    *  @param __a First integer, to be encoded in the most-significant @c
    *  _CASable_bits/2 bits.
    *  @param __b Second integer, to be encoded in the least-significant
    *  @c _CASable_bits/2 bits.
    *  @return value encoding @c __a and @c __b.
    *  @see __decode2
    */
   inline _CASable
   __encode2(int __a, int __b)     //must all be non-negative, actually
   {
     return (((_CASable)__a) << (_CASable_bits / 2)) | (((_CASable)__b) << 0);
   }

   /** @brief Decode two integers from one gnu_parallel::_CASable.
    *  @param __x __gnu_parallel::_CASable to decode integers from.
    *  @param __a First integer, to be decoded from the most-significant
    *  @c _CASable_bits/2 bits of @c __x.
    *  @param __b Second integer, to be encoded in the least-significant
    *  @c _CASable_bits/2 bits of @c __x.
    *  @see __encode2
    */
   inline void
   __decode2(_CASable __x, int& __a, int& __b)
   {
     __a = (int)((__x >> (_CASable_bits / 2)) & _CASable_mask);
     __b = (int)((__x >>               0 ) & _CASable_mask);
   }

   //needed for parallel "numeric", even if "algorithm" not included

   /** @brief Equivalent to std::min. */
   template<typename _Tp>
     inline const _Tp&
     min(const _Tp& __a, const _Tp& __b)
     { return (__a < __b) ? __a : __b; }

   /** @brief Equivalent to std::max. */
   template<typename _Tp>
     inline const _Tp&
     max(const _Tp& __a, const _Tp& __b)
     { return (__a > __b) ? __a : __b; }

   /** @brief Constructs predicate for equality from strict weak
    *  ordering predicate
    */
   template<typename _T1, typename _T2, typename _Compare>
     class _EqualFromLess : public std::binary_function<_T1, _T2, bool>
     {
     private:
       _Compare& _M_comp;

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

       bool operator()(const _T1& __a, const _T2& __b)
       { return !_M_comp(__a, __b) && !_M_comp(__b, __a); }
     };


   /** @brief Similar to std::unary_negate,
    *  but giving the argument types explicitly. */
   template<typename _Predicate, typename argument_type>
     class __unary_negate
     : public std::unary_function<argument_type, bool>
     {
     protected:
       _Predicate _M_pred;

     public:
       explicit
       __unary_negate(const _Predicate& __x) : _M_pred(__x) { }

       bool
       operator()(const argument_type& __x)
       { return !_M_pred(__x); }
     };

   /** @brief Similar to std::binder1st,
    *  but giving the argument types explicitly. */
   template<typename _Operation, typename _FirstArgumentType,
 	   typename _SecondArgumentType, typename _ResultType>
     class __binder1st
     : public std::unary_function<_SecondArgumentType, _ResultType>
     {
     protected:
       _Operation _M_op;
       _FirstArgumentType _M_value;

     public:
       __binder1st(const _Operation& __x, const _FirstArgumentType& __y)
       : _M_op(__x), _M_value(__y) { }

       _ResultType
       operator()(const _SecondArgumentType& __x)
       { return _M_op(_M_value, __x); }

       // _GLIBCXX_RESOLVE_LIB_DEFECTS
       // 109.  Missing binders for non-const sequence elements
       _ResultType
       operator()(_SecondArgumentType& __x) const
       { return _M_op(_M_value, __x); }
     };

   /**
    *  @brief Similar to std::binder2nd, but giving the argument types
    *  explicitly.
    */
   template<typename _Operation, typename _FirstArgumentType,
 	   typename _SecondArgumentType, typename _ResultType>
     class __binder2nd
     : public std::unary_function<_FirstArgumentType, _ResultType>
     {
     protected:
       _Operation _M_op;
       _SecondArgumentType _M_value;

     public:
       __binder2nd(const _Operation& __x, const _SecondArgumentType& __y)
       : _M_op(__x), _M_value(__y) { }

       _ResultType
       operator()(const _FirstArgumentType& __x) const
       { return _M_op(__x, _M_value); }

       // _GLIBCXX_RESOLVE_LIB_DEFECTS
       // 109.  Missing binders for non-const sequence elements
       _ResultType
       operator()(_FirstArgumentType& __x)
       { return _M_op(__x, _M_value); }
     };

   /** @brief Similar to std::equal_to, but allows two different types. */
   template<typename _T1, typename _T2>
     struct _EqualTo : std::binary_function<_T1, _T2, bool>
     {
       bool operator()(const _T1& __t1, const _T2& __t2) const
       { return __t1 == __t2; }
     };

