boost_1_45_0/libs/fusion/example/performance/sequence_efficiency.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /*=============================================================================
     Copyright (c) 2001-2006 Joel de Guzman

     Distributed under 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)
 ==============================================================================*/
 #include "measure.hpp"

 #define FUSION_MAX_LIST_SIZE 30
 #define FUSION_MAX_VECTOR_SIZE 30

 #include <boost/fusion/algorithm/iteration/accumulate.hpp>
 #include <boost/fusion/container/vector.hpp>
 #include <boost/fusion/container/list.hpp>

 #include <boost/type_traits/remove_reference.hpp>

 #include <boost/lexical_cast.hpp>
 #include <boost/preprocessor/stringize.hpp>
 #include <boost/preprocessor/enum.hpp>

 #include <iostream>

 #ifdef _MSC_VER
 // inline aggressively
 # pragma inline_recursion(on) // turn on inline recursion
 # pragma inline_depth(255)    // max inline depth
 #endif

 //  About the tests:
 //
 //  The tests below compare various fusion sequences to see how abstraction
 //  affects prformance.
 //
 //  We have 3 sequence sizes for each fusion sequence we're going to test.
 //
 //      small = 3 elements
 //      medium = 10 elements
 //      big = 30 elements
 //
 //  The sequences are initialized with values 0..N-1 from numeric strings
 //  parsed by boost::lexical_cast to make sure that the compiler is not
 //  optimizing by replacing the computation with constant results computed
 //  at compile time.
 //
 //  These sequences will be subjected to our accumulator which calls
 //  fusion::accumulate:
 //
 //      this->sum += boost::fusion::accumulate(seq, 0, poly_add());
 //
 //  where poly_add simply sums the current value with the content of
 //  the sequence element. This accumulator will be called many times
 //  through the "hammer" test (see measure.hpp).
 //
 //  The tests are compared against a base using a plain_accumulator
 //  which does a simple addition:
 //
 //      this->sum += x;

 namespace
 {
     struct poly_add
     {
         template<typename Sig>
         struct result;

         template<typename Lhs, typename Rhs>
         struct result<poly_add(Lhs, Rhs)>
             : boost::remove_reference<Lhs>
         {};

         template<typename Lhs, typename Rhs>
         Lhs operator()(const Lhs& lhs, const Rhs& rhs) const
         {
             return lhs + rhs;
         }
     };

     // Our Accumulator function
     template <typename T>
     struct accumulator
     {
         accumulator()
             : sum()
         {}

         template <typename Sequence>
         void operator()(Sequence const& seq)
         {
             this->sum += boost::fusion::accumulate(seq, 0, poly_add());
         }

         T sum;
     };

     // Plain Accumulator function
     template <typename T>
     struct plain_accumulator
     {
         plain_accumulator()
             : sum()
         {}

         template <typename X>
         void operator()(X const& x)
         {
             this->sum += x;
         }

         T sum;
     };

     template <typename T>
     void check(T const& seq, char const* info)
     {
         test::measure<accumulator<int> >(seq, 1);
         std::cout << info << test::live_code << std::endl;
     }

     template <typename T>
     void measure(T const& seq, char const* info, long const repeats, double base)
     {
         double t = test::measure<accumulator<int> >(seq, repeats);
         std::cout
             << info
             << t
             << " (" << int((t/base)*100) << "%)"
             << std::endl;
     }

     template <typename T>
     void test_assembler(T const& seq)
     {
         test::live_code = boost::fusion::accumulate(seq, 0, poly_add());
     }
 }

 // We'll initialize the sequences from numeric strings that
 // pass through boost::lexical_cast to make sure that the
 // compiler is not optimizing by replacing the computation
 // with constant results computed at compile time.
 #define INIT(z, n, text) boost::lexical_cast<int>(BOOST_PP_STRINGIZE(n))

 int main()
 {
     using namespace boost::fusion;
     std::cout.setf(std::ios::scientific);

     vector<
         int, int, int
     >
     vsmall(BOOST_PP_ENUM(3, INIT, _));

     list<
         int, int, int
     >
     lsmall(BOOST_PP_ENUM(3, INIT, _));

     vector<
         int, int, int, int, int, int, int, int, int, int
     >
     vmedium(BOOST_PP_ENUM(10, INIT, _));

     list<
         int, int, int, int, int, int, int, int, int, int
     >
     lmedium(BOOST_PP_ENUM(10, INIT, _));

     vector<
         int, int, int, int, int, int, int, int, int, int
       , int, int, int, int, int, int, int, int, int, int
       , int, int, int, int, int, int, int, int, int, int
     >
     vbig(BOOST_PP_ENUM(30, INIT, _));

     list<
         int, int, int, int, int, int, int, int, int, int
       , int, int, int, int, int, int, int, int, int, int
       , int, int, int, int, int, int, int, int, int, int
     >
     lbig(BOOST_PP_ENUM(30, INIT, _));

