bench/bench_static_vector.cpp - RealtimeRoboticsGroup/test - Gitiles

 // benchmark based on: http://cpp-next.com/archive/2010/10/howards-stl-move-semantics-benchmark/
 //
 //  @file   bench_static_vector.cpp
 //  @date   Aug 14, 2011
 //  @author Andrew Hundt <ATHundt@gmail.com>
 //
 //  (C) Copyright 2011-2013 Andrew Hundt <ATHundt@gmail.com>
 //  (C) Copyright 2013-2013 Ion Gaztanaga
 //
 //  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)
 //
 //  @brief  varray_benchmark.cpp compares the performance of boost::container::varray to boost::container::vector

 #include "varray.hpp"
 #include "boost/container/vector.hpp"
 #include "boost/container/static_vector.hpp"
 #include "../test/movable_int.hpp"
 #include <vector>
 #include <iostream>
 #include <boost/timer/timer.hpp>
 #include <algorithm>
 #include <exception>

 using boost::timer::cpu_timer;
 using boost::timer::cpu_times;
 using boost::timer::nanosecond_type;

 static const std::size_t N = 500;

 #ifdef NDEBUG
 static const std::size_t Iter = 50;
 #else
 static const std::size_t Iter = 5;
 #endif

 //#define BENCH_SIMPLE_CONSTRUCTION
 //#define BENCH_TRIVIAL_TYPE

 #ifdef BENCH_TRIVIAL_TYPE
 typedef std::size_t basic_type_t;
 #else
 typedef boost::container::test::copyable_int basic_type_t;
 #endif

 template<typename T>
 T &get_set(std::size_t)
 {
    #ifdef BENCH_SIMPLE_CONSTRUCTION
    T &t = *new T(N);
    for (std::size_t i = 0; i < N; ++i)
       t[i] = basic_type_t(std::rand());
    #else
    T &t = *new T;
    t.reserve(N);
    for (std::size_t i = 0; i < N; ++i)
       t.push_back(basic_type_t(std::rand()));
    #endif
    return t;
 }

 template<typename T>
 T &generate()
 {
    T &v = *new T;
    v.reserve(N);

    for (std::size_t i = 0; i < N; ++i){
       typename T::reference r = get_set<typename T::value_type>(i);
       v.push_back(boost::move(r));
       delete &r;
    }
    return v;
 }

 template<typename T>
 cpu_times time_it()
 {
    cpu_timer sortTime,rotateTime,destructionTime;
    sortTime.stop();rotateTime.stop();destructionTime.stop();
    cpu_timer totalTime, constructTime;
    std::srand (0);
    for(std::size_t i = 0; i< Iter; ++i){
      constructTime.resume();
      {
       T &v = generate<T>();
       constructTime.stop();
       sortTime.resume();
       std::sort(v.begin(), v.end());
       sortTime.stop();
       rotateTime.resume();
       std::rotate(v.begin(), v.begin() + v.size()/2, v.end());
       rotateTime.stop();
       destructionTime.resume();
       delete &v;
      }
      destructionTime.stop();
    }
    totalTime.stop();
    std::cout << "  construction took " << boost::timer::format(constructTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n");
    std::cout << "  sort took         " << boost::timer::format(sortTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n");
    std::cout << "  rotate took       " << boost::timer::format(rotateTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n");
    std::cout << "  destruction took  " << boost::timer::format(destructionTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n");
    std::cout << "  Total time =      " << boost::timer::format(totalTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n") << std::endl;
    return totalTime.elapsed();
 }

 void compare_times(cpu_times time_numerator, cpu_times time_denominator){
    std::cout
    << "\n  wall       = " << ((double)time_numerator.wall/(double)time_denominator.wall)
    << "\n  (user+sys) = " << ((double)(time_numerator.system+time_numerator.user)/(double)(time_denominator.system+time_denominator.user)) << "\n\n";
 }

 int main()
 {
    try {
       std::cout << "N = " << N << " Iter = " << Iter << "\n\n";

       std::cout << "varray benchmark:" << std::endl;
       cpu_times time_varray = time_it<boost::container::varray<boost::container::varray<basic_type_t,N>,N > >();

       std::cout << "boost::container::static_vector benchmark" << std::endl;
       cpu_times time_boost_static_vector = time_it<boost::container::static_vector<boost::container::static_vector<basic_type_t,N>,N > >();

       std::cout << "boost::container::vector benchmark"  << std::endl;
       cpu_times time_boost_vector = time_it<boost::container::vector<boost::container::vector<basic_type_t> > >();

       std::cout << "std::vector benchmark" << std::endl;
       cpu_times time_standard_vector = time_it<std::vector<std::vector<basic_type_t> > >();

       std::cout << "varray/boost::container::vector total time comparison:";
       compare_times(time_varray, time_boost_vector);

       std::cout << "varray/boost::container::static_vector total time comparison:";
       compare_times(time_varray, time_boost_static_vector);

       std::cout << "varray/std::vector total time comparison:";
       compare_times(time_varray,time_standard_vector);
    }catch(std::exception e){
       std::cout << e.what();
    }
    return 0;
 }
	// benchmark based on: http://cpp-next.com/archive/2010/10/howards-stl-move-semantics-benchmark/
	//
	// @file bench_static_vector.cpp
	// @date Aug 14, 2011
	// @author Andrew Hundt <ATHundt@gmail.com>
	//
	// (C) Copyright 2011-2013 Andrew Hundt <ATHundt@gmail.com>
	// (C) Copyright 2013-2013 Ion Gaztanaga
	//
	// 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)
	//
	// @brief varray_benchmark.cpp compares the performance of boost::container::varray to boost::container::vector

