Exemple #1
0
int main(int argc, char *argv[])
{
	LOGOG_INITIALIZE();

	TCLAP::CmdLine cmd("Simple matrix vector multiplication test", ' ', "0.1");

	// Define a value argument and add it to the command line.
	// A value arg defines a flag and a type of value that it expects,
	// such as "-m matrix".
	TCLAP::ValueArg<std::string> matrix_arg("m", "matrix", "input matrix file", true, "", "string");

	// Add the argument mesh_arg to the CmdLine object. The CmdLine object
	// uses this Arg to parse the command line.
	cmd.add( matrix_arg );

	TCLAP::ValueArg<unsigned> n_cores_arg("p", "number-cores", "number of cores to use", false, 1, "number");
	cmd.add( n_cores_arg );

	TCLAP::ValueArg<unsigned> n_mults_arg("n", "number-of-multiplications", "number of multiplications to perform", true, 10, "number");
	cmd.add( n_mults_arg );

	TCLAP::ValueArg<std::string> output_arg("o", "output", "output file", false, "", "string");
	cmd.add( output_arg );

	TCLAP::ValueArg<unsigned> verbosity_arg("v", "verbose", "level of verbosity [0 very low information, 1 much information]", false, 0, "string");
	cmd.add( verbosity_arg );

	cmd.parse( argc, argv );

	// read the number of multiplication to execute
	unsigned n_mults (n_mults_arg.getValue());
	std::string fname_mat (matrix_arg.getValue());

	FormatterCustom *custom_format (new FormatterCustom);
	logog::Cout *logogCout(new logog::Cout);
	logogCout->SetFormatter(*custom_format);

	logog::LogFile *logog_file(NULL);
	if (! output_arg.getValue().empty()) {
		logog_file = new logog::LogFile(output_arg.getValue().c_str());
		logog_file->SetFormatter( *custom_format );
	}

	// read number of threads
	unsigned n_threads (n_cores_arg.getValue());

	INFO("%s was build with compiler %s",
		argv[0],
		BaseLib::BuildInfo::cmake_cxx_compiler.c_str());
#ifdef NDEBUG
	INFO("CXX_FLAGS: %s %s",
		BaseLib::BuildInfo::cmake_cxx_flags.c_str(),
		BaseLib::BuildInfo::cmake_cxx_flags_release.c_str());
#else
	INFO("CXX_FLAGS: %s %s",
		BaseLib::BuildInfo::cmake_cxx_flags.c_str(),
		BaseLib::BuildInfo::cmake_cxx_flags_debug.c_str());
#endif

#ifdef UNIX
	const int max_host_name_len (255);
	char *hostname(new char[max_host_name_len]);
	if (gethostname(hostname, max_host_name_len) == 0)
		INFO("hostname: %s", hostname);
	delete [] host_name_len;
#endif

	// *** reading matrix in crs format from file
	std::ifstream in(fname_mat.c_str(), std::ios::in | std::ios::binary);
	double *A(NULL);
	unsigned *iA(NULL), *jA(NULL), n;
	if (in) {
		INFO("reading matrix from %s ...", fname_mat.c_str());
		BaseLib::RunTime timer;
		timer.start();
		CS_read(in, n, iA, jA, A);
		INFO("\t- took %e s", timer.elapsed());
	} else {
		INFO("error reading matrix from %s", fname_mat.c_str());
		return -1;
	}
	unsigned nnz(iA[n]);
	INFO("\tParameters read: n=%d, nnz=%d", n, nnz);

#ifdef _OPENMP
	omp_set_num_threads(n_threads);
	unsigned *mat_entries_per_core(new unsigned[n_threads]);
	for (unsigned k(0); k<n_threads; k++) {
		mat_entries_per_core[k] = 0;
	}

	OPENMP_LOOP_TYPE i;
	{
#pragma omp parallel for
		for (i = 0; i < n; i++) {
			mat_entries_per_core[omp_get_thread_num()] += iA[i + 1] - iA[i];
		}
	}

	INFO("*** work per core ***");
	for (unsigned k(0); k<n_threads; k++) {
		INFO("\t%d\t%d", k, mat_entries_per_core[k]);
	}
#endif