     // first decide how many repetitions to measure
     long repeats = 100;
     double measured = 0;
     while (measured < 2.0 && repeats <= 10000000)
     {
         repeats *= 10;

         boost::timer time;

         test::hammer<plain_accumulator<int> >(0, repeats);
         test::hammer<accumulator<int> >(vsmall, repeats);
         test::hammer<accumulator<int> >(lsmall, repeats);
         test::hammer<accumulator<int> >(vmedium, repeats);
         test::hammer<accumulator<int> >(lmedium, repeats);
         test::hammer<accumulator<int> >(vbig, repeats);
         test::hammer<accumulator<int> >(lbig, repeats);

         measured = time.elapsed();
     }

     test::measure<plain_accumulator<int> >(1, 1);
     std::cout
         << "base accumulated result:            "
         << test::live_code
         << std::endl;

     double base_time = test::measure<plain_accumulator<int> >(1, repeats);
     std::cout
         << "base time:                          "
         << base_time;

     std::cout
         << std::endl
         << "-------------------------------------------------------------------"
         << std::endl;

     check(vsmall,       "small vector accumulated result:    ");
     check(lsmall,       "small list accumulated result:      ");
     check(vmedium,      "medium vector accumulated result:   ");
     check(lmedium,      "medium list accumulated result:     ");
     check(vbig,         "big vector accumulated result:      ");
     check(lbig,         "big list accumulated result:        ");

     std::cout
         << "-------------------------------------------------------------------"
         << std::endl;

     measure(vsmall,     "small vector time:                  ", repeats, base_time);
     measure(lsmall,     "small list time:                    ", repeats, base_time);
     measure(vmedium,    "medium vector time:                 ", repeats, base_time);
     measure(lmedium,    "medium list time:                   ", repeats, base_time);
     measure(vbig,       "big vector time:                    ", repeats, base_time);
     measure(lbig,       "big list time:                      ", repeats, base_time);

     std::cout
         << "-------------------------------------------------------------------"
         << std::endl;

     // Let's see how this looks in assembler
     test_assembler(vmedium);

     // This is ultimately responsible for preventing all the test code
     // from being optimized away.  Change this to return 0 and you
     // unplug the whole test's life support system.
     return test::live_code != 0;
 }
	/*=============================================================================
	Copyright (c) 2001-2006 Joel de Guzman

	Distributed under 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)
	==============================================================================*/
	#include "measure.hpp"

	#define FUSION_MAX_LIST_SIZE 30
	#define FUSION_MAX_VECTOR_SIZE 30

	#include <boost/fusion/algorithm/iteration/accumulate.hpp>
	#include <boost/fusion/container/vector.hpp>
	#include <boost/fusion/container/list.hpp>

	#include <boost/type_traits/remove_reference.hpp>

	#include <boost/lexical_cast.hpp>
	#include <boost/preprocessor/stringize.hpp>
	#include <boost/preprocessor/enum.hpp>

	#include <iostream>

	#ifdef _MSC_VER
	// inline aggressively
	# pragma inline_recursion(on) // turn on inline recursion
	# pragma inline_depth(255) // max inline depth
	#endif

	// About the tests:
	//
	// The tests below compare various fusion sequences to see how abstraction
	// affects prformance.
	//
	// We have 3 sequence sizes for each fusion sequence we're going to test.
	//
	// small = 3 elements
	// medium = 10 elements
	// big = 30 elements
	//
	// The sequences are initialized with values 0..N-1 from numeric strings
	// parsed by boost::lexical_cast to make sure that the compiler is not
	// optimizing by replacing the computation with constant results computed
	// at compile time.
	//
	// These sequences will be subjected to our accumulator which calls
	// fusion::accumulate:
	//
	// this->sum += boost::fusion::accumulate(seq, 0, poly_add());
	//
	// where poly_add simply sums the current value with the content of
	// the sequence element. This accumulator will be called many times
	// through the "hammer" test (see measure.hpp).
	//
	// The tests are compared against a base using a plain_accumulator
	// which does a simple addition:
	//
	// this->sum += x;

	namespace
	{
	struct poly_add
	{
	template<typename Sig>
	struct result;

	template<typename Lhs, typename Rhs>
	struct result<poly_add(Lhs, Rhs)>
	: boost::remove_reference<Lhs>
	{};

	template<typename Lhs, typename Rhs>
	Lhs operator()(const Lhs& lhs, const Rhs& rhs) const
	{
	return lhs + rhs;
	}
	};

