boost_1_45_0/libs/spirit/optimization/measure.hpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Copyright David Abrahams, Matthias Troyer, Michael Gauckler
 // 2005. 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)
 #if !defined(BOOST_SPIRIT_TEST_BENCHMARK_HPP)
 #define BOOST_SPIRIT_TEST_BENCHMARK_HPP

 #ifdef _MSC_VER
 // inline aggressively
 # pragma inline_recursion(on) // turn on inline recursion
 # pragma inline_depth(255)    // max inline depth
 # define _SECURE_SCL 0
 #endif

 #include "high_resolution_timer.hpp"
 #include <iostream>
 #include <cstring>
 #include <boost/preprocessor/seq/for_each.hpp>
 #include <boost/preprocessor/stringize.hpp>

 namespace test
 {
     // This value is required to ensure that a smart compiler's dead
     // code elimination doesn't optimize away anything we're testing.
     // We'll use it to compute the return code of the executable to make
     // sure it's needed.
     int live_code;

     // Call objects of the given Accumulator type repeatedly
     template <class Accumulator>
     void hammer(long const repeats)
     {
         // Strategy: because the sum in an accumulator after each call
         // depends on the previous value of the sum, the CPU's pipeline
         // might be stalled while waiting for the previous addition to
         // complete.  Therefore, we allocate an array of accumulators,
         // and update them in sequence, so that there's no dependency
         // between adjacent addition operations.
         //
         // Additionally, if there were only one accumulator, the
         // compiler or CPU might decide to update the value in a
         // register rather that writing it back to memory.  we want each
         // operation to at least update the L1 cache.  *** Note: This
         // concern is specific to the particular application at which
         // we're targeting the test. ***

         // This has to be at least as large as the number of
         // simultaneous accumulations that can be executing in the
         // compiler pipeline.  A safe number here is larger than the
         // machine's maximum pipeline depth. If you want to test the L2
         // or L3 cache, or main memory, you can increase the size of
         // this array.  1024 is an upper limit on the pipeline depth of
         // current vector machines.

         const std::size_t number_of_accumulators = 1024;
         live_code = 0; // reset to zero

         Accumulator a[number_of_accumulators];

         for (long iteration = 0; iteration < repeats; ++iteration)
         {
             for (Accumulator* ap = a;  ap < a + number_of_accumulators; ++ap)
             {
                 ap->benchmark();
             }
         }

         // Accumulate all the partial sums to avoid dead code
         // elimination.
         for (Accumulator* ap = a; ap < a + number_of_accumulators; ++ap)
         {
             live_code += ap->val;
         }
     }

     // Measure the time required to hammer accumulators of the given type
     template <class Accumulator>
     double measure(long const repeats)
     {
         // Hammer accumulators a couple of times to ensure the
         // instruction cache is full of our test code, and that we don't
         // measure the cost of a page fault for accessing the data page
         // containing the memory where the accumulators will be
         // allocated
         hammer<Accumulator>(repeats);
         hammer<Accumulator>(repeats);

         // Now start a timer
         util::high_resolution_timer time;
         hammer<Accumulator>(repeats);   // This time, we'll measure
         return time.elapsed();          // return the elapsed time
     }

     template <class Accumulator>
     void report(char const* name, long const repeats)
     {
         std::cout.precision(10);
         std::cout << name << ": ";
         for (int i = 0; i < (20-int(strlen(name))); ++i)
             std::cout << ' ';
         std::cout << std::fixed << test::measure<Accumulator>(repeats) << " [s] ";
         Accumulator acc;
         acc.benchmark();
         std::cout << std::hex << "{checksum: " << acc.val << "}";
         std::cout << std::flush << std::endl;
     }

     struct base
     {
         base() : val(0) {}
         int val;    // This is needed to avoid dead-code elimination
     };

 #define BOOST_SPIRIT_TEST_HAMMER(r, data, elem)                     \
     test::hammer<elem>(repeats);
     /***/

 #define BOOST_SPIRIT_TEST_MEASURE(r, data, elem)                    \
     test::report<elem>(BOOST_PP_STRINGIZE(elem), repeats);          \
     /***/

 #define BOOST_SPIRIT_TEST_BENCHMARK(max_repeats, FSeq)              \
     long repeats = 100;                                             \
     double measured = 0;                                            \
     while (measured < 2.0 && repeats <= max_repeats)                \
     {                                                               \
         repeats *= 10;                                              \
         util::high_resolution_timer time;                           \
         BOOST_PP_SEQ_FOR_EACH(BOOST_SPIRIT_TEST_HAMMER, _, FSeq)    \
         measured = time.elapsed();                                  \
     }                                                               \
     BOOST_PP_SEQ_FOR_EACH(BOOST_SPIRIT_TEST_MEASURE, _, FSeq)       \
     /***/
 }