	#include "varray.hpp"
	#include "boost/container/vector.hpp"
	#include "boost/container/static_vector.hpp"
	#include "../test/movable_int.hpp"
	#include <vector>
	#include <iostream>
	#include <boost/timer/timer.hpp>
	#include <algorithm>
	#include <exception>

	using boost::timer::cpu_timer;
	using boost::timer::cpu_times;
	using boost::timer::nanosecond_type;

	static const std::size_t N = 500;

	#ifdef NDEBUG
	static const std::size_t Iter = 50;
	#else
	static const std::size_t Iter = 5;
	#endif

	//#define BENCH_SIMPLE_CONSTRUCTION
	//#define BENCH_TRIVIAL_TYPE

	#ifdef BENCH_TRIVIAL_TYPE
	typedef std::size_t basic_type_t;
	#else
	typedef boost::container::test::copyable_int basic_type_t;
	#endif

	template<typename T>
	T &get_set(std::size_t)
	{
	#ifdef BENCH_SIMPLE_CONSTRUCTION
	T &t = *new T(N);
	for (std::size_t i = 0; i < N; ++i)
	t[i] = basic_type_t(std::rand());
	#else
	T &t = *new T;
	t.reserve(N);
	for (std::size_t i = 0; i < N; ++i)
	t.push_back(basic_type_t(std::rand()));
	#endif
	return t;
	}

	template<typename T>
	T &generate()
	{
	T &v = *new T;
	v.reserve(N);

	for (std::size_t i = 0; i < N; ++i){
	typename T::reference r = get_set<typename T::value_type>(i);
	v.push_back(boost::move(r));
	delete &r;
	}
	return v;
	}

	template<typename T>
	cpu_times time_it()
	{
	cpu_timer sortTime,rotateTime,destructionTime;
	sortTime.stop();rotateTime.stop();destructionTime.stop();
	cpu_timer totalTime, constructTime;
	std::srand (0);
	for(std::size_t i = 0; i< Iter; ++i){
	constructTime.resume();
	{
	T &v = generate<T>();
	constructTime.stop();
	sortTime.resume();
	std::sort(v.begin(), v.end());
	sortTime.stop();
	rotateTime.resume();
	std::rotate(v.begin(), v.begin() + v.size()/2, v.end());
	rotateTime.stop();
	destructionTime.resume();
	delete &v;
	}
	destructionTime.stop();
	}
	totalTime.stop();
	std::cout << " construction took " << boost::timer::format(constructTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n");
	std::cout << " sort took " << boost::timer::format(sortTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n");
	std::cout << " rotate took " << boost::timer::format(rotateTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n");
	std::cout << " destruction took " << boost::timer::format(destructionTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n");
	std::cout << " Total time = " << boost::timer::format(totalTime.elapsed(), 6, "%ws wall, %ts CPU (%p%)\n") << std::endl;
	return totalTime.elapsed();
	}

	void compare_times(cpu_times time_numerator, cpu_times time_denominator){
	std::cout
	<< "\n wall = " << ((double)time_numerator.wall/(double)time_denominator.wall)
	<< "\n (user+sys) = " << ((double)(time_numerator.system+time_numerator.user)/(double)(time_denominator.system+time_denominator.user)) << "\n\n";
	}

	int main()
	{
	try {
	std::cout << "N = " << N << " Iter = " << Iter << "\n\n";

	std::cout << "varray benchmark:" << std::endl;
	cpu_times time_varray = time_it<boost::container::varray<boost::container::varray<basic_type_t,N>,N > >();

	std::cout << "boost::container::static_vector benchmark" << std::endl;
	cpu_times time_boost_static_vector = time_it<boost::container::static_vector<boost::container::static_vector<basic_type_t,N>,N > >();

	std::cout << "boost::container::vector benchmark" << std::endl;
	cpu_times time_boost_vector = time_it<boost::container::vector<boost::container::vector<basic_type_t> > >();

	std::cout << "std::vector benchmark" << std::endl;
	cpu_times time_standard_vector = time_it<std::vector<std::vector<basic_type_t> > >();

	std::cout << "varray/boost::container::vector total time comparison:";
	compare_times(time_varray, time_boost_vector);

	std::cout << "varray/boost::container::static_vector total time comparison:";
	compare_times(time_varray, time_boost_static_vector);

	std::cout << "varray/std::vector total time comparison:";
	compare_times(time_varray,time_standard_vector);
	}catch(std::exception e){
	std::cout << e.what();
	}
	return 0;
	}