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libs/units/example/performance.cpp

// Boost.Units - A C++ library for zero-overhead dimensional analysis and 
// unit/quantity manipulation and conversion
//
// Copyright (C) 2003-2008 Matthias Christian Schabel
// Copyright (C) 2008 Steven Watanabe
//
// 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)

/** 
\file
    
\brief performance.cpp

\details
Test runtime performance.

Output:
@verbatim

multiplying ublas::matrix<double>(1000, 1000) : 25.03 seconds
multiplying ublas::matrix<quantity>(1000, 1000) : 24.49 seconds
tiled_matrix_multiply<double>(1000, 1000) : 1.12 seconds
tiled_matrix_multiply<quantity>(1000, 1000) : 1.16 seconds
solving y' = 1 - x + 4 * y with double: 1.97 seconds
solving y' = 1 - x + 4 * y with quantity: 1.84 seconds

@endverbatim
**/

#define _SCL_SECURE_NO_WARNINGS

#include <cstdlib>
#include <ctime>
#include <algorithm>
#include <iostream>
#include <iomanip>

#include <boost/config.hpp>
#include <boost/timer.hpp>
#include <boost/utility/result_of.hpp>

#ifdef BOOST_MSVC
#pragma warning(push)
#pragma warning(disable:4267; disable:4127; disable:4244; disable:4100)
#endif

#include <boost/numeric/ublas/matrix.hpp>

#ifdef BOOST_MSVC
#pragma warning(pop)
#endif

#include <boost/units/quantity.hpp>
#include <boost/units/systems/si.hpp>
#include <boost/units/cmath.hpp>
#include <boost/units/io.hpp>

enum {
    tile_block_size = 24
};

template<class T0, class T1, class Out>
void tiled_multiply_carray_inner(T0* first,
                                 T1* second,
                                 Out* out,
                                 int totalwidth,
                                 int width2,
                                 int height1,
                                 int common) {
    for(int j = 0; j < height1; ++j) {
        for(int i = 0; i < width2; ++i) {
            Out value = out[j * totalwidth + i];
            for(int k = 0; k < common; ++k) {
                value += first[k + totalwidth * j] * second[k * totalwidth + i];
            }
            out[j * totalwidth + i] = value;
        }
    }
}

template<class T0, class T1, class Out>
void tiled_multiply_carray_outer(T0* first,
                                 T1* second,
                                 Out* out,
                                 int width2,
                                 int height1,
                                 int common) {
    std::fill_n(out, width2 * height1, Out());
    int j = 0;
    for(; j < height1 - tile_block_size; j += tile_block_size) {
        int i = 0;
        for(; i < width2 - tile_block_size; i += tile_block_size) {
            int k = 0;
            for(; k < common - tile_block_size; k += tile_block_size) {
                tiled_multiply_carray_inner(
                    &first[k + width2 * j],
                    &second[k * width2 + i],
                    &out[j * width2 + i],
                    width2,
                    tile_block_size,
                    tile_block_size,
                    tile_block_size);
            }
            tiled_multiply_carray_inner(
                &first[k + width2 * j],
                &second[k * width2 + i],
                &out[j * width2 + i],
                width2,
                tile_block_size,
                tile_block_size,
                common - k);
        }
        int k = 0;
        for(; k < common - tile_block_size; k += tile_block_size) {
            tiled_multiply_carray_inner(
                &first[k + width2 * j],
                &second[k * width2 + i],
                &out[j * width2 + i],
                width2, width2 - i,
                tile_block_size,
                tile_block_size);
        }
        tiled_multiply_carray_inner(
            &first[k + width2 * j],
            &second[k * width2 + i],
            &out[j * width2 + i],
            width2, width2 - i,
            tile_block_size,
            common - k);
    }
    int i = 0;
    for(; i < width2 - tile_block_size; i += tile_block_size) {
        int k = 0;
        for(; k < common - tile_block_size; k += tile_block_size) {
            tiled_multiply_carray_inner(
                &first[k + width2 * j],
                &second[k * width2 + i],
                &out[j * width2 + i],
                width2,
                tile_block_size,
                height1 - j,
                tile_block_size);
        }
        tiled_multiply_carray_inner(
            &first[k + width2 * j],
            &second[k * width2 + i],
            &out[j * width2 + i],
            width2,
            tile_block_size,
            height1 - j,
            common - k);
    }
    int k = 0;
    for(; k < common - tile_block_size; k += tile_block_size) {
        tiled_multiply_carray_inner(
            &first[k + width2 * j],
            &second[k * width2 + i],
            &out[j * width2 + i],
            width2,
            width2 - i,
            height1 - j,
            tile_block_size);
    }
    tiled_multiply_carray_inner(
        &first[k + width2 * j],
        &second[k * width2 + i],
        &out[j * width2 + i],
        width2,
        width2 - i,
        height1 - j,
        common - k);
}

enum { max_value = 1000};

template<class F, class T, class N, class R>
BOOST_CXX14_CONSTEXPR
R solve_differential_equation(F f, T lower, T upper, N steps, R start) {
    typedef typename F::template result<T, R>::type f_result;
    T h = (upper - lower) / (1.0*steps);
    for(N i = N(); i < steps; ++i) {
        R y = start;
        T x = lower + h * (1.0*i);
        f_result k1 = f(x, y);
        f_result k2 = f(x + h / 2.0, y + h * k1 / 2.0);
        f_result k3 = f(x + h / 2.0, y + h * k2 / 2.0);
        f_result k4 = f(x + h, y + h * k3);
        start = y + h * (k1 + 2.0 * k2 + 2.0 * k3 + k4) / 6.0;
    }
    return(start);
}

using namespace boost::units;

//y' = 1 - x + 4 * y
struct f {
    template<class Arg1, class Arg2> struct result;
    
    BOOST_CONSTEXPR double operator()(const double& x, const double& y) const {
        return(1.0 - x + 4.0 * y);
    }

    boost::units::quantity<boost::units::si::velocity>
    BOOST_CONSTEXPR operator()(const quantity<si::time>& x,
                               const quantity<si::length>& y) const {
        using namespace boost::units;
        using namespace si;
        return(1.0 * meters / second -
                x * meters / pow<2>(seconds) +
                4.0 * y / seconds );
    }
};

template<> 
struct f::result<double,double> {
    typedef double type;
};

template<>
struct f::result<quantity<si::time>, quantity<si::length> > {
    typedef quantity<si::velocity> type;
};



//y' = 1 - x + 4 * y
//y' - 4 * y = 1 - x
//e^(-4 * x) * (dy - 4 * y * dx) = e^(-4 * x) * (1 - x) * dx
//d/dx(y * e ^ (-4 * x)) = e ^ (-4 * x) (1 - x) * dx

//d/dx(y * e ^ (-4 * x)) = e ^ (-4 * x) * dx - x * e ^ (-4 * x) * dx
//d/dx(y * e ^ (-4 * x)) = d/dx((-3/16 + 1/4 * x) * e ^ (-4 * x))
//y * e ^ (-4 * x) = (-3/16 + 1/4 * x) * e ^ (-4 * x) + C
//y = (-3/16 + 1/4 * x) + C/e ^ (-4 * x)
//y = 1/4 * x - 3/16 + C * e ^ (4 * x)

//y(0) = 1
//1 = - 3/16 + C
//C = 19/16
//y(x) = 1/4 * x - 3/16 + 19/16 * e ^ (4 * x)