   /** @brief Similar to std::less, but allows two different types. */
   template<typename _T1, typename _T2>
     struct _Less : std::binary_function<_T1, _T2, bool>
     {
       bool
       operator()(const _T1& __t1, const _T2& __t2) const
       { return __t1 < __t2; }

       bool
       operator()(const _T2& __t2, const _T1& __t1) const
       { return __t2 < __t1; }
     };

   // Partial specialization for one type. Same as std::less.
   template<typename _Tp>
     struct _Less<_Tp, _Tp>
     : public std::less<_Tp> { };

   /** @brief Similar to std::plus, but allows two different types. */
   template<typename _Tp1, typename _Tp2, typename _Result
 	   = __typeof__(*static_cast<_Tp1*>(0)
 			+ *static_cast<_Tp2*>(0))>
     struct _Plus : public std::binary_function<_Tp1, _Tp2, _Result>
     {
       _Result
       operator()(const _Tp1& __x, const _Tp2& __y) const
       { return __x + __y; }
     };

   // Partial specialization for one type. Same as std::plus.
   template<typename _Tp>
     struct _Plus<_Tp, _Tp, _Tp>
     : public std::plus<_Tp> { };

   /** @brief Similar to std::multiplies, but allows two different types. */
   template<typename _Tp1, typename _Tp2, typename _Result
 	   = __typeof__(*static_cast<_Tp1*>(0)
 			* *static_cast<_Tp2*>(0))>
     struct _Multiplies : public std::binary_function<_Tp1, _Tp2, _Result>
     {
       _Result
       operator()(const _Tp1& __x, const _Tp2& __y) const
       { return __x * __y; }
     };

   // Partial specialization for one type. Same as std::multiplies.
   template<typename _Tp>
     struct _Multiplies<_Tp, _Tp, _Tp>
     : public std::multiplies<_Tp> { };

   /** @brief _Iterator associated with __gnu_parallel::_PseudoSequence.
    *  If features the usual random-access iterator functionality.
    *  @param _Tp Sequence _M_value type.
    *  @param _DifferenceTp Sequence difference type.
    */
   template<typename _Tp, typename _DifferenceTp>
     class _PseudoSequenceIterator
     {
     public:
       typedef _DifferenceTp _DifferenceType;

       _PseudoSequenceIterator(const _Tp& __val, _DifferenceType __pos)
       : _M_val(__val), _M_pos(__pos) { }

       // Pre-increment operator.
       _PseudoSequenceIterator&
       operator++()
       {
 	++_M_pos;
 	return *this;
       }

       // Post-increment operator.
       _PseudoSequenceIterator
       operator++(int)
       { return _PseudoSequenceIterator(_M_pos++); }

       const _Tp&
       operator*() const
       { return _M_val; }

       const _Tp&
       operator[](_DifferenceType) const
       { return _M_val; }

       bool
       operator==(const _PseudoSequenceIterator& __i2)
       { return _M_pos == __i2._M_pos; }

       bool
       operator!=(const _PseudoSequenceIterator& __i2)
       { return _M_pos != __i2._M_pos; }

       _DifferenceType
       operator-(const _PseudoSequenceIterator& __i2)
       { return _M_pos - __i2._M_pos; }

     private:
       const _Tp& _M_val;
       _DifferenceType _M_pos;
     };

   /** @brief Sequence that conceptually consists of multiple copies of
       the same element.
       *  The copies are not stored explicitly, of course.
       *  @param _Tp Sequence _M_value type.
       *  @param _DifferenceTp Sequence difference type.
       */
   template<typename _Tp, typename _DifferenceTp>
     class _PseudoSequence
     {
     public:
       typedef _DifferenceTp _DifferenceType;

       // Better cast down to uint64_t, than up to _DifferenceTp.
       typedef _PseudoSequenceIterator<_Tp, uint64_t> iterator;

       /** @brief Constructor.
        *  @param __val Element of the sequence.
        *  @param __count Number of (virtual) copies.
        */
       _PseudoSequence(const _Tp& __val, _DifferenceType __count)
       : _M_val(__val), _M_count(__count)  { }

       /** @brief Begin iterator. */
       iterator
       begin() const
       { return iterator(_M_val, 0); }

       /** @brief End iterator. */
       iterator
       end() const
       { return iterator(_M_val, _M_count); }

     private:
       const _Tp& _M_val;
       _DifferenceType _M_count;
     };

