Beispiel #1
0
int main( int argc, char** argv )
{
	obj_t a, c;
	obj_t c_save;
	obj_t alpha, beta;
	dim_t m, k;
	dim_t p;
	dim_t p_begin, p_end, p_inc;
	int   m_input, k_input;
	num_t dt;
	int   r, n_repeats;
	uplo_t uploc;
	trans_t transa;
	f77_char f77_uploc;
	f77_char f77_transa;

	double dtime;
	double dtime_save;
	double gflops;

	bli_init();

	//bli_error_checking_level_set( BLIS_NO_ERROR_CHECKING );

	n_repeats = 3;

#ifndef PRINT
	p_begin = 200;
	p_end   = 2000;
	p_inc   = 200;

	m_input = -1;
	k_input = -1;
#else
	p_begin = 16;
	p_end   = 16;
	p_inc   = 1;

	m_input = 3;
	k_input = 1;
#endif

#if 1
	//dt = BLIS_FLOAT;
	dt = BLIS_DOUBLE;
#else
	//dt = BLIS_SCOMPLEX;
	dt = BLIS_DCOMPLEX;
#endif

	uploc = BLIS_LOWER;
	//uploc = BLIS_UPPER;

	transa = BLIS_NO_TRANSPOSE;

	bli_param_map_blis_to_netlib_uplo( uploc, &f77_uploc );
	bli_param_map_blis_to_netlib_trans( transa, &f77_transa );


	for ( p = p_begin; p <= p_end; p += p_inc )
	{
		if ( m_input < 0 ) m = p * ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( k_input < 0 ) k = p * ( dim_t )abs(k_input);
		else               k =     ( dim_t )    k_input;

		bli_obj_create( dt, 1, 1, 0, 0, &alpha );
		bli_obj_create( dt, 1, 1, 0, 0, &beta );

		if ( bli_does_trans( transa ) )
			bli_obj_create( dt, k, m, 0, 0, &a );
		else
			bli_obj_create( dt, m, k, 0, 0, &a );
		bli_obj_create( dt, m, m, 0, 0, &c );
		bli_obj_create( dt, m, m, 0, 0, &c_save );

		bli_randm( &a );
		bli_randm( &c );

		bli_obj_set_struc( BLIS_HERMITIAN, c );
		bli_obj_set_uplo( uploc, c );

		bli_obj_set_conjtrans( transa, a );


		bli_setsc(  (2.0/1.0), 0.0, &alpha );
		bli_setsc( -(1.0/1.0), 0.0, &beta );


		bli_copym( &c, &c_save );
	
		dtime_save = 1.0e9;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &c_save, &c );


			dtime = bli_clock();


#ifdef PRINT
			bli_printm( "a", &a, "%4.1f", "" );
			bli_printm( "c", &c, "%4.1f", "" );
#endif

#ifdef BLIS

			bli_herk( &alpha,
			          &a,
			          &beta,
			          &c );

#else
		if ( bli_is_float( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldc    = bli_obj_col_stride( c );
			float*   alphap = bli_obj_buffer( alpha );
			float*   ap     = bli_obj_buffer( a );
			float*   betap  = bli_obj_buffer( beta );
			float*   cp     = bli_obj_buffer( c );

			ssyrk_( &f77_uploc,
			        &f77_transa,
			        &mm,
			        &kk,
			        alphap,
			        ap, &lda,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_double( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldc    = bli_obj_col_stride( c );
			double*  alphap = bli_obj_buffer( alpha );
			double*  ap     = bli_obj_buffer( a );
			double*  betap  = bli_obj_buffer( beta );
			double*  cp     = bli_obj_buffer( c );

			dsyrk_( &f77_uploc,
			        &f77_transa,
			        &mm,
			        &kk,
			        alphap,
			        ap, &lda,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_scomplex( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldc    = bli_obj_col_stride( c );
			float*     alphap = bli_obj_buffer( alpha );
			scomplex*  ap     = bli_obj_buffer( a );
			float*     betap  = bli_obj_buffer( beta );
			scomplex*  cp     = bli_obj_buffer( c );

			cherk_( &f77_uploc,
			        &f77_transa,
			        &mm,
			        &kk,
			        alphap,
			        ap, &lda,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_dcomplex( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldc    = bli_obj_col_stride( c );
			double*    alphap = bli_obj_buffer( alpha );
			dcomplex*  ap     = bli_obj_buffer( a );
			double*    betap  = bli_obj_buffer( beta );
			dcomplex*  cp     = bli_obj_buffer( c );

			zherk_( &f77_uploc,
			        &f77_transa,
			        &mm,
			        &kk,
			        alphap,
			        ap, &lda,
			        betap,
			        cp, &ldc );
		}
#endif

#ifdef PRINT
			bli_printm( "c after", &c, "%4.1f", "" );
			exit(1);
#endif


			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}

		gflops = ( 1.0 * m * k * m ) / ( dtime_save * 1.0e9 );

		if ( bli_is_complex( dt ) ) gflops *= 4.0;

#ifdef BLIS
		printf( "data_herk_blis" );
#else
		printf( "data_herk_%s", BLAS );
#endif
		printf( "( %2lu, 1:4 ) = [ %4lu %4lu  %10.3e  %6.3f ];\n",
		        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
		        ( unsigned long )m,
		        ( unsigned long )k, dtime_save, gflops );


		bli_obj_free( &alpha );
		bli_obj_free( &beta );

		bli_obj_free( &a );
		bli_obj_free( &c );
		bli_obj_free( &c_save );
	}

	bli_finalize();

	return 0;
}
Beispiel #2
0
int main( int argc, char** argv )
{
	obj_t a, b, c;
	obj_t c_save;
	obj_t alpha, beta;
	dim_t m, n;
	dim_t p;
	dim_t p_begin, p_end, p_inc;
	int   m_input, n_input;
	num_t dt_a, dt_b, dt_c;
	num_t dt_alpha, dt_beta;
	int   r, n_repeats;
	side_t side;
	uplo_t uplo;

	double dtime;
	double dtime_save;
	double gflops;

	bli_init();

	n_repeats = 3;

#ifndef PRINT
	p_begin = 40;
	p_end   = 2000;
	p_inc   = 40;

	m_input = -1;
	n_input = -1;
#else
	p_begin = 16;
	p_end   = 16;
	p_inc   = 1;

	m_input = 8;
	n_input = 4;
#endif

	dt_a = BLIS_DOUBLE;
	dt_b = BLIS_DOUBLE;
	dt_c = BLIS_DOUBLE;
	dt_alpha = BLIS_DOUBLE;
	dt_beta = BLIS_DOUBLE;

	side = BLIS_LEFT;
	//side = BLIS_RIGHT;

	uplo = BLIS_LOWER;

	for ( p = p_begin; p <= p_end; p += p_inc )
	{

		if ( m_input < 0 ) m = p * ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( n_input < 0 ) n = p * ( dim_t )abs(n_input);
		else               n =     ( dim_t )    n_input;


		bli_obj_create( dt_alpha, 1, 1, 0, 0, &alpha );
		bli_obj_create( dt_beta,  1, 1, 0, 0, &beta );

		if ( bli_is_left( side ) )
			bli_obj_create( dt_a, m, m, 0, 0, &a );
		else
			bli_obj_create( dt_a, n, n, 0, 0, &a );
		bli_obj_create( dt_b, m, n, 0, 0, &b );
		bli_obj_create( dt_c, m, n, 0, 0, &c );
		bli_obj_create( dt_c, m, n, 0, 0, &c_save );

		bli_obj_set_struc( BLIS_TRIANGULAR, a );
		bli_obj_set_uplo( uplo, a );

		bli_randm( &a );
		bli_randm( &c );
		bli_randm( &b );


		bli_setsc(  (2.0/1.0), 0.0, &alpha );
		bli_setsc( -(1.0/1.0), 0.0, &beta );


		bli_copym( &c, &c_save );
	
		dtime_save = 1.0e9;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &c_save, &c );

			dtime = bli_clock();