 #endif
	// Copyright David Abrahams, Matthias Troyer, Michael Gauckler
	// 2005. 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)
	#if !defined(BOOST_SPIRIT_TEST_BENCHMARK_HPP)
	#define BOOST_SPIRIT_TEST_BENCHMARK_HPP

	#ifdef _MSC_VER
	// inline aggressively
	# pragma inline_recursion(on) // turn on inline recursion
	# pragma inline_depth(255) // max inline depth
	# define _SECURE_SCL 0
	#endif

	#include "high_resolution_timer.hpp"
	#include <iostream>
	#include <cstring>
	#include <boost/preprocessor/seq/for_each.hpp>
	#include <boost/preprocessor/stringize.hpp>

	namespace test
	{
	// This value is required to ensure that a smart compiler's dead
	// code elimination doesn't optimize away anything we're testing.
	// We'll use it to compute the return code of the executable to make
	// sure it's needed.
	int live_code;

	// Call objects of the given Accumulator type repeatedly
	template <class Accumulator>
	void hammer(long const repeats)
	{
	// Strategy: because the sum in an accumulator after each call
	// depends on the previous value of the sum, the CPU's pipeline
	// might be stalled while waiting for the previous addition to
	// complete. Therefore, we allocate an array of accumulators,
	// and update them in sequence, so that there's no dependency
	// between adjacent addition operations.
	//
	// Additionally, if there were only one accumulator, the
	// compiler or CPU might decide to update the value in a
	// register rather that writing it back to memory. we want each
	// operation to at least update the L1 cache. *** Note: This
	// concern is specific to the particular application at which
	// we're targeting the test. ***

	// This has to be at least as large as the number of
	// simultaneous accumulations that can be executing in the
	// compiler pipeline. A safe number here is larger than the
	// machine's maximum pipeline depth. If you want to test the L2
	// or L3 cache, or main memory, you can increase the size of
	// this array. 1024 is an upper limit on the pipeline depth of
	// current vector machines.

	const std::size_t number_of_accumulators = 1024;
	live_code = 0; // reset to zero

	Accumulator a[number_of_accumulators];

	for (long iteration = 0; iteration < repeats; ++iteration)
	{
	for (Accumulator* ap = a; ap < a + number_of_accumulators; ++ap)
	{
	ap->benchmark();
	}
	}

	// Accumulate all the partial sums to avoid dead code
	// elimination.
	for (Accumulator* ap = a; ap < a + number_of_accumulators; ++ap)
	{
	live_code += ap->val;
	}
	}

	// Measure the time required to hammer accumulators of the given type
	template <class Accumulator>
	double measure(long const repeats)
	{
	// Hammer accumulators a couple of times to ensure the
	// instruction cache is full of our test code, and that we don't
	// measure the cost of a page fault for accessing the data page
	// containing the memory where the accumulators will be
	// allocated
	hammer<Accumulator>(repeats);
	hammer<Accumulator>(repeats);

	// Now start a timer
	util::high_resolution_timer time;
	hammer<Accumulator>(repeats); // This time, we'll measure
	return time.elapsed(); // return the elapsed time
	}

	template <class Accumulator>
	void report(char const* name, long const repeats)
	{
	std::cout.precision(10);
	std::cout << name << ": ";
	for (int i = 0; i < (20-int(strlen(name))); ++i)
	std::cout << ' ';
	std::cout << std::fixed << test::measure<Accumulator>(repeats) << " [s] ";
	Accumulator acc;
	acc.benchmark();
	std::cout << std::hex << "{checksum: " << acc.val << "}";
	std::cout << std::flush << std::endl;
	}

	struct base
	{
	base() : val(0) {}
	int val; // This is needed to avoid dead-code elimination
	};

	#define BOOST_SPIRIT_TEST_HAMMER(r, data, elem) \
	test::hammer<elem>(repeats);
	/***/

	#define BOOST_SPIRIT_TEST_MEASURE(r, data, elem) \
	test::report<elem>(BOOST_PP_STRINGIZE(elem), repeats); \
	/***/

	#define BOOST_SPIRIT_TEST_BENCHMARK(max_repeats, FSeq) \
	long repeats = 100; \
	double measured = 0; \
	while (measured < 2.0 && repeats <= max_repeats) \
	{ \
	repeats *= 10; \
	util::high_resolution_timer time; \
	BOOST_PP_SEQ_FOR_EACH(BOOST_SPIRIT_TEST_HAMMER, _, FSeq) \
	measured = time.elapsed(); \
	} \
	BOOST_PP_SEQ_FOR_EACH(BOOST_SPIRIT_TEST_MEASURE, _, FSeq) \
	/***/
	}

	#endif