boost_1_45_0/boost/mpi/operations.hpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Copyright (C) 2004 The Trustees of Indiana University.
 // Copyright (C) 2005-2006 Douglas Gregor <doug.gregor -at- gmail.com>

 // Use, modification and distribution is subject to the Boost Software
 // License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
 // http://www.boost.org/LICENSE_1_0.txt)

 //  Authors: Douglas Gregor
 //           Andrew Lumsdaine

 /** @file operations.hpp
  *
  *  This header provides a mapping from function objects to @c MPI_Op
  *  constants used in MPI collective operations. It also provides
  *  several new function object types not present in the standard @c
  *  <functional> header that have direct mappings to @c MPI_Op.
  */
 #ifndef BOOST_MPI_IS_MPI_OP_HPP
 #define BOOST_MPI_IS_MPI_OP_HPP

 #include <boost/mpi/config.hpp>
 #include <boost/mpl/bool.hpp>
 #include <boost/mpl/if.hpp>
 #include <boost/mpl/and.hpp>
 #include <boost/mpi/datatype.hpp>
 #include <boost/utility/enable_if.hpp>
 #include <functional>

 namespace boost { namespace mpi {

 template<typename Op, typename T> struct is_mpi_op;

 /**
  * @brief Determine if a function object type is commutative.
  *
  * This trait determines if an operation @c Op is commutative when
  * applied to values of type @c T. Parallel operations such as @c
  * reduce and @c prefix_sum can be implemented more efficiently with
  * commutative operations. To mark an operation as commutative, users
  * should specialize @c is_commutative and derive from the class @c
  * mpl::true_.
  */
 template<typename Op, typename T>
 struct is_commutative : public mpl::false_ { };

 /**************************************************************************
  * Function objects for MPI operations not in <functional> header         *
  **************************************************************************/

 /**
  *  @brief Compute the maximum of two values.
  *
  *  This binary function object computes the maximum of the two values
  *  it is given. When used with MPI and a type @c T that has an
  *  associated, built-in MPI data type, translates to @c MPI_MAX.
  */
 template<typename T>
 struct maximum : public std::binary_function<T, T, T>
 {
   /** @returns the maximum of x and y. */
   const T& operator()(const T& x, const T& y) const
   {
     return x < y? y : x;
   }
 };

 /**
  *  @brief Compute the minimum of two values.
  *
  *  This binary function object computes the minimum of the two values
  *  it is given. When used with MPI and a type @c T that has an
  *  associated, built-in MPI data type, translates to @c MPI_MIN.
  */
 template<typename T>
 struct minimum : public std::binary_function<T, T, T>
 {
   /** @returns the minimum of x and y. */
   const T& operator()(const T& x, const T& y) const
   {
     return x < y? x : y;
   }
 };


 /**
  *  @brief Compute the bitwise AND of two integral values.
  *
  *  This binary function object computes the bitwise AND of the two
  *  values it is given. When used with MPI and a type @c T that has an
  *  associated, built-in MPI data type, translates to @c MPI_BAND.
  */
 template<typename T>
 struct bitwise_and : public std::binary_function<T, T, T>
 {
   /** @returns @c x & y. */
   T operator()(const T& x, const T& y) const
   {
     return x & y;
   }
 };

 /**
  *  @brief Compute the bitwise OR of two integral values.
  *
  *  This binary function object computes the bitwise OR of the two
  *  values it is given. When used with MPI and a type @c T that has an
  *  associated, built-in MPI data type, translates to @c MPI_BOR.
  */
 template<typename T>
 struct bitwise_or : public std::binary_function<T, T, T>
 {
   /** @returns the @c x | y. */
   T operator()(const T& x, const T& y) const
   {
     return x | y;
   }
 };

 /**
  *  @brief Compute the logical exclusive OR of two integral values.
  *
  *  This binary function object computes the logical exclusive of the
  *  two values it is given. When used with MPI and a type @c T that has
  *  an associated, built-in MPI data type, translates to @c MPI_LXOR.
  */
 template<typename T>
 struct logical_xor : public std::binary_function<T, T, T>
 {
   /** @returns the logical exclusive OR of x and y. */
   T operator()(const T& x, const T& y) const
   {
     return (x || y) && !(x && y);
   }
 };

 /**
  *  @brief Compute the bitwise exclusive OR of two integral values.
  *
  *  This binary function object computes the bitwise exclusive OR of
  *  the two values it is given. When used with MPI and a type @c T that
  *  has an associated, built-in MPI data type, translates to @c
  *  MPI_BXOR.
  */
 template<typename T>
 struct bitwise_xor : public std::binary_function<T, T, T>
 {
   /** @returns @c x ^ y. */
   T operator()(const T& x, const T& y) const
   {
     return x ^ y;
   }
 };