   /** @brief Compute the median of three referenced elements,
       according to @c __comp.
       *  @param __a First iterator.
       *  @param __b Second iterator.
       *  @param __c Third iterator.
       *  @param __comp Comparator.
       */
   template<typename _RAIter, typename _Compare>
     _RAIter
     __median_of_three_iterators(_RAIter __a, _RAIter __b,
 				_RAIter __c, _Compare __comp)
     {
       if (__comp(*__a, *__b))
 	if (__comp(*__b, *__c))
 	  return __b;
 	else
 	  if (__comp(*__a, *__c))
 	    return __c;
 	  else
 	    return __a;
       else
 	{
 	  // Just swap __a and __b.
 	  if (__comp(*__a, *__c))
 	    return __a;
 	  else
 	    if (__comp(*__b, *__c))
 	      return __c;
 	    else
 	      return __b;
 	}
     }

 #define _GLIBCXX_PARALLEL_ASSERT(_Condition) __glibcxx_assert(_Condition)

 } //namespace __gnu_parallel

 #endif /* _GLIBCXX_PARALLEL_BASE_H */
	// -- C++ --

	// Copyright (C) 2007-2016 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/base.h
	* @brief Sequential helper functions.
	* This file is a GNU parallel extension to the Standard C++ Library.
	*/

	// Written by Johannes Singler.

	#ifndef _GLIBCXX_PARALLEL_BASE_H
	#define _GLIBCXX_PARALLEL_BASE_H 1

	#include <bits/c++config.h>
	#include <bits/stl_function.h>
	#include <omp.h>
	#include <parallel/features.h>
	#include <parallel/basic_iterator.h>
	#include <parallel/parallel.h>

	// Parallel mode namespaces.

	/**
	* @namespace std::__parallel
	* @brief GNU parallel code, replaces standard behavior with parallel behavior.
	*/
	namespace std _GLIBCXX_VISIBILITY(default)
	{
	namespace __parallel { }
	}

	/**
	* @namespace __gnu_parallel
	* @brief GNU parallel code for public use.
	*/
	namespace __gnu_parallel
	{
	// Import all the parallel versions of components in namespace std.
	using namespace std::__parallel;
	}

	/**
	* @namespace __gnu_sequential
	* @brief GNU sequential classes for public use.
	*/
	namespace __gnu_sequential
	{
	// Import whatever is the serial version.
	#ifdef _GLIBCXX_PARALLEL
	using namespace std::_GLIBCXX_STD_A;
	#else
	using namespace std;
	#endif
	}


	namespace __gnu_parallel
	{
	// NB: Including this file cannot produce (unresolved) symbols from
	// the OpenMP runtime unless the parallel mode is actually invoked
	// and active, which imples that the OpenMP runtime is actually
	// going to be linked in.
	inline _ThreadIndex
	__get_max_threads()
	{
	_ThreadIndex __i = omp_get_max_threads();
	return __i > 1 ? __i : 1;
	}


	inline bool
	__is_parallel(const _Parallelism __p) { return __p != sequential; }


	/** @brief Calculates the rounded-down logarithm of @c __n for base 2.
	* @param __n Argument.
	* @return Returns 0 for any argument <1.
	*/
	template<typename _Size>
	inline _Size
	__rd_log2(_Size __n)
	{
	_Size __k;
	for (__k = 0; __n > 1; __n >>= 1)
	++__k;
	return __k;
	}

	/** @brief Encode two integers into one gnu_parallel::_CASable.
	* @param __a First integer, to be encoded in the most-significant @c
	* _CASable_bits/2 bits.
	* @param __b Second integer, to be encoded in the least-significant
	* @c _CASable_bits/2 bits.
	* @return value encoding @c __a and @c __b.
	* @see __decode2
	*/
	inline _CASable
	__encode2(int __a, int __b) //must all be non-negative, actually
	{
	return (((_CASable)__a) << (_CASable_bits / 2)) \| (((_CASable)__b) << 0);
	}

	/** @brief Decode two integers from one gnu_parallel::_CASable.
	* @param __x __gnu_parallel::_CASable to decode integers from.
	* @param __a First integer, to be decoded from the most-significant
	* @c _CASable_bits/2 bits of @c __x.
	* @param __b Second integer, to be encoded in the least-significant
	* @c _CASable_bits/2 bits of @c __x.
	* @see __encode2
	*/
	inline void
	__decode2(_CASable __x, int& __a, int& __b)
	{
	__a = (int)((__x >> (_CASable_bits / 2)) & _CASable_mask);
	__b = (int)((__x >> 0 ) & _CASable_mask);
	}