#ifdef PRINT
			bli_printm( "a", &a, "%11.8f", "" );
			bli_printm( "c", &c, "%14.11f", "" );
#endif

#ifdef BLIS
			//bli_error_checking_level_set( BLIS_NO_ERROR_CHECKING );

			bli_trmm( side,
			          &alpha,
			          &a,
			          &c );

#else

			f77_char side   = 'L';
			f77_char uplo   = 'L';
			f77_char transa = 'N';
			f77_char diag   = 'N';
			f77_int  mm     = bli_obj_length( c );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldc    = bli_obj_col_stride( c );
			double*  alphap = bli_obj_buffer( alpha );
			double*  ap     = bli_obj_buffer( a );
			double*  cp     = bli_obj_buffer( c );

			dtrmm_( &side,
			        &uplo,
			        &transa,
			        &diag,
			        &mm,
			        &nn,
			        alphap,
			        ap, &lda,
			        cp, &ldc );
#endif

#ifdef PRINT
			bli_printm( "c after", &c, "%14.11f", "" );
			exit(1);
#endif



			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}

		if ( bli_is_left( side ) )
			gflops = ( 1.0 * m * m * n ) / ( dtime_save * 1.0e9 );
		else
			gflops = ( 1.0 * m * n * n ) / ( dtime_save * 1.0e9 );

#ifdef BLIS
		printf( "data_trmm_blis" );
#else
		printf( "data_trmm_%s", BLAS );
#endif
		printf( "( %2lu, 1:4 ) = [ %4lu %4lu  %10.3e  %6.3f ];\n",
		        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
		        ( unsigned long )m,
		        ( unsigned long )n, dtime_save, gflops );


		bli_obj_free( &alpha );
		bli_obj_free( &beta );

		bli_obj_free( &a );
		bli_obj_free( &b );
		bli_obj_free( &c );
		bli_obj_free( &c_save );
	}

	bli_finalize();

	return 0;
}
Beispiel #3
0
int main( int argc, char** argv )
{
	obj_t a, b, c;
	obj_t c_save;
	obj_t alpha, beta;
	dim_t m, n;
	dim_t p;
	dim_t p_begin, p_end, p_inc;
	int   m_input, n_input;
	num_t dt_a, dt_b, dt_c;
	num_t dt_alpha, dt_beta;
	int   r, n_repeats;
	side_t side;
	uplo_t uplo;

	double dtime;
	double dtime_save;
	double gflops;

	bli_init();

	n_repeats = 3;

    if( argc < 7 ) 
    {   
        printf("Usage:\n");
        printf("test_foo.x m n k p_begin p_inc p_end:\n");
        exit;
    }   

    int world_size, world_rank, provided;
    MPI_Init_thread( NULL, NULL, MPI_THREAD_FUNNELED, &provided );
    MPI_Comm_size( MPI_COMM_WORLD, &world_size );
    MPI_Comm_rank( MPI_COMM_WORLD, &world_rank );

    m_input = strtol( argv[1], NULL, 10 );
    n_input = strtol( argv[2], NULL, 10 );
    p_begin = strtol( argv[4], NULL, 10 );
    p_inc   = strtol( argv[5], NULL, 10 );
    p_end   = strtol( argv[6], NULL, 10 );

#if 1
	dt_a = BLIS_DOUBLE;
	dt_b = BLIS_DOUBLE;
	dt_c = BLIS_DOUBLE;
	dt_alpha = BLIS_DOUBLE;
	dt_beta = BLIS_DOUBLE;
#else
	dt_a = dt_b = dt_c = dt_alpha = dt_beta = BLIS_FLOAT; 
	//dt_a = dt_b = dt_c = dt_alpha = dt_beta = BLIS_SCOMPLEX; 
#endif

	side = BLIS_LEFT;
	//side = BLIS_RIGHT;

	uplo = BLIS_LOWER;
	//uplo = BLIS_UPPER;

    for ( p = p_begin + world_rank * p_inc; p <= p_end; p += p_inc * world_size )
	{

		if ( m_input < 0 ) m = p * ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( n_input < 0 ) n = p * ( dim_t )abs(n_input);
		else               n =     ( dim_t )    n_input;


		bli_obj_create( dt_alpha, 1, 1, 0, 0, &alpha );
		bli_obj_create( dt_beta,  1, 1, 0, 0, &beta );

		if ( bli_is_left( side ) )
			bli_obj_create( dt_a, m, m, 0, 0, &a );
		else
			bli_obj_create( dt_a, n, n, 0, 0, &a );
		bli_obj_create( dt_b, m, n, 0, 0, &b );
		bli_obj_create( dt_c, m, n, 0, 0, &c );
		bli_obj_create( dt_c, m, n, 0, 0, &c_save );

		bli_obj_set_struc( BLIS_TRIANGULAR, &a );
		bli_obj_set_uplo( uplo, &a );
		//bli_obj_set_diag( BLIS_UNIT_DIAG, &a );

		bli_randm( &a );
		bli_randm( &c );
		bli_randm( &b );

/*
		{ 
			obj_t a2;

			bli_obj_alias_to( &a, &a2 );
			bli_obj_toggle_uplo( &a2 );
			bli_obj_inc_diag_offset( 1, &a2 );
			bli_setm( &BLIS_ZERO, &a2 );
			bli_obj_inc_diag_offset( -2, &a2 );
			bli_obj_toggle_uplo( &a2 );
			bli_obj_set_diag( BLIS_NONUNIT_DIAG, &a2 );
			bli_scalm( &BLIS_TWO, &a2 );
			//bli_scalm( &BLIS_TWO, &a );
		} 
*/

		bli_setsc(  (2.0/1.0), 0.0, &alpha );
		bli_setsc(  (1.0/1.0), 0.0, &beta );


		bli_copym( &c, &c_save );
	
		dtime_save = 1.0e9;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &c_save, &c );

			dtime = bli_clock();


#ifdef PRINT
/*
			obj_t ar, ai;
			bli_obj_alias_to( &a, &ar );
			bli_obj_alias_to( &a, &ai );
			bli_obj_set_dt( BLIS_DOUBLE, &ar ); ar.rs *= 2; ar.cs *= 2;
			bli_obj_set_dt( BLIS_DOUBLE, &ai ); ai.rs *= 2; ai.cs *= 2; ai.buffer = ( double* )ai.buffer + 1;

			bli_printm( "ar", &ar, "%4.1f", "" );
			bli_printm( "ai", &ai, "%4.1f", "" );
*/

			bli_invertd( &a );
			bli_printm( "a", &a, "%4.1f", "" );
			bli_invertd( &a );
			bli_printm( "c", &c, "%4.1f", "" );
#endif