 /**************************************************************************
  * MPI_Op queries                                                         *
  **************************************************************************/

 /**
  *  @brief Determine if a function object has an associated @c MPI_Op.
  *
  *  This trait determines if a function object type @c Op, when used
  *  with argument type @c T, has an associated @c MPI_Op. If so, @c
  *  is_mpi_op<Op,T> will derive from @c mpl::false_ and will
  *  contain a static member function @c op that takes no arguments but
  *  returns the associated @c MPI_Op value. For instance, @c
  *  is_mpi_op<std::plus<int>,int>::op() returns @c MPI_SUM.
  *
  *  Users may specialize @c is_mpi_op for any other class templates
  *  that map onto operations that have @c MPI_Op equivalences, such as
  *  bitwise OR, logical and, or maximum. However, users are encouraged
  *  to use the standard function objects in the @c functional and @c
  *  boost/mpi/operations.hpp headers whenever possible. For
  *  function objects that are class templates with a single template
  *  parameter, it may be easier to specialize @c is_builtin_mpi_op.
  */
 template<typename Op, typename T>
 struct is_mpi_op : public mpl::false_ { };

 /// INTERNAL ONLY
 template<typename T>
 struct is_mpi_op<maximum<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_floating_point_datatype<T> >
 {
   static MPI_Op op() { return MPI_MAX; }
 };

 /// INTERNAL ONLY
 template<typename T>
 struct is_mpi_op<minimum<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_floating_point_datatype<T> >
 {
   static MPI_Op op() { return MPI_MIN; }
 };

 /// INTERNAL ONLY
 template<typename T>
  struct is_mpi_op<std::plus<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_floating_point_datatype<T>,
                            is_mpi_complex_datatype<T> >
 {
   static MPI_Op op() { return MPI_SUM; }
 };

 /// INTERNAL ONLY
 template<typename T>
  struct is_mpi_op<std::multiplies<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_floating_point_datatype<T>,
                            is_mpi_complex_datatype<T> >
 {
   static MPI_Op op() { return MPI_PROD; }
 };

 /// INTERNAL ONLY
 template<typename T>
  struct is_mpi_op<std::logical_and<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_logical_datatype<T> >
 {
   static MPI_Op op() { return MPI_LAND; }
 };

 /// INTERNAL ONLY
 template<typename T>
  struct is_mpi_op<std::logical_or<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_logical_datatype<T> >
 {
   static MPI_Op op() { return MPI_LOR; }
 };

 /// INTERNAL ONLY
 template<typename T>
  struct is_mpi_op<logical_xor<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_logical_datatype<T> >
 {
   static MPI_Op op() { return MPI_LXOR; }
 };

 /// INTERNAL ONLY
 template<typename T>
  struct is_mpi_op<bitwise_and<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_byte_datatype<T> >
 {
   static MPI_Op op() { return MPI_BAND; }
 };

 /// INTERNAL ONLY
 template<typename T>
  struct is_mpi_op<bitwise_or<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_byte_datatype<T> >
 {
   static MPI_Op op() { return MPI_BOR; }
 };

 /// INTERNAL ONLY
 template<typename T>
  struct is_mpi_op<bitwise_xor<T>, T>
   : public boost::mpl::or_<is_mpi_integer_datatype<T>,
                            is_mpi_byte_datatype<T> >
 {
   static MPI_Op op() { return MPI_BXOR; }
 };

 namespace detail {
   // A helper class used to create user-defined MPI_Ops
   template<typename Op, typename T>
   class user_op
   {
   public:
     explicit user_op(Op& op)
     {
       BOOST_MPI_CHECK_RESULT(MPI_Op_create,
                              (&user_op<Op, T>::perform,
                               is_commutative<Op, T>::value,
                               &mpi_op));

       op_ptr = &op;
     }

     ~user_op()
     {
       if (std::uncaught_exception()) {
         // Ignore failure cases: there are obviously other problems
         // already, and we don't want to cause program termination if
         // MPI_Op_free fails.
         MPI_Op_free(&mpi_op);
       } else {
         BOOST_MPI_CHECK_RESULT(MPI_Op_free, (&mpi_op));
       }
     }