int main() {
    boost::numeric::ublas::matrix<double> ublas_result;
    {
        boost::numeric::ublas::matrix<double> m1(max_value, max_value);
        boost::numeric::ublas::matrix<double> m2(max_value, max_value);
        std::srand(1492);
        for(int i = 0; i < max_value; ++i) {
            for(int j = 0; j < max_value; ++j) {
                m1(i,j) = std::rand();
                m2(i,j) = std::rand();
            }
        }
        std::cout << "multiplying ublas::matrix<double>("
                  << max_value << ", " << max_value << ") : ";
        boost::timer timer;
        ublas_result = (prod(m1, m2));
        std::cout << timer.elapsed() << " seconds" << std::endl;
    }
    typedef boost::numeric::ublas::matrix<
        boost::units::quantity<boost::units::si::dimensionless>
    > matrix_type;
    matrix_type ublas_resultq;
    {
        matrix_type m1(max_value, max_value);
        matrix_type m2(max_value, max_value);
        std::srand(1492);
        for(int i = 0; i < max_value; ++i) {
            for(int j = 0; j < max_value; ++j) {
                m1(i,j) = std::rand();
                m2(i,j) = std::rand();
            }
        }
        std::cout << "multiplying ublas::matrix<quantity>("
                  << max_value << ", " << max_value << ") : ";
        boost::timer timer;
        ublas_resultq = (prod(m1, m2));
        std::cout << timer.elapsed() << " seconds" << std::endl;
    }
    std::vector<double> cresult(max_value * max_value);
    {
        std::vector<double> m1(max_value * max_value);
        std::vector<double> m2(max_value * max_value);
        std::srand(1492);
        for(int i = 0; i < max_value * max_value; ++i) {
            m1[i] = std::rand();
            m2[i] = std::rand();
        }
        std::cout << "tiled_matrix_multiply<double>("
                  << max_value << ", " << max_value << ") : ";
        boost::timer timer;
        tiled_multiply_carray_outer(
            &m1[0],
            &m2[0],
            &cresult[0],
            max_value,
            max_value,
            max_value);
        std::cout << timer.elapsed() << " seconds" << std::endl;
    }
    std::vector<
        boost::units::quantity<boost::units::si::energy>
    >  cresultq(max_value * max_value);
    {
        std::vector<
            boost::units::quantity<boost::units::si::force>
        > m1(max_value * max_value);
        std::vector<
            boost::units::quantity<boost::units::si::length>
        > m2(max_value * max_value);
        std::srand(1492);
        for(int i = 0; i < max_value * max_value; ++i) {
            m1[i] = std::rand() * boost::units::si::newtons;
            m2[i] = std::rand() * boost::units::si::meters;
        }
        std::cout << "tiled_matrix_multiply<quantity>("
                  << max_value << ", " << max_value << ") : ";
        boost::timer timer;
        tiled_multiply_carray_outer(
            &m1[0],
            &m2[0],
            &cresultq[0],
            max_value,
            max_value,
            max_value);
        std::cout << timer.elapsed() << " seconds" << std::endl;
    }
    for(int i = 0; i < max_value; ++i) {
        for(int j = 0; j < max_value; ++j) {
            const double diff =
                std::abs(ublas_result(i,j) - cresult[i * max_value + j]);
            if(diff > ublas_result(i,j) /1e14) {
                std::cout << std::setprecision(15) << "Uh Oh. ublas_result("
                          << i << "," << j << ") = " << ublas_result(i,j)
                          << std::endl
                          << "cresult[" << i << " * " << max_value << " + "
                          << j << "] = " << cresult[i * max_value + j]
                          << std::endl;
                return(EXIT_FAILURE);
            }
        }
    }
    {
        std::vector<double> values(1000);
        std::cout << "solving y' = 1 - x + 4 * y with double: ";
        boost::timer timer;
        for(int i = 0; i < 1000; ++i) {
            const double x = .1 * i;
            values[i] = solve_differential_equation(f(), 0.0, x, i * 100, 1.0);
        }
        std::cout << timer.elapsed() << " seconds" << std::endl;
        for(int i = 0; i < 1000; ++i) {
            const double x = .1 * i;
            const double value = 1.0/4.0 * x - 3.0/16.0 + 19.0/16.0 * std::exp(4 * x);
            if(std::abs(values[i] - value) > value / 1e9) {
                std::cout << std::setprecision(15) << "i = : " << i
                          << ", value = " << value << " approx = "  << values[i]
                          << std::endl;
                return(EXIT_FAILURE);
            }
        }
    }
    {
        using namespace boost::units;
        using namespace si;
        std::vector<quantity<length> > values(1000);
        std::cout << "solving y' = 1 - x + 4 * y with quantity: ";
        boost::timer timer;
        for(int i = 0; i < 1000; ++i) {
            const quantity<si::time> x = .1 * i * seconds;
            values[i] = solve_differential_equation(
                f(),
                0.0 * seconds,
                x,
                i * 100,
                1.0 * meters);
        }
        std::cout << timer.elapsed() << " seconds" << std::endl;
        for(int i = 0; i < 1000; ++i) {
            const double x = .1 * i;
            const quantity<si::length> value =
                (1.0/4.0 * x - 3.0/16.0 + 19.0/16.0 * std::exp(4 * x)) * meters;
            if(abs(values[i] - value) > value / 1e9) {
                std::cout << std::setprecision(15) << "i = : " << i
                          << ", value = " << value << " approx = "
                          << values[i] << std::endl;
                return(EXIT_FAILURE);
            }
        }
    }
}