	//needed for parallel "numeric", even if "algorithm" not included

	/** @brief Equivalent to std::min. */
	template<typename _Tp>
	inline const _Tp&
	min(const _Tp& __a, const _Tp& __b)
	{ return (__a < __b) ? __a : __b; }

	/** @brief Equivalent to std::max. */
	template<typename _Tp>
	inline const _Tp&
	max(const _Tp& __a, const _Tp& __b)
	{ return (__a > __b) ? __a : __b; }

	/** @brief Constructs predicate for equality from strict weak
	* ordering predicate
	*/
	template<typename _T1, typename _T2, typename _Compare>
	class _EqualFromLess : public std::binary_function<_T1, _T2, bool>
	{
	private:
	_Compare& _M_comp;

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

	bool operator()(const _T1& __a, const _T2& __b)
	{ return !_M_comp(__a, __b) && !_M_comp(__b, __a); }
	};


	/** @brief Similar to std::unary_negate,
	* but giving the argument types explicitly. */
	template<typename _Predicate, typename argument_type>
	class __unary_negate
	: public std::unary_function<argument_type, bool>
	{
	protected:
	_Predicate _M_pred;

	public:
	explicit
	__unary_negate(const _Predicate& __x) : _M_pred(__x) { }

	bool
	operator()(const argument_type& __x)
	{ return !_M_pred(__x); }
	};

	/** @brief Similar to std::binder1st,
	* but giving the argument types explicitly. */
	template<typename _Operation, typename _FirstArgumentType,
	typename _SecondArgumentType, typename _ResultType>
	class __binder1st
	: public std::unary_function<_SecondArgumentType, _ResultType>
	{
	protected:
	_Operation _M_op;
	_FirstArgumentType _M_value;

	public:
	__binder1st(const _Operation& __x, const _FirstArgumentType& __y)
	: _M_op(__x), _M_value(__y) { }

	_ResultType
	operator()(const _SecondArgumentType& __x)
	{ return _M_op(_M_value, __x); }

	// _GLIBCXX_RESOLVE_LIB_DEFECTS
	// 109. Missing binders for non-const sequence elements
	_ResultType
	operator()(_SecondArgumentType& __x) const
	{ return _M_op(_M_value, __x); }
	};

	/**
	* @brief Similar to std::binder2nd, but giving the argument types
	* explicitly.
	*/
	template<typename _Operation, typename _FirstArgumentType,
	typename _SecondArgumentType, typename _ResultType>
	class __binder2nd
	: public std::unary_function<_FirstArgumentType, _ResultType>
	{
	protected:
	_Operation _M_op;
	_SecondArgumentType _M_value;

	public:
	__binder2nd(const _Operation& __x, const _SecondArgumentType& __y)
	: _M_op(__x), _M_value(__y) { }

	_ResultType
	operator()(const _FirstArgumentType& __x) const
	{ return _M_op(__x, _M_value); }

	// _GLIBCXX_RESOLVE_LIB_DEFECTS
	// 109. Missing binders for non-const sequence elements
	_ResultType
	operator()(_FirstArgumentType& __x)
	{ return _M_op(__x, _M_value); }
	};

	/** @brief Similar to std::equal_to, but allows two different types. */
	template<typename _T1, typename _T2>
	struct _EqualTo : std::binary_function<_T1, _T2, bool>
	{
	bool operator()(const _T1& __t1, const _T2& __t2) const
	{ return __t1 == __t2; }
	};

	/** @brief Similar to std::less, but allows two different types. */
	template<typename _T1, typename _T2>
	struct _Less : std::binary_function<_T1, _T2, bool>
	{
	bool
	operator()(const _T1& __t1, const _T2& __t2) const
	{ return __t1 < __t2; }

	bool
	operator()(const _T2& __t2, const _T1& __t1) const
	{ return __t2 < __t1; }
	};

	// Partial specialization for one type. Same as std::less.
	template<typename _Tp>
	struct _Less<_Tp, _Tp>
	: public std::less<_Tp> { };

	/** @brief Similar to std::plus, but allows two different types. */
	template<typename _Tp1, typename _Tp2, typename _Result
	= __typeof__(static_cast<_Tp1>(0)
	+ static_cast<_Tp2>(0))>
	struct _Plus : public std::binary_function<_Tp1, _Tp2, _Result>
	{
	_Result
	operator()(const _Tp1& __x, const _Tp2& __y) const
	{ return __x + __y; }
	};