     MPI_Op& get_mpi_op()
     {
       return mpi_op;
     }

   private:
     MPI_Op mpi_op;
     static Op* op_ptr;

     static void BOOST_MPI_CALLING_CONVENTION perform(void* vinvec, void* voutvec, int* plen, MPI_Datatype*)
     {
       T* invec = static_cast<T*>(vinvec);
       T* outvec = static_cast<T*>(voutvec);
       std::transform(invec, invec + *plen, outvec, outvec, *op_ptr);
     }
   };

   template<typename Op, typename T> Op* user_op<Op, T>::op_ptr = 0;

 } // end namespace detail

 } } // end namespace boost::mpi

 #endif // BOOST_MPI_GET_MPI_OP_HPP
	// Copyright (C) 2004 The Trustees of Indiana University.
	// Copyright (C) 2005-2006 Douglas Gregor <doug.gregor -at- gmail.com>

	// Use, modification and distribution is subject to the Boost Software
	// License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
	// http://www.boost.org/LICENSE_1_0.txt)

	// Authors: Douglas Gregor
	// Andrew Lumsdaine

	/** @file operations.hpp
	*
	* This header provides a mapping from function objects to @c MPI_Op
	* constants used in MPI collective operations. It also provides
	* several new function object types not present in the standard @c
	* <functional> header that have direct mappings to @c MPI_Op.
	*/
	#ifndef BOOST_MPI_IS_MPI_OP_HPP
	#define BOOST_MPI_IS_MPI_OP_HPP

	#include <boost/mpi/config.hpp>
	#include <boost/mpl/bool.hpp>
	#include <boost/mpl/if.hpp>
	#include <boost/mpl/and.hpp>
	#include <boost/mpi/datatype.hpp>
	#include <boost/utility/enable_if.hpp>
	#include <functional>

	namespace boost { namespace mpi {

	template<typename Op, typename T> struct is_mpi_op;

	/**
	* @brief Determine if a function object type is commutative.
	*
	* This trait determines if an operation @c Op is commutative when
	* applied to values of type @c T. Parallel operations such as @c
	* reduce and @c prefix_sum can be implemented more efficiently with
	* commutative operations. To mark an operation as commutative, users
	* should specialize @c is_commutative and derive from the class @c
	* mpl::true_.
	*/
	template<typename Op, typename T>
	struct is_commutative : public mpl::false_ { };

	/**************************************************************************
	* Function objects for MPI operations not in <functional> header *
	**************************************************************************/

	/**
	* @brief Compute the maximum of two values.
	*
	* This binary function object computes the maximum of the two values
	* it is given. When used with MPI and a type @c T that has an
	* associated, built-in MPI data type, translates to @c MPI_MAX.
	*/
	template<typename T>
	struct maximum : public std::binary_function<T, T, T>
	{
	/** @returns the maximum of x and y. */
	const T& operator()(const T& x, const T& y) const
	{
	return x < y? y : x;
	}
	};

	/**
	* @brief Compute the minimum of two values.
	*
	* This binary function object computes the minimum of the two values
	* it is given. When used with MPI and a type @c T that has an
	* associated, built-in MPI data type, translates to @c MPI_MIN.
	*/
	template<typename T>
	struct minimum : public std::binary_function<T, T, T>
	{
	/** @returns the minimum of x and y. */
	const T& operator()(const T& x, const T& y) const
	{
	return x < y? x : y;
	}
	};


	/**
	* @brief Compute the bitwise AND of two integral values.
	*
	* This binary function object computes the bitwise AND of the two
	* values it is given. When used with MPI and a type @c T that has an
	* associated, built-in MPI data type, translates to @c MPI_BAND.
	*/
	template<typename T>
	struct bitwise_and : public std::binary_function<T, T, T>
	{
	/** @returns @c x & y. */
	T operator()(const T& x, const T& y) const
	{
	return x & y;
	}
	};

	/**
	* @brief Compute the bitwise OR of two integral values.
	*
	* This binary function object computes the bitwise OR of the two
	* values it is given. When used with MPI and a type @c T that has an
	* associated, built-in MPI data type, translates to @c MPI_BOR.
	*/
	template<typename T>
	struct bitwise_or : public std::binary_function<T, T, T>
	{
	/** @returns the @c x \| y. */
	T operator()(const T& x, const T& y) const
	{
	return x \| y;
	}
	};

	/**
	* @brief Compute the logical exclusive OR of two integral values.
	*
	* This binary function object computes the logical exclusive of the
	* two values it is given. When used with MPI and a type @c T that has
	* an associated, built-in MPI data type, translates to @c MPI_LXOR.
	*/
	template<typename T>
	struct logical_xor : public std::binary_function<T, T, T>
	{
	/** @returns the logical exclusive OR of x and y. */
	T operator()(const T& x, const T& y) const
	{
	return (x \|\| y) && !(x && y);
	}
	};

	/**
	* @brief Compute the bitwise exclusive OR of two integral values.
	*
	* This binary function object computes the bitwise exclusive OR of
	* the two values it is given. When used with MPI and a type @c T that
	* has an associated, built-in MPI data type, translates to @c
	* MPI_BXOR.
	*/
	template<typename T>
	struct bitwise_xor : public std::binary_function<T, T, T>
	{
	/** @returns @c x ^ y. */
	T operator()(const T& x, const T& y) const
	{
	return x ^ y;
	}
	};

	/**************************************************************************
	* MPI_Op queries *
	**************************************************************************/

	/**
	* @brief Determine if a function object has an associated @c MPI_Op.
	*
	* This trait determines if a function object type @c Op, when used
	* with argument type @c T, has an associated @c MPI_Op. If so, @c
	* is_mpi_op<Op,T> will derive from @c mpl::false_ and will
	* contain a static member function @c op that takes no arguments but
	* returns the associated @c MPI_Op value. For instance, @c
	* is_mpi_op<std::plus<int>,int>::op() returns @c MPI_SUM.
	*
	* Users may specialize @c is_mpi_op for any other class templates
	* that map onto operations that have @c MPI_Op equivalences, such as
	* bitwise OR, logical and, or maximum. However, users are encouraged
	* to use the standard function objects in the @c functional and @c
	* boost/mpi/operations.hpp headers whenever possible. For
	* function objects that are class templates with a single template
	* parameter, it may be easier to specialize @c is_builtin_mpi_op.
	*/
	template<typename Op, typename T>
	struct is_mpi_op : public mpl::false_ { };

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<maximum<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_floating_point_datatype<T> >
	{
	static MPI_Op op() { return MPI_MAX; }
	};

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<minimum<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_floating_point_datatype<T> >
	{
	static MPI_Op op() { return MPI_MIN; }
	};

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<std::plus<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_floating_point_datatype<T>,
	is_mpi_complex_datatype<T> >
	{
	static MPI_Op op() { return MPI_SUM; }
	};

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<std::multiplies<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_floating_point_datatype<T>,
	is_mpi_complex_datatype<T> >
	{
	static MPI_Op op() { return MPI_PROD; }
	};

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<std::logical_and<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_logical_datatype<T> >
	{
	static MPI_Op op() { return MPI_LAND; }
	};

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<std::logical_or<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_logical_datatype<T> >
	{
	static MPI_Op op() { return MPI_LOR; }
	};

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<logical_xor<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_logical_datatype<T> >
	{
	static MPI_Op op() { return MPI_LXOR; }
	};

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<bitwise_and<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_byte_datatype<T> >
	{
	static MPI_Op op() { return MPI_BAND; }
	};

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<bitwise_or<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_byte_datatype<T> >
	{
	static MPI_Op op() { return MPI_BOR; }
	};

	/// INTERNAL ONLY
	template<typename T>
	struct is_mpi_op<bitwise_xor<T>, T>
	: public boost::mpl::or_<is_mpi_integer_datatype<T>,
	is_mpi_byte_datatype<T> >
	{
	static MPI_Op op() { return MPI_BXOR; }
	};

	namespace detail {
	// A helper class used to create user-defined MPI_Ops
	template<typename Op, typename T>
	class user_op
	{
	public:
	explicit user_op(Op& op)
	{
	BOOST_MPI_CHECK_RESULT(MPI_Op_create,
	(&user_op<Op, T>::perform,
	is_commutative<Op, T>::value,
	&mpi_op));

	op_ptr = &op;
	}

	~user_op()
	{
	if (std::uncaught_exception()) {
	// Ignore failure cases: there are obviously other problems
	// already, and we don't want to cause program termination if
	// MPI_Op_free fails.
	MPI_Op_free(&mpi_op);
	} else {
	BOOST_MPI_CHECK_RESULT(MPI_Op_free, (&mpi_op));
	}
	}

	MPI_Op& get_mpi_op()
	{
	return mpi_op;
	}

	private:
	MPI_Op mpi_op;
	static Op* op_ptr;

	static void BOOST_MPI_CALLING_CONVENTION perform(void* vinvec, void* voutvec, int* plen, MPI_Datatype*)
	{
	T* invec = static_cast<T*>(vinvec);
	T* outvec = static_cast<T*>(voutvec);
	std::transform(invec, invec + plen, outvec, outvec, op_ptr);
	}
	};

	template<typename Op, typename T> Op* user_op<Op, T>::op_ptr = 0;

	} // end namespace detail

	} } // end namespace boost::mpi

	#endif // BOOST_MPI_GET_MPI_OP_HPP