https://hal.archives-ouvertes.fr/hal-02128878
Tip revision: 4201397494d9af8b687117e8ff4d85a8944f5c5a authored by Software Heritage on 11 June 2019, 10:15:02 UTC
hal: Deposit 298 in collection hal
hal: Deposit 298 in collection hal
Tip revision: 4201397
winograd.C
/*
* Copyright (C) 2012 FFLAS-FFPACK group.
*
* Extirpé form a m4 macro by Brice Boyer (briceboyer) <boyer.brice@gmail.com>.
*
*
* ========LICENCE========
* This file is part of the library FFLAS-FFPACK.
*
* FFLAS-FFPACK is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
* ========LICENCE========
*
*/
//#define LinBoxSrcOnly
#define DOUBLE_TO_FLOAT_CROSSOVER 0
#include "fflas-ffpack/fflas-ffpack-config.h"
#include "fflas-ffpack/utils/fflas_randommatrix.h"
#include <iostream>
#include <fstream>
#include <givaro/modular.h>
#include <givaro/modular-balanced.h>
#include "fflas-ffpack/utils/timer.h"
#include "fflas-ffpack/fflas/fflas.h"
template<class Field>
bool balanced(const Field & )
{
return false;
}
template <class T>
bool balanced(const Givaro::ModularBalanced<T>&)
{
return true;
}
#ifdef __GIVARO_USE_OPENMP
typedef Givaro::OMPTimer TTimer;
#else
typedef Givaro::Timer TTimer;
#endif
#define GFOPS(n,t) (2.0/t*(double)n/1000.0*(double)n/1000.0*(double)n/1000.0)
#include <ctime>
int main () {
using namespace std;
typedef FIELD Field;
Field F(17);
typedef Field::Element Element ;
size_t n=512, nmax=4000, prec=512, nbest=0, count=0;
TTimer chrono;
bool bound=false;
Element * A = FFLAS::fflas_new (F,nmax,nmax);
Element * B = FFLAS::fflas_new (F,nmax,nmax);
Element * C = FFLAS::fflas_new (F,nmax,nmax);
FFPACK::RandomMatrix (F, nmax, nmax, A, nmax);
FFPACK::RandomMatrix (F, nmax, nmax, B, nmax);
FFPACK::RandomMatrix (F, nmax, nmax, C, nmax);
time_t result = std::time(NULL);
cerr << std::endl
<< "---------------------------------------------------------------------"
<< std::endl << std::asctime(std::localtime(&result))
<< std::endl
<< "Threshold for finite field Strassen-Winograd matrix multiplication" ;
F.write(cerr << " (using ") << ')' << endl << endl;
cerr << "fgemm: n Classic Winograd 1 level" << std::endl;
cerr << " seconds Gfops seconds Gfops" << std::endl;
FFLAS::MMHelper<Field, FFLAS::MMHelperAlgo::Winograd> ClassicH(F,0, FFLAS::ParSeqHelper::Sequential());
FFLAS::MMHelper<Field, FFLAS::MMHelperAlgo::Winograd> WinogradH(F,1, FFLAS::ParSeqHelper::Sequential());
//warm up computation
FFLAS::fgemm(F, FFLAS::FflasNoTrans, FFLAS::FflasNoTrans, n, n, n, F.mOne, A, n, B, n, F.one, C, n, ClassicH);
do {
double classicTime, winogradTime;
int iter=3;
chrono.start();
for (int i=0;i<iter;i++)
FFLAS::fgemm(F, FFLAS::FflasNoTrans, FFLAS::FflasNoTrans, n, n, n, F.mOne, A, n, B, n, F.one, C, n, ClassicH);
chrono.stop();
classicTime = chrono.realtime()/iter;
chrono.clear(); chrono.start();
for (int i=0; i<iter; i++)
FFLAS::fgemm(F, FFLAS::FflasNoTrans, FFLAS::FflasNoTrans, n, n, n, F.mOne, A, n, B,n, F.one, C, n, WinogradH);
chrono.stop();
winogradTime = chrono.realtime()/iter;
cerr << " ";
cerr.width(4);
cerr << n;
cerr << " ";
cerr.width(15);
cerr << classicTime;
cerr << " ";
cerr.width(15);
cerr << GFOPS(n, classicTime) << " ";
cerr.width(15);
cerr << winogradTime;
cerr << " ";
cerr.width(15);
cerr << GFOPS(n, winogradTime) << endl;
if (classicTime > winogradTime ){
count++;
if (count > 1){
nbest = n;
bound = true;
prec = prec >> 1;
n -= prec;
}
}
else{
count=0;
if (bound)
prec=prec>>1;
n+=prec;
}
} while ((prec > 32 ) && (n < nmax));
cerr<<endl;
if (nbest != 0 ) {
if (typeid(Element).name() == typeid(double).name()) {
if ( balanced(F) ) {
cout << "#ifndef __FFLASFFPACK_WINOTHRESHOLD_BAL" << endl;
cout << "#define __FFLASFFPACK_WINOTHRESHOLD_BAL" << ' ' << nbest << endl;
cerr << "defined __FFLASFFPACK_WINOTHRESHOLD_BAL to " << nbest << "" << std::endl;
}
else {
cout << "#ifndef __FFLASFFPACK_WINOTHRESHOLD" << endl;
cout << "#define __FFLASFFPACK_WINOTHRESHOLD" << ' ' << nbest << endl;
cerr << "defined __FFLASFFPACK_WINOTHRESHOLD to " << nbest << "" << std::endl;
}
std::cout << "#endif" << endl << endl;
}
if (typeid(Element).name() == typeid(float).name()) {
if ( balanced(F) ) {
cout << "#ifndef __FFLASFFPACK_WINOTHRESHOLD_BAL_FLT" << endl;
cout << "#define __FFLASFFPACK_WINOTHRESHOLD_BAL_FLT" << ' ' << nbest << endl;
cerr << "defined __FFLASFFPACK_WINOTHRESHOLD_BAL_FLT to " << nbest << "" << std::endl;
}
else {
cout << "#ifndef __FFLASFFPACK_WINOTHRESHOLD_FLT" << endl;
cout << "#define __FFLASFFPACK_WINOTHRESHOLD_FLT" << ' ' << nbest << endl;
cerr << "defined __FFLASFFPACK_WINOTHRESHOLD_FLT to " << nbest << "" << std::endl;
}
cout << "#endif" << endl << endl;
}
}
FFLAS::fflas_delete(A);
FFLAS::fflas_delete(B);
FFLAS::fflas_delete(C);
return 0;
}
/* -*- mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
// vim:sts=4:sw=4:ts=4:et:sr:cino=>s,f0,{0,g0,(0,\:0,t0,+0,=s