	// Partial specialization for one type. Same as std::plus.
	template<typename _Tp>
	struct _Plus<_Tp, _Tp, _Tp>
	: public std::plus<_Tp> { };

	/** @brief Similar to std::multiplies, but allows two different types. */
	template<typename _Tp1, typename _Tp2, typename _Result
	= __typeof__(static_cast<_Tp1>(0)
	* static_cast<_Tp2>(0))>
	struct _Multiplies : public std::binary_function<_Tp1, _Tp2, _Result>
	{
	_Result
	operator()(const _Tp1& __x, const _Tp2& __y) const
	{ return __x * __y; }
	};

	// Partial specialization for one type. Same as std::multiplies.
	template<typename _Tp>
	struct _Multiplies<_Tp, _Tp, _Tp>
	: public std::multiplies<_Tp> { };

	/** @brief _Iterator associated with __gnu_parallel::_PseudoSequence.
	* If features the usual random-access iterator functionality.
	* @param _Tp Sequence _M_value type.
	* @param _DifferenceTp Sequence difference type.
	*/
	template<typename _Tp, typename _DifferenceTp>
	class _PseudoSequenceIterator
	{
	public:
	typedef _DifferenceTp _DifferenceType;

	_PseudoSequenceIterator(const _Tp& __val, _DifferenceType __pos)
	: _M_val(__val), _M_pos(__pos) { }

	// Pre-increment operator.
	_PseudoSequenceIterator&
	operator++()
	{
	++_M_pos;
	return *this;
	}

	// Post-increment operator.
	_PseudoSequenceIterator
	operator++(int)
	{ return _PseudoSequenceIterator(_M_pos++); }

	const _Tp&
	operator*() const
	{ return _M_val; }

	const _Tp&
	operator[](_DifferenceType) const
	{ return _M_val; }

	bool
	operator==(const _PseudoSequenceIterator& __i2)
	{ return _M_pos == __i2._M_pos; }

	bool
	operator!=(const _PseudoSequenceIterator& __i2)
	{ return _M_pos != __i2._M_pos; }

	_DifferenceType
	operator-(const _PseudoSequenceIterator& __i2)
	{ return _M_pos - __i2._M_pos; }

	private:
	const _Tp& _M_val;
	_DifferenceType _M_pos;
	};

	/** @brief Sequence that conceptually consists of multiple copies of
	the same element.
	* The copies are not stored explicitly, of course.
	* @param _Tp Sequence _M_value type.
	* @param _DifferenceTp Sequence difference type.
	*/
	template<typename _Tp, typename _DifferenceTp>
	class _PseudoSequence
	{
	public:
	typedef _DifferenceTp _DifferenceType;

	// Better cast down to uint64_t, than up to _DifferenceTp.
	typedef _PseudoSequenceIterator<_Tp, uint64_t> iterator;

	/** @brief Constructor.
	* @param __val Element of the sequence.
	* @param __count Number of (virtual) copies.
	*/
	_PseudoSequence(const _Tp& __val, _DifferenceType __count)
	: _M_val(__val), _M_count(__count) { }

	/** @brief Begin iterator. */
	iterator
	begin() const
	{ return iterator(_M_val, 0); }

	/** @brief End iterator. */
	iterator
	end() const
	{ return iterator(_M_val, _M_count); }

	private:
	const _Tp& _M_val;
	_DifferenceType _M_count;
	};

	/** @brief Compute the median of three referenced elements,
	according to @c __comp.
	* @param __a First iterator.
	* @param __b Second iterator.
	* @param __c Third iterator.
	* @param __comp Comparator.
	*/
	template<typename _RAIter, typename _Compare>
	_RAIter
	__median_of_three_iterators(_RAIter __a, _RAIter __b,
	_RAIter __c, _Compare __comp)
	{
	if (__comp(__a, __b))
	if (__comp(__b, __c))
	return __b;
	else
	if (__comp(__a, __c))
	return __c;
	else
	return __a;
	else
	{
	// Just swap __a and __b.
	if (__comp(__a, __c))
	return __a;
	else
	if (__comp(__b, __c))
	return __c;
	else
	return __b;
	}
	}

	#define _GLIBCXX_PARALLEL_ASSERT(_Condition) __glibcxx_assert(_Condition)

	} //namespace __gnu_parallel

	#endif /* _GLIBCXX_PARALLEL_BASE_H */