	// Our Accumulator function
	template <typename T>
	struct accumulator
	{
	accumulator()
	: sum()
	{}

	template <typename Sequence>
	void operator()(Sequence const& seq)
	{
	this->sum += boost::fusion::accumulate(seq, 0, poly_add());
	}

	T sum;
	};

	// Plain Accumulator function
	template <typename T>
	struct plain_accumulator
	{
	plain_accumulator()
	: sum()
	{}

	template <typename X>
	void operator()(X const& x)
	{
	this->sum += x;
	}

	T sum;
	};

	template <typename T>
	void check(T const& seq, char const* info)
	{
	test::measure<accumulator<int> >(seq, 1);
	std::cout << info << test::live_code << std::endl;
	}

	template <typename T>
	void measure(T const& seq, char const* info, long const repeats, double base)
	{
	double t = test::measure<accumulator<int> >(seq, repeats);
	std::cout
	<< info
	<< t
	<< " (" << int((t/base)*100) << "%)"
	<< std::endl;
	}

	template <typename T>
	void test_assembler(T const& seq)
	{
	test::live_code = boost::fusion::accumulate(seq, 0, poly_add());
	}
	}

	// We'll initialize the sequences from numeric strings that
	// pass through boost::lexical_cast to make sure that the
	// compiler is not optimizing by replacing the computation
	// with constant results computed at compile time.
	#define INIT(z, n, text) boost::lexical_cast<int>(BOOST_PP_STRINGIZE(n))

	int main()
	{
	using namespace boost::fusion;
	std::cout.setf(std::ios::scientific);

	vector<
	int, int, int
	>
	vsmall(BOOST_PP_ENUM(3, INIT, _));

	list<
	int, int, int
	>
	lsmall(BOOST_PP_ENUM(3, INIT, _));

	vector<
	int, int, int, int, int, int, int, int, int, int
	>
	vmedium(BOOST_PP_ENUM(10, INIT, _));

	list<
	int, int, int, int, int, int, int, int, int, int
	>
	lmedium(BOOST_PP_ENUM(10, INIT, _));

	vector<
	int, int, int, int, int, int, int, int, int, int
	, int, int, int, int, int, int, int, int, int, int
	, int, int, int, int, int, int, int, int, int, int
	>
	vbig(BOOST_PP_ENUM(30, INIT, _));

	list<
	int, int, int, int, int, int, int, int, int, int
	, int, int, int, int, int, int, int, int, int, int
	, int, int, int, int, int, int, int, int, int, int
	>
	lbig(BOOST_PP_ENUM(30, INIT, _));

	// first decide how many repetitions to measure
	long repeats = 100;
	double measured = 0;
	while (measured < 2.0 && repeats <= 10000000)
	{
	repeats *= 10;

	boost::timer time;

	test::hammer<plain_accumulator<int> >(0, repeats);
	test::hammer<accumulator<int> >(vsmall, repeats);
	test::hammer<accumulator<int> >(lsmall, repeats);
	test::hammer<accumulator<int> >(vmedium, repeats);
	test::hammer<accumulator<int> >(lmedium, repeats);
	test::hammer<accumulator<int> >(vbig, repeats);
	test::hammer<accumulator<int> >(lbig, repeats);

	measured = time.elapsed();
	}

	test::measure<plain_accumulator<int> >(1, 1);
	std::cout
	<< "base accumulated result: "
	<< test::live_code
	<< std::endl;

	double base_time = test::measure<plain_accumulator<int> >(1, repeats);
	std::cout
	<< "base time: "
	<< base_time;

	std::cout
	<< std::endl
	<< "-------------------------------------------------------------------"
	<< std::endl;

	check(vsmall, "small vector accumulated result: ");
	check(lsmall, "small list accumulated result: ");
	check(vmedium, "medium vector accumulated result: ");
	check(lmedium, "medium list accumulated result: ");
	check(vbig, "big vector accumulated result: ");
	check(lbig, "big list accumulated result: ");

	std::cout
	<< "-------------------------------------------------------------------"
	<< std::endl;

	measure(vsmall, "small vector time: ", repeats, base_time);
	measure(lsmall, "small list time: ", repeats, base_time);
	measure(vmedium, "medium vector time: ", repeats, base_time);
	measure(lmedium, "medium list time: ", repeats, base_time);
	measure(vbig, "big vector time: ", repeats, base_time);
	measure(lbig, "big list time: ", repeats, base_time);

	std::cout
	<< "-------------------------------------------------------------------"
	<< std::endl;

	// Let's see how this looks in assembler
	test_assembler(vmedium);

	// This is ultimately responsible for preventing all the test code
	// from being optimized away. Change this to return 0 and you
	// unplug the whole test's life support system.
	return test::live_code != 0;
	}