#ifdef _OPENMP
	omp_set_num_threads(n_threads);
	MathLib::CRSMatrixOpenMP<double, unsigned> mat (n, iA, jA, A);
#else
	MathLib::CRSMatrix<double, unsigned> mat (n, iA, jA, A);
#endif

	double *x(new double[n]);
	double *y(new double[n]);

	for (unsigned k(0); k<n; ++k)
		x[k] = 1.0;

	INFO("*** %d matrix vector multiplications (MVM) with Toms amuxCRS (%d threads) ...", n_mults, n_threads);
	BaseLib::RunTime run_timer;
	BaseLib::CPUTime cpu_timer;
	run_timer.start();
	cpu_timer.start();
	for (std::size_t k(0); k<n_mults; k++) {
		mat.amux (1.0, x, y);
	}

	INFO("\t[MVM] - took %e sec cpu time, %e sec run time", cpu_timer.elapsed(), run_timer.elapsed());

	delete [] x;
	delete [] y;

	delete custom_format;
	delete logogCout;
	delete logog_file;
	LOGOG_SHUTDOWN();

	return 0;
}
Exemple #2
0
int main(int argc, char *argv[])
{
	if (argc < 4) {
		std::cout << "Usage: " << argv[0] << " num_of_threads matrix number_of_multiplications resultfile" << std::endl;
		exit (1);
	}

	// read number of threads
	unsigned n_threads (1);
	n_threads = atoi (argv[1]);

	// read the number of multiplication to execute
	unsigned n_mults (0);
	n_mults = atoi (argv[3]);

	std::string fname_mat (argv[2]);

	bool verbose (true);

	// *** reading matrix in crs format from file
	std::ifstream in(fname_mat.c_str(), std::ios::in | std::ios::binary);
	double *A(NULL);
	unsigned *iA(NULL), *jA(NULL), n;
	if (in) {
		if (verbose) {
			std::cout << "reading matrix from " << fname_mat << " ... " << std::flush;
		}
		RunTimeTimer timer;
		timer.start();
		CS_read(in, n, iA, jA, A);
		timer.stop();
		if (verbose) {
			std::cout << "ok, " << timer.elapsed() << " s)" << std::endl;
		}
	} else {
		std::cout << "error reading matrix from " << fname_mat << std::endl;
	}
	unsigned nnz(iA[n]);
	if (verbose) {
		std::cout << "Parameters read: n=" << n << ", nnz=" << nnz << std::endl;
	}

#ifdef _OPENMP
	omp_set_num_threads(n_threads);
	MathLib::CRSMatrixOpenMP<double, unsigned> mat (n, iA, jA, A);
#else
	MathLib::CRSMatrix<double, unsigned> mat (n, iA, jA, A);
#endif
//	CRSMatrixPThreads<double> mat (n, iA, jA, A, n_threads);
	std::cout << mat.getNRows() << " x " << mat.getNCols() << std::endl;

	double *x(new double[n]);
	double *y(new double[n]);

	for (unsigned k(0); k<n; ++k)
		x[k] = 1.0;

	if (verbose) {
		std::cout << "matrix vector multiplication with Toms amuxCRS (" << n_threads << " threads) ... " << std::flush;
	}
	RunTimeTimer run_timer;
	CPUTimeTimer cpu_timer;
	run_timer.start();
	cpu_timer.start();
	for (size_t k(0); k<n_mults; k++) {
		mat.amux (1.0, x, y);
	}
	cpu_timer.stop();
	run_timer.stop();

	if (verbose) {
		std::cout << "done [" << cpu_timer.elapsed() << " sec cpu time], ["
				<< run_timer.elapsed() << " sec run time]" << std::endl;
	} else {
		if (argc == 5) {
			std::ofstream result_os (argv[4], std::ios::app);
			if (result_os) {
				result_os << cpu_timer.elapsed() << "\t" << run_timer.elapsed() << std::endl;
			}
			result_os.close();
		} else {
			std::cout << cpu_timer.elapsed() << "\t" << run_timer.elapsed() << std::endl;
		}
	}

	delete [] x;
	delete [] y;

	return 0;
}