#ifdef BLIS
			//bli_error_checking_level_set( BLIS_NO_ERROR_CHECKING );

			bli_trsm( side,
			//bli_trsm4m( side,
			//bli_trsm3m( side,
			          &alpha,
			          &a,
			          &c );
#else

		if ( bli_is_real( dt_a ) )
		{
			f77_char side   = 'L';
			f77_char uplo   = 'L';
			f77_char transa = 'N';
			f77_char diag   = 'N';
			f77_int  mm     = bli_obj_length( &c );
			f77_int  nn     = bli_obj_width( &c );
			f77_int  lda    = bli_obj_col_stride( &a );
			f77_int  ldc    = bli_obj_col_stride( &c );
			float *  alphap = bli_obj_buffer( &alpha );
			float *  ap     = bli_obj_buffer( &a );
			float *  cp     = bli_obj_buffer( &c );

			strsm_( &side,
			        &uplo,
			        &transa,
			        &diag,
			        &mm,
			        &nn,
			        alphap,
			        ap, &lda,
			        cp, &ldc );
		}
		else // if ( bli_is_complex( dt_a ) )
		{
			f77_char  side   = 'L';
			f77_char  uplo   = 'L';
			f77_char  transa = 'N';
			f77_char  diag   = 'N';
			f77_int   mm     = bli_obj_length( &c );
			f77_int   nn     = bli_obj_width( &c );
			f77_int   lda    = bli_obj_col_stride( &a );
			f77_int   ldc    = bli_obj_col_stride( &c );
			scomplex* alphap = bli_obj_buffer( &alpha );
			scomplex* ap     = bli_obj_buffer( &a );
			scomplex* cp     = bli_obj_buffer( &c );

			ctrsm_( &side,
			//ztrsm_( &side,
			        &uplo,
			        &transa,
			        &diag,
			        &mm,
			        &nn,
			        alphap,
			        ap, &lda,
			        cp, &ldc );
		}
		
#endif

#ifdef PRINT
			bli_printm( "c after", &c, "%4.1f", "" );
			exit(1);
#endif


			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}

		if ( bli_is_left( side ) )
			gflops = ( 1.0 * m * m * n ) / ( dtime_save * 1.0e9 );
		else
			gflops = ( 1.0 * m * n * n ) / ( dtime_save * 1.0e9 );

		if ( bli_is_complex( dt_a ) ) gflops *= 4.0;

#ifdef BLIS
		printf( "data_trsm_blis" );
#else
		printf( "data_trsm_%s", BLAS );
#endif
		printf( "( %2lu, 1:4 ) = [ %4lu %4lu  %10.3e  %6.3f ];\n",
		        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
		        ( unsigned long )m,
		        ( unsigned long )n, dtime_save, gflops );


		bli_obj_free( &alpha );
		bli_obj_free( &beta );

		bli_obj_free( &a );
		bli_obj_free( &b );
		bli_obj_free( &c );
		bli_obj_free( &c_save );
	}

	bli_finalize();

	return 0;
}
Beispiel #4
0
int main( int argc, char** argv )
{
	bli_init();

#if 0
	obj_t a, b, c;
	obj_t aa, bb, cc;
	dim_t m, n, k;
	num_t dt;
	uplo_t uploa, uplob, uploc;

	{
		dt = BLIS_DOUBLE;

		m = 6;
		k = 6;
		n = 6;

		bli_obj_create( dt, m, k, 0, 0, &a );
		bli_obj_create( dt, k, n, 0, 0, &b );
		bli_obj_create( dt, m, n, 0, 0, &c );

		uploa = BLIS_UPPER;
		uploa = BLIS_LOWER;
		bli_obj_set_struc( BLIS_TRIANGULAR, a );
		bli_obj_set_uplo( uploa, a );
		bli_obj_set_diag_offset( -2, a );

		uplob = BLIS_UPPER;
		uplob = BLIS_LOWER;
		bli_obj_set_struc( BLIS_TRIANGULAR, b );
		bli_obj_set_uplo( uplob, b );
		bli_obj_set_diag_offset( -2, b );

		uploc = BLIS_UPPER;
		//uploc = BLIS_LOWER;
		//uploc = BLIS_ZEROS;
		//uploc = BLIS_DENSE;
		bli_obj_set_struc( BLIS_HERMITIAN, c );
		//bli_obj_set_struc( BLIS_TRIANGULAR, c );
		bli_obj_set_uplo( uploc, c );
		bli_obj_set_diag_offset(  1, c );

		bli_obj_alias_to( a, aa ); (void)aa;
		bli_obj_alias_to( b, bb ); (void)bb;
		bli_obj_alias_to( c, cc ); (void)cc;

		bli_randm( &a );
		bli_randm( &b );
		bli_randm( &c );
		//bli_mkherm( &a );
		//bli_mktrim( &a );

		bli_prune_unref_mparts( &cc, BLIS_M,
		                        &aa, BLIS_N );

		bli_printm( "c orig", &c, "%4.1f", "" );
		bli_printm( "c alias", &cc, "%4.1f", "" );
		bli_printm( "a orig", &a, "%4.1f", "" );
		bli_printm( "a alias", &aa, "%4.1f", "" );
		//bli_obj_print( "a struct", &a );
	}
#endif

	dim_t  p_begin, p_max, p_inc;
	gint_t m_input, n_input;
	char   uploa_ch;
	doff_t diagoffa;
	dim_t  bf;
	dim_t  n_way;
	char   part_dim_ch;
	bool_t go_fwd;
	char   out_ch;

	obj_t  a;

	thrinfo_t thrinfo;
	dim_t  m, n;
	uplo_t uploa;
	bool_t part_m_dim, part_n_dim;
	bool_t go_bwd;
	dim_t  p;
	num_t  dt;
	dim_t  start, end;

	dim_t  width;
	siz_t  area;

	gint_t t_begin, t_stop, t_inc;
	dim_t  t;

	if ( argc == 13 )
	{
		sscanf( argv[1], "%lu", &p_begin );
		sscanf( argv[2], "%lu", &p_max );
		sscanf( argv[3], "%lu", &p_inc );
		sscanf( argv[4], "%ld", &m_input );
		sscanf( argv[5], "%ld", &n_input );
		sscanf( argv[6], "%c",  &uploa_ch );
		sscanf( argv[7], "%ld", &diagoffa );
		sscanf( argv[8], "%lu", &bf );
		sscanf( argv[9], "%lu", &n_way );
		sscanf( argv[10], "%c", &part_dim_ch );
		sscanf( argv[11], "%lu", &go_fwd );
		sscanf( argv[12], "%c", &out_ch );
	}
	else
	{
		printf( "\n" );
		printf( " %s\n", argv[0] );
		printf( "\n" );
		printf( "  Simulate the dimension ranges assigned to threads when\n" );
		printf( "  partitioning a matrix for parallelism in BLIS.\n" );
		printf( "\n" );
		printf( " Usage:\n" );
		printf( "\n" );
		printf( "  %s p_beg p_max p_inc m n uplo doff bf n_way part_dim go_fwd out\n", argv[0] );
		printf( "\n" );
		printf( "  p_beg:    the first problem size p to test.\n" );
		printf( "  p_max:    the maximum problem size p to test.\n" );
		printf( "  p_inc:    the increase in problem size p between tests.\n" );
		printf( "  m:        the m dimension:\n" );
		printf( "  n:        the n dimension:\n" );
		printf( "            if m,n = -1: bind m,n to problem size p.\n" );
		printf( "            if m,n =  0: bind m,n to p_max.\n" );
		printf( "            if m,n >  0: hold m,n = c constant for all p.\n" );
		printf( "  uplo:     the uplo field of the matrix being partitioned:\n" );
		printf( "            'l': lower-stored (BLIS_LOWER)\n" );
		printf( "            'u': upper-stored (BLIS_UPPER)\n" );
		printf( "            'd': densely-stored (BLIS_DENSE)\n" );
		printf( "  doff:     the diagonal offset of the matrix being partitioned.\n" );
		printf( "  bf:       the simulated blocking factor. all thread ranges must\n" );
		printf( "            be a multiple of bf, except for the range that contains\n" );
		printf( "            the edge case (if one exists). the blocking factor\n" );
		printf( "            would typically correspond to a register blocksize.\n" );
		printf( "  n_way:    the number of ways of parallelism for which we are\n" );
		printf( "            partitioning (i.e.: the number of threads, or thread\n" );
		printf( "            groups).\n" );
		printf( "  part_dim: the dimension to partition:\n" );
		printf( "            'm': partition the m dimension.\n" );
		printf( "            'n': partition the n dimension.\n" );
		printf( "  go_fwd:   the direction to partition:\n" );
		printf( "            '1': forward, e.g. left-to-right (part_dim = 'm') or\n" );
		printf( "                 top-to-bottom (part_dim = 'n')\n" );
		printf( "            '0': backward, e.g. right-to-left (part_dim = 'm') or\n" );
		printf( "                 bottom-to-top (part_dim = 'n')\n" );
		printf( "            NOTE: reversing the direction does not change the\n" );
		printf( "            subpartitions' widths, but it does change which end of\n" );
		printf( "            the index range receives the edge case, if it exists.\n" );
		printf( "  out:      the type of output per thread-column:\n" );
		printf( "            'w': the width (and area) of the thread's subpartition\n" );
		printf( "            'r': the actual ranges of the thread's subpartition\n" );
		printf( "                 where the start and end points of each range are\n" );
		printf( "                 inclusive and exclusive, respectively.\n" );
		printf( "\n" );

		exit(1);
	}

	if ( m_input == 0 ) m_input = p_max;
	if ( n_input == 0 ) n_input = p_max;

	if ( part_dim_ch == 'm' ) { part_m_dim = TRUE;  part_n_dim = FALSE; }
	else                      { part_m_dim = FALSE; part_n_dim = TRUE;  }

	go_bwd = !go_fwd;

	if      ( uploa_ch == 'l' ) uploa = BLIS_LOWER;
	else if ( uploa_ch == 'u' ) uploa = BLIS_UPPER;
	else                        uploa = BLIS_DENSE;

	if ( part_n_dim )
	{
		if ( bli_is_upper( uploa ) ) { t_begin = n_way-1; t_stop = -1;    t_inc = -1; }
		else /* if lower or dense */ { t_begin = 0;       t_stop = n_way; t_inc =  1; }
	}
	else // if ( part_m_dim )
	{
		if ( bli_is_lower( uploa ) ) { t_begin = n_way-1; t_stop = -1;    t_inc = -1; }
		else /* if upper or dense */ { t_begin = 0;       t_stop = n_way; t_inc =  1; }
	}

	printf( "\n" );
	printf( "  part: %3s   doff: %3ld   bf: %3ld   output: %s\n",
	        ( part_n_dim ? ( go_fwd ? "l2r" : "r2l" )
	                     : ( go_fwd ? "t2b" : "b2t" ) ),
	        diagoffa, bf,
            ( out_ch == 'w' ? "width(area)" : "ranges" ) );
	printf( "              uplo: %3c   nt: %3ld\n", uploa_ch, n_way );
	printf( "\n" );

	printf( "             " );
	for ( t = t_begin; t != t_stop; t += t_inc )
	{
		if ( part_n_dim )
		{
			if      ( t == t_begin      ) printf( "left...      " );
			else if ( t == t_stop-t_inc ) printf( "     ...right" );
			else                          printf( "             " );
		}
		else // if ( part_m_dim )
		{
			if      ( t == t_begin      ) printf( "top...       " );
			else if ( t == t_stop-t_inc ) printf( "    ...bottom" );
			else                          printf( "             " );
		}
	}
	printf( "\n" );


	printf( "%4c x %4c  ", 'm', 'n' );
	for ( t = t_begin; t != t_stop; t += t_inc )
	{
		printf( "%9s %lu  ", "thread", t );
	}
	printf( "\n" );
	printf( "-------------" );
	for ( t = t_begin; t != t_stop; t += t_inc )
	{
		printf( "-------------" );
	}
	printf( "\n" );


	for ( p = p_begin; p <= p_max; p += p_inc )
	{
		if ( m_input < 0 ) m = ( dim_t )p;
		else               m = ( dim_t )m_input;
		if ( n_input < 0 ) n = ( dim_t )p;
		else               n = ( dim_t )n_input;

		dt = BLIS_DOUBLE;
		
		bli_obj_create( dt, m, n, 0, 0, &a );

		bli_obj_set_struc( BLIS_TRIANGULAR, a );
		bli_obj_set_uplo( uploa, a );
		bli_obj_set_diag_offset( diagoffa, a );

		bli_randm( &a );

		printf( "%4lu x %4lu  ", m, n );

		for ( t = t_begin; t != t_stop; t += t_inc )
		{
			thrinfo.n_way   = n_way;
			thrinfo.work_id = t;

			if      ( part_n_dim && go_fwd )
				area = bli_get_range_weighted_l2r( &thrinfo, &a, bf, &start, &end );
			else if ( part_n_dim && go_bwd )
				area = bli_get_range_weighted_r2l( &thrinfo, &a, bf, &start, &end );
			else if ( part_m_dim && go_fwd )
				area = bli_get_range_weighted_t2b( &thrinfo, &a, bf, &start, &end );
			else // ( part_m_dim && go_bwd )
				area = bli_get_range_weighted_b2t( &thrinfo, &a, bf, &start, &end );

			width = end - start;

			if ( out_ch == 'w' ) printf( "%4lu(%6lu) ", width, area );
			else                 printf( "[%4lu,%4lu)  ", start, end );
		}

		printf( "\n" );

		bli_obj_free( &a );
	}

	bli_finalize();

	return 0;
}
Beispiel #5
0
int main( int argc, char** argv )
{
	obj_t a, b, c;
	obj_t c_save;
	obj_t alpha, beta;
	dim_t m, n, k;
	dim_t p;
	dim_t p_begin, p_end, p_inc;
	int   m_input, n_input, k_input;
	num_t dt_a, dt_b, dt_c;
	num_t dt_alpha, dt_beta;
	int   r, n_repeats;

	double dtime;
	double dtime_save;
	double gflops;

    
    int world_size, world_rank, provided;
    MPI_Init_thread( NULL, NULL, MPI_THREAD_FUNNELED, &provided );
    MPI_Comm_size( MPI_COMM_WORLD, &world_size );
    MPI_Comm_rank( MPI_COMM_WORLD, &world_rank );

	bli_init();

	n_repeats = 3;

#ifndef PRINT
	p_begin = 16;
	p_end   = 2048;
	p_inc   = 16;

	m_input = 10240;
	n_input = 10240;
	k_input = -1;
#else
	p_begin = 24;
	p_end   = 24;
	p_inc   = 1;

	m_input = -1;
	k_input = -1;
	n_input = -1;
#endif

	dt_a = BLIS_DOUBLE;
	dt_b = BLIS_DOUBLE;
	dt_c = BLIS_DOUBLE;
	dt_alpha = BLIS_DOUBLE;
	dt_beta = BLIS_DOUBLE;

	for ( p = p_begin + world_rank * p_inc ; p <= p_end; p += p_inc * world_size )
	{

		if ( m_input < 0 ) m = p * ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( n_input < 0 ) n = p * ( dim_t )abs(n_input);
		else               n =     ( dim_t )    n_input;
		if ( k_input < 0 ) k = p * ( dim_t )abs(k_input);
		else               k =     ( dim_t )    k_input;


		bli_obj_create( dt_alpha, 1, 1, 0, 0, &alpha );
		bli_obj_create( dt_beta,  1, 1, 0, 0, &beta );

		bli_obj_create( dt_a, m, k, 0, 0, &a );
		bli_obj_create( dt_b, k, n, 0, 0, &b );
		bli_obj_create( dt_c, m, n, 0, 0, &c );
		bli_obj_create( dt_c, m, n, 0, 0, &c_save );

		bli_randm( &a );
		bli_randm( &b );
		bli_randm( &c );


		bli_setsc(  (1.0/1.0), 0.0, &alpha );
		bli_setsc(  (1.0/1.0), 0.0, &beta );

		bli_copym( &c, &c_save );
	
		dtime_save = 1.0e9;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &c_save, &c );


			dtime = bli_clock();


#ifdef PRINT
			bli_printm( "a", &a, "%4.1f", "" );
			bli_printm( "b", &b, "%4.1f", "" );
			bli_printm( "c", &c, "%4.1f", "" );
#endif

#ifdef BLIS
			//bli_error_checking_level_set( BLIS_NO_ERROR_CHECKING );
            {
                bli_gemm( &alpha,
                          &a,
                          &b,
                          &beta,
                          &c );
            }

#else
			char    transa = 'N';
			char    transb = 'N';
			int     mm     = bli_obj_length( c );
			int     kk     = bli_obj_width_after_trans( a );
			int     nn     = bli_obj_width( c );
			int     lda    = bli_obj_col_stride( a );
			int     ldb    = bli_obj_col_stride( b );
			int     ldc    = bli_obj_col_stride( c );
			double* alphap = bli_obj_buffer( alpha );
			double* ap     = bli_obj_buffer( a );
			double* bp     = bli_obj_buffer( b );
			double* betap  = bli_obj_buffer( beta );
			double* cp     = bli_obj_buffer( c );

			dgemm_( &transa,
			        &transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
            
#endif

#ifdef PRINT
			bli_printm( "c after", &c, "%4.1f", "" );
			exit(1);
#endif


			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}
		
        gflops = ( 2.0 * m * k * n ) / ( dtime_save * 1.0e9 );

        //if(world_rank == 0){
#ifdef BLIS
            printf( "data_gemm_blis" );
#else
            printf( "data_gemm_%s", BLAS );
#endif
            printf( "( %2ld, 1:5 ) = [ %4lu %4lu %4lu  %10.3e  %6.3f %d ];\n",
                    (p - p_begin + 1)/p_inc + 1, m, k, n, dtime_save, gflops, world_rank );
        //}
    
        bli_obj_free( &alpha );
        bli_obj_free( &beta );

        bli_obj_free( &a );
        bli_obj_free( &b );
        bli_obj_free( &c );
        bli_obj_free( &c_save );
	}

	bli_finalize();

    MPI_Finalize();

	return 0;
}
Beispiel #6
0
int main( int argc, char** argv )
{
	obj_t a, b, c;
	obj_t c_save;
	obj_t alpha, beta;
	dim_t m, n;
	dim_t p;
	dim_t p_begin, p_end, p_inc;
	int   m_input, n_input;
	num_t dt;
	int   r, n_repeats;
	side_t side;
	uplo_t uploa;
	f77_char f77_side;
	f77_char f77_uploa;

	double dtime;
	double dtime_save;
	double gflops;

	bli_init();

	//bli_error_checking_level_set( BLIS_NO_ERROR_CHECKING );

	n_repeats = 3;

#ifndef PRINT
	p_begin = 200;
	p_end   = 2000;
	p_inc   = 200;

	m_input = -1;
	n_input = -1;
#else
	p_begin = 16;
	p_end   = 16;
	p_inc   = 1;

	m_input = 4;
	n_input = 4;
#endif

#if 1
	//dt = BLIS_FLOAT;
	dt = BLIS_DOUBLE;
#else
	//dt = BLIS_SCOMPLEX;
	dt = BLIS_DCOMPLEX;
#endif

	side = BLIS_LEFT;
	//side = BLIS_RIGHT;

	uploa = BLIS_LOWER;
	//uploa = BLIS_UPPER;

	bli_param_map_blis_to_netlib_side( side, &f77_side );
	bli_param_map_blis_to_netlib_uplo( uploa, &f77_uploa );


	for ( p = p_begin; p <= p_end; p += p_inc )
	{
		if ( m_input < 0 ) m = p * ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( n_input < 0 ) n = p * ( dim_t )abs(n_input);
		else               n =     ( dim_t )    n_input;

		bli_obj_create( dt, 1, 1, 0, 0, &alpha );
		bli_obj_create( dt, 1, 1, 0, 0, &beta );

		if ( bli_is_left( side ) )
			bli_obj_create( dt, m, m, 0, 0, &a );
		else
			bli_obj_create( dt, n, n, 0, 0, &a );
		bli_obj_create( dt, m, n, 0, 0, &b );
		bli_obj_create( dt, m, n, 0, 0, &c );
		bli_obj_create( dt, m, n, 0, 0, &c_save );

		bli_randm( &a );
		bli_randm( &b );
		bli_randm( &c );

		bli_obj_set_struc( BLIS_HERMITIAN, a );
		bli_obj_set_uplo( uploa, a );

		// Randomize A, make it densely Hermitian, and zero the unstored
		// triangle to ensure the implementation reads only from the stored
		// region.
		bli_randm( &a );
		bli_mkherm( &a );
		bli_mktrim( &a );
/*
		bli_obj_toggle_uplo( a );
		bli_obj_inc_diag_off( 1, a );
		bli_setm( &BLIS_ZERO, &a );
		bli_obj_inc_diag_off( -1, a );
		bli_obj_toggle_uplo( a );
		bli_obj_set_diag( BLIS_NONUNIT_DIAG, a );
		bli_scalm( &BLIS_TWO, &a );
		bli_scalm( &BLIS_TWO, &a );
*/

		bli_setsc(  (2.0/1.0), 1.0, &alpha );
		bli_setsc( -(1.0/1.0), 0.0, &beta );


		bli_copym( &c, &c_save );
	
		dtime_save = 1.0e9;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &c_save, &c );


			dtime = bli_clock();

#ifdef PRINT
			bli_printm( "a", &a, "%4.1f", "" );
			bli_printm( "b", &b, "%4.1f", "" );
			bli_printm( "c", &c, "%4.1f", "" );
#endif

#ifdef BLIS

			bli_hemm( side,
			          &alpha,
			          &a,
			          &b,
			          &beta,
			          &c );
#else

		if ( bli_is_float( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			float*   alphap = bli_obj_buffer( alpha );
			float*   ap     = bli_obj_buffer( a );
			float*   bp     = bli_obj_buffer( b );
			float*   betap  = bli_obj_buffer( beta );
			float*   cp     = bli_obj_buffer( c );

			ssymm_( &f77_side,
			        &f77_uploa,
			        &mm,
			        &nn,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_double( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			double*  alphap = bli_obj_buffer( alpha );
			double*  ap     = bli_obj_buffer( a );
			double*  bp     = bli_obj_buffer( b );
			double*  betap  = bli_obj_buffer( beta );
			double*  cp     = bli_obj_buffer( c );

			dsymm_( &f77_side,
			        &f77_uploa,
			        &mm,
			        &nn,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_scomplex( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			scomplex*  alphap = bli_obj_buffer( alpha );
			scomplex*  ap     = bli_obj_buffer( a );
			scomplex*  bp     = bli_obj_buffer( b );
			scomplex*  betap  = bli_obj_buffer( beta );
			scomplex*  cp     = bli_obj_buffer( c );

			chemm_( &f77_side,
			        &f77_uploa,
			        &mm,
			        &nn,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_dcomplex( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			dcomplex*  alphap = bli_obj_buffer( alpha );
			dcomplex*  ap     = bli_obj_buffer( a );
			dcomplex*  bp     = bli_obj_buffer( b );
			dcomplex*  betap  = bli_obj_buffer( beta );
			dcomplex*  cp     = bli_obj_buffer( c );

			zhemm_( &f77_side,
			        &f77_uploa,
			        &mm,
			        &nn,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
#endif

#ifdef PRINT
			bli_printm( "c after", &c, "%9.5f", "" );
			exit(1);
#endif

			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}

		if ( bli_is_left( side ) )
			gflops = ( 2.0 * m * m * n ) / ( dtime_save * 1.0e9 );
		else
			gflops = ( 2.0 * m * n * n ) / ( dtime_save * 1.0e9 );

		if ( bli_is_complex( dt ) ) gflops *= 4.0;

#ifdef BLIS
		printf( "data_hemm_blis" );
#else
		printf( "data_hemm_%s", BLAS );
#endif
		printf( "( %2lu, 1:4 ) = [ %4lu %4lu  %10.3e  %6.3f ];\n",
		        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
		        ( unsigned long )m,
		        ( unsigned long )n, dtime_save, gflops );

		bli_obj_free( &alpha );
		bli_obj_free( &beta );

		bli_obj_free( &a );
		bli_obj_free( &b );
		bli_obj_free( &c );
		bli_obj_free( &c_save );
	}

	bli_finalize();

	return 0;
}
Beispiel #7
0
int main( int argc, char** argv )
{
	obj_t a, x, y;
	obj_t a_save;
	obj_t alpha;
	dim_t m, n;
	dim_t p;
	dim_t p_begin, p_end, p_inc;
	int   m_input, n_input;
	num_t dt_a, dt_x, dt_y;
	num_t dt_alpha;
	int   r, n_repeats;

	double dtime;
	double dtime_save;
	double gflops;

	bli_init();

	n_repeats = 3;

#ifndef PRINT
	p_begin = 40;
	p_end   = 2000;
	p_inc   = 40;

	m_input = -1;
	n_input = -1;
#else
	p_begin = 16;
	p_end   = 16;
	p_inc   = 1;

	m_input = 15;
	n_input = 15;
#endif

	dt_alpha = dt_x = dt_y = dt_a = BLIS_DOUBLE;

	for ( p = p_begin; p <= p_end; p += p_inc )
	{

		if ( m_input < 0 ) m = p * ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( n_input < 0 ) n = p * ( dim_t )abs(n_input);
		else               n =     ( dim_t )    n_input;


		bli_obj_create( dt_alpha, 1, 1, 0, 0, &alpha );

		bli_obj_create( dt_x, m, 1, 0, 0, &x );
		bli_obj_create( dt_y, n, 1, 0, 0, &y );
		bli_obj_create( dt_a, m, n, 0, 0, &a );
		bli_obj_create( dt_a, m, n, 0, 0, &a_save );

		bli_randm( &x );
		bli_randm( &y );
		bli_randm( &a );


		bli_setsc(  (2.0/1.0), 0.0, &alpha );


		bli_copym( &a, &a_save );
	
		dtime_save = DBL_MAX;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &a_save, &a );


			dtime = bli_clock();

#ifdef PRINT
			bli_printm( "x", &x, "%4.1f", "" );
			bli_printm( "y", &y, "%4.1f", "" );
			bli_printm( "a", &a, "%4.1f", "" );
#endif

#ifdef BLIS

			bli_ger( &alpha,
			         &x,
			         &y,
			         &a );
#else

			f77_int  mm     = bli_obj_length( a );
			f77_int  nn     = bli_obj_width( a );
			f77_int  incx   = bli_obj_vector_inc( x );
			f77_int  incy   = bli_obj_vector_inc( y );
			f77_int  lda    = bli_obj_col_stride( a );
			double*  alphap = bli_obj_buffer( alpha );
			double*  xp     = bli_obj_buffer( x );
			double*  yp     = bli_obj_buffer( y );
			double*  ap     = bli_obj_buffer( a );

			dger_( &mm,
			       &nn,
			       alphap,
			       xp, &incx,
			       yp, &incy,
			       ap, &lda );
#endif

#ifdef PRINT
			bli_printm( "a after", &a, "%4.1f", "" );
			exit(1);
#endif


			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}

		gflops = ( 2.0 * m * n ) / ( dtime_save * 1.0e9 );

#ifdef BLIS
		printf( "data_ger_blis" );
#else
		printf( "data_ger_%s", BLAS );
#endif
		printf( "( %2lu, 1:4 ) = [ %4lu %4lu  %10.3e  %6.3f ];\n",
		        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
		        ( unsigned long )m,
		        ( unsigned long )n, dtime_save, gflops );

		bli_obj_free( &alpha );

		bli_obj_free( &x );
		bli_obj_free( &y );
		bli_obj_free( &a );
		bli_obj_free( &a_save );
	}

	bli_finalize();

	return 0;
}
Beispiel #8
0
int main( int argc, char** argv )
{
	obj_t    a, b, c;
	obj_t    c_save;
	obj_t    alpha, beta;
	dim_t    m, n, k;
	dim_t    p;
	dim_t    p_begin, p_end, p_inc;
	int      m_input, n_input, k_input;
	num_t    dt, dt_real;
	char     dt_ch;
	int      r, n_repeats;
	trans_t  transa;
	trans_t  transb;
	f77_char f77_transa;
	f77_char f77_transb;

	double   dtime;
	double   dtime_save;
	double   gflops;

	extern blksz_t* gemm_kc;

	bli_init();

	//bli_error_checking_level_set( BLIS_NO_ERROR_CHECKING );

	n_repeats = 3;

	dt      = DT;
	dt_real = bli_datatype_proj_to_real( DT );

	p_begin = P_BEGIN;
	p_end   = P_END;
	p_inc   = P_INC;

	m_input = -1;
	n_input = -1;
	k_input = -1;

	// Extract the kc blocksize for the requested datatype and its
	// real analogue.
	dim_t kc      = bli_blksz_get_def( dt,      gemm_kc );
	dim_t kc_real = bli_blksz_get_def( dt_real, gemm_kc );

	// Assign the k dimension depending on which implementation is
	// being tested. Note that the BLIS_NAT case handles the real
	// domain cases as well as native complex.
	if      ( IND == BLIS_NAT  ) k_input = kc;
	else if ( IND == BLIS_3M1  ) k_input = kc_real / 3;
	else if ( IND == BLIS_4M1A ) k_input = kc_real / 2;
	else                         k_input = kc_real;

	// Adjust the relative dimensions, if requested.
#if   (defined ADJ_MK)
	m_input = -2; k_input = -2; n_input = -1;
#elif (defined ADJ_KN)
	k_input = -2; n_input = -2; m_input = -1;
#elif (defined ADJ_MN)
	m_input = -2; n_input = -2; k_input = -1;
#endif

	// Choose the char corresponding to the requested datatype.
	if      ( bli_is_float( dt ) )    dt_ch = 's';
	else if ( bli_is_double( dt ) )   dt_ch = 'd';
	else if ( bli_is_scomplex( dt ) ) dt_ch = 'c';
	else                              dt_ch = 'z';

	transa = BLIS_NO_TRANSPOSE;
	transb = BLIS_NO_TRANSPOSE;

	bli_param_map_blis_to_netlib_trans( transa, &f77_transa );
	bli_param_map_blis_to_netlib_trans( transb, &f77_transb );

	// Begin with initializing the last entry to zero so that
	// matlab allocates space for the entire array once up-front.
	for ( p = p_begin; p + p_inc <= p_end; p += p_inc ) ;
#ifdef BLIS
	printf( "data_%s_%cgemm_%s_blis", THR_STR, dt_ch, STR );
#else
	printf( "data_%s_%cgemm_%s",      THR_STR, dt_ch, STR );
#endif
	printf( "( %2lu, 1:5 ) = [ %4lu %4lu %4lu  %10.3e  %6.3f ];\n",
	        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
	        ( unsigned long )0,
	        ( unsigned long )0,
	        ( unsigned long )0, 0.0, 0.0 );


	for ( p = p_begin; p <= p_end; p += p_inc )
	{
		if ( m_input < 0 ) m = p / ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( n_input < 0 ) n = p / ( dim_t )abs(n_input);
		else               n =     ( dim_t )    n_input;
		if ( k_input < 0 ) k = p / ( dim_t )abs(k_input);
		else               k =     ( dim_t )    k_input;

		bli_obj_create( dt, 1, 1, 0, 0, &alpha );
		bli_obj_create( dt, 1, 1, 0, 0, &beta );

		bli_obj_create( dt, m, k, 0, 0, &a );
		bli_obj_create( dt, k, n, 0, 0, &b );
		bli_obj_create( dt, m, n, 0, 0, &c );
		//bli_obj_create( dt, m, k, 2, 2*m, &a );
		//bli_obj_create( dt, k, n, 2, 2*k, &b );
		//bli_obj_create( dt, m, n, 2, 2*m, &c );
		bli_obj_create( dt, m, n, 0, 0, &c_save );

		bli_randm( &a );
		bli_randm( &b );
		bli_randm( &c );

		bli_obj_set_conjtrans( transa, a );
		bli_obj_set_conjtrans( transb, b );

		bli_setsc(  (2.0/1.0), 0.0, &alpha );
		bli_setsc( -(1.0/1.0), 0.0, &beta );


		bli_copym( &c, &c_save );
	
#ifdef BLIS
		bli_ind_disable_all_dt( dt );
		bli_ind_enable_dt( IND, dt );
#endif

		dtime_save = 1.0e9;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &c_save, &c );


			dtime = bli_clock();


#ifdef PRINT
			bli_printm( "a", &a, "%4.1f", "" );
			bli_printm( "b", &b, "%4.1f", "" );
			bli_printm( "c", &c, "%4.1f", "" );
#endif

#ifdef BLIS

			bli_gemm( &alpha,
			          &a,
			          &b,
			          &beta,
			          &c );

#else

		if ( bli_is_float( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			float*   alphap = bli_obj_buffer( alpha );
			float*   ap     = bli_obj_buffer( a );
			float*   bp     = bli_obj_buffer( b );
			float*   betap  = bli_obj_buffer( beta );
			float*   cp     = bli_obj_buffer( c );

			sgemm_( &f77_transa,
			        &f77_transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_double( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			double*  alphap = bli_obj_buffer( alpha );
			double*  ap     = bli_obj_buffer( a );
			double*  bp     = bli_obj_buffer( b );
			double*  betap  = bli_obj_buffer( beta );
			double*  cp     = bli_obj_buffer( c );

			dgemm_( &f77_transa,
			        &f77_transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_scomplex( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			scomplex*  alphap = bli_obj_buffer( alpha );
			scomplex*  ap     = bli_obj_buffer( a );
			scomplex*  bp     = bli_obj_buffer( b );
			scomplex*  betap  = bli_obj_buffer( beta );
			scomplex*  cp     = bli_obj_buffer( c );

			cgemm_( &f77_transa,
			        &f77_transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_dcomplex( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			dcomplex*  alphap = bli_obj_buffer( alpha );
			dcomplex*  ap     = bli_obj_buffer( a );
			dcomplex*  bp     = bli_obj_buffer( b );
			dcomplex*  betap  = bli_obj_buffer( beta );
			dcomplex*  cp     = bli_obj_buffer( c );

			zgemm_( &f77_transa,
			//zgemm3m_( &f77_transa,
			        &f77_transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
#endif

#ifdef PRINT
			bli_printm( "c after", &c, "%4.1f", "" );
			exit(1);
#endif


			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}

		gflops = ( 2.0 * m * k * n ) / ( dtime_save * 1.0e9 );

		if ( bli_is_complex( dt ) ) gflops *= 4.0;

#ifdef BLIS
		printf( "data_%s_%cgemm_%s_blis", THR_STR, dt_ch, STR );
#else
		printf( "data_%s_%cgemm_%s",      THR_STR, dt_ch, STR );
#endif
		printf( "( %2lu, 1:5 ) = [ %4lu %4lu %4lu  %10.3e  %6.3f ];\n",
		        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
		        ( unsigned long )m,
		        ( unsigned long )k,
		        ( unsigned long )n, dtime_save, gflops );

		bli_obj_free( &alpha );
		bli_obj_free( &beta );

		bli_obj_free( &a );
		bli_obj_free( &b );
		bli_obj_free( &c );
		bli_obj_free( &c_save );
	}

	bli_finalize();

	return 0;
}
Beispiel #9
0
void bli_init_auto( err_t* init_result )
{
	*init_result = bli_init();
}
Beispiel #10
0
static struct options parse_options(int argc, char** argv) {
	struct options options = {
		.type = gemm_type_unknown,
		.k = 0,
		.m = 0,
		.n = 0,
		.iterations = 151
	};
	for (int argi = 1; argi < argc; argi += 1) {
		if ((strcmp(argv[argi], "-g") == 0) || (strcmp(argv[argi], "--gemm") == 0)) {
			if (argi + 1 == argc) {
				fprintf(stderr, "Error: expected k value\n");
				exit(EXIT_FAILURE);
			}
			if (strcmp(argv[argi + 1], "sgemm") == 0) {
				options.type = gemm_type_sgemm;
			} else if (strcmp(argv[argi + 1], "cgemm") == 0) {
				options.type = gemm_type_cgemm;
			} else {
				fprintf(stderr, "Error: invalid value %s for the gemm type: expected \"sgemm\", \"cgemm\"\n", argv[argi + 1]);
				exit(EXIT_FAILURE);
			}
			argi += 1;
		} else if (strcmp(argv[argi], "-k") == 0) {
			if (argi + 1 == argc) {
				fprintf(stderr, "Error: expected K value\n");
				exit(EXIT_FAILURE);
			}
			if (sscanf(argv[argi + 1], "%zu", &options.k) != 1) {
				fprintf(stderr, "Error: can not parse %s as an unsigned integer\n", argv[argi + 1]);
				exit(EXIT_FAILURE);
			}
			if (options.k == 0) {
				fprintf(stderr, "Error: invalid value %s for the K parameter: positive value expected\n", argv[argi + 1]);
				exit(EXIT_FAILURE);
			}
			argi += 1;
		} else if (strcmp(argv[argi], "-m") == 0) {
			if (argi + 1 == argc) {
				fprintf(stderr, "Error: expected M value\n");
				exit(EXIT_FAILURE);
			}
			if (sscanf(argv[argi + 1], "%zu", &options.m) != 1) {
				fprintf(stderr, "Error: can not parse %s as an unsigned integer\n", argv[argi + 1]);
				exit(EXIT_FAILURE);
			}
			if (options.m == 0) {
				fprintf(stderr, "Error: invalid value %s for the M parameter: positive value expected\n", argv[argi + 1]);
				exit(EXIT_FAILURE);
			}
			argi += 1;
		} else if (strcmp(argv[argi], "-n") == 0) {
			if (argi + 1 == argc) {
				fprintf(stderr, "Error: expected N value\n");
				exit(EXIT_FAILURE);
			}
			if (sscanf(argv[argi + 1], "%zu", &options.n) != 1) {
				fprintf(stderr, "Error: can not parse %s as an unsigned integer\n", argv[argi + 1]);
				exit(EXIT_FAILURE);
			}
			if (options.n == 0) {
				fprintf(stderr, "Error: invalid value %s for the N parameter: positive value expected\n", argv[argi + 1]);
				exit(EXIT_FAILURE);
			}
			argi += 1;
		} else if ((strcmp(argv[argi], "--iterations") == 0) || (strcmp(argv[argi], "-i") == 0)) {
			if (argi + 1 == argc) {
				fprintf(stderr, "Error: expected iterations value\n");
				exit(EXIT_FAILURE);
			}
			if (sscanf(argv[argi + 1], "%zu", &options.iterations) != 1) {
				fprintf(stderr, "Error: can not parse %s as an unsigned integer\n", argv[argi + 1]);
				exit(EXIT_FAILURE);
			}
			if (options.iterations == 0) {
				fprintf(stderr, "Error: invalid value %s for the number of iterations: positive value expected\n", argv[argi + 1]);
				exit(EXIT_FAILURE);
			}
			argi += 1;
		} else if ((strcmp(argv[argi], "--help") == 0) || (strcmp(argv[argi], "-h") == 0)) {
			print_options_help(argv[0]);
			exit(EXIT_SUCCESS);
		} else {
			fprintf(stderr, "Error: unknown argument '%s'\n", argv[argi]);
			print_options_help(argv[0]);
			exit(EXIT_FAILURE);
		}
	}
	if (options.type == gemm_type_unknown) {
		fprintf(stderr, "Error: gemm kernel type is not specified\n");
		print_options_help(argv[0]);
		exit(EXIT_FAILURE);
	}
	if (options.m == 0) {
		fprintf(stderr, "Error: M is not specified\n");
		print_options_help(argv[0]);
		exit(EXIT_FAILURE);
	}
	if (options.n == 0) {
		fprintf(stderr, "Error: N is not specified\n");
		print_options_help(argv[0]);
		exit(EXIT_FAILURE);
	}
	if (options.k == 0) {
		fprintf(stderr, "Error: K is not specified\n");
		print_options_help(argv[0]);
		exit(EXIT_FAILURE);
	}
	return options;
}

int main(int argc, char** argv) {
	const struct options options = parse_options(argc, argv);
	size_t components = 0;
	switch (options.type) {
		case gemm_type_sgemm:
			components = 1;
			break;
		case gemm_type_cgemm:
			components = 2;
			break;
		default:
			__builtin_unreachable();
	}

	const size_t cache_size = 128 * 1024 * 1024;
	void* memory = valloc(cache_size);

#ifdef USE_BLIS
	err_t blis_status = bli_init();
	if (blis_status != BLIS_SUCCESS) {
		fprintf(stderr, "BLIS initialization failed: error code %d\n", blis_status);
		exit(EXIT_FAILURE);
	}
#endif

	float* c = (float*) valloc(options.m * options.n * components * sizeof(float));
	float* a = (float*) valloc(options.m * options.k * components * sizeof(float));
	float* b = (float*) valloc(options.k * options.n * components * sizeof(float));

	memset(c, 0, options.m * options.n * components * sizeof(float));
	memset(a, 0, options.m * options.k * components * sizeof(float));
	memset(b, 0, options.k * options.n * components * sizeof(float));

	{
		printf("Iterations: %zu\n", options.iterations);

		const unsigned long long gemm_nanoseconds = benchmark_gemm(
			memory, cache_size,
			options.type,
			options.m, options.n, options.k,
			a, b, c,
			options.iterations);
		const double gemm_gflops = 2.0 * components * components * options.m * options.n * options.k / ((double) gemm_nanoseconds);

		printf("Time: %5.3lf ms\n", gemm_nanoseconds * 1.0e-6);
		printf("Performance: %5.3lf GFLOPs/s\n", gemm_gflops);
	}
}
Beispiel #11
0
int main( int argc, char** argv )
{
    obj_t a, b, c;
    obj_t x, y;
    obj_t alpha, beta;
    dim_t m;
    num_t dt_a, dt_b, dt_c;
    num_t dt_alpha, dt_beta;
    int   ii;

#ifdef NBLIS
    bli_init();
#endif


    m = 4000;

    dt_a = BLIS_DOUBLE;
    dt_b = BLIS_DOUBLE;
    dt_c = BLIS_DOUBLE;
    dt_alpha = BLIS_DOUBLE;
    dt_beta = BLIS_DOUBLE;

    {


#ifdef NBLIS
        bli_obj_create( dt_alpha, 1, 1, 0, 0, &alpha );
        bli_obj_create( dt_beta,  1, 1, 0, 0, &beta );

        bli_obj_create( dt_a, m, 1, 0, 0, &x );
        bli_obj_create( dt_a, m, 1, 0, 0, &y );

        bli_obj_create( dt_a, m, m, 0, 0, &a );
        bli_obj_create( dt_b, m, m, 0, 0, &b );
        bli_obj_create( dt_c, m, m, 0, 0, &c );

        bli_randm( &a );
        bli_randm( &b );
        bli_randm( &c );

        bli_setsc(  (2.0/1.0), 0.0, &alpha );
        bli_setsc( -(1.0/1.0), 0.0, &beta );

#endif

#ifdef NBLAS
        x.buffer     = malloc( m * 1 * sizeof( double ) );
        y.buffer     = malloc( m * 1 * sizeof( double ) );

        alpha.buffer = malloc( 1 * sizeof( double ) );
        beta.buffer  = malloc( 1 * sizeof( double ) );
        a.buffer     = malloc( m * m * sizeof( double ) );
        a.m          = m;
        a.n          = m;
        a.cs         = m;
        b.buffer     = malloc( m * m * sizeof( double ) );
        b.m          = m;
        b.n          = m;
        b.cs         = m;
        c.buffer     = malloc( m * m * sizeof( double ) );
        c.m          = m;
        c.n          = m;
        c.cs         = m;

        *((double*)alpha.buffer) =  2.0;
        *((double*)beta.buffer)  = -1.0;
#endif


#ifdef NBLIS

#if NBLIS >= 1
        for ( ii = 0; ii < 2000000000; ++ii )
        {
            bli_gemm( &BLIS_ONE,
                      &a,
                      &b,
                      &BLIS_ONE,
                      &c );
        }
#endif

#if NBLIS >= 2
        {
            bli_hemm( BLIS_LEFT,
                      &BLIS_ONE,
                      &a,
                      &b,
                      &BLIS_ONE,
                      &c );
        }
#endif

#if NBLIS >= 3
        {
            bli_herk( &BLIS_ONE,
                      &a,
                      &BLIS_ONE,
                      &c );
        }
#endif

#if NBLIS >= 4
        {
            bli_her2k( &BLIS_ONE,
                       &a,
                       &b,
                       &BLIS_ONE,
                       &c );
        }
#endif

#if NBLIS >= 5
        {
            bli_trmm( BLIS_LEFT,
                      &BLIS_ONE,
                      &a,
                      &c );
        }
#endif

#if NBLIS >= 6
        {
            bli_trsm( BLIS_LEFT,
                      &BLIS_ONE,
                      &a,
                      &c );
        }
#endif

#endif



#ifdef NBLAS

#if NBLAS >= 1
        for ( ii = 0; ii < 2000000000; ++ii )
        {
            f77_char transa = 'N';
            f77_char transb = 'N';
            f77_int  mm     = bli_obj_length( c );
            f77_int  kk     = bli_obj_width_after_trans( a );
            f77_int  nn     = bli_obj_width( c );
            f77_int  lda    = bli_obj_col_stride( a );
            f77_int  ldb    = bli_obj_col_stride( b );
            f77_int  ldc    = bli_obj_col_stride( c );
            double*  alphap = bli_obj_buffer( alpha );
            double*  ap     = bli_obj_buffer( a );
            double*  bp     = bli_obj_buffer( b );
            double*  betap  = bli_obj_buffer( beta );
            double*  cp     = bli_obj_buffer( c );

            dgemm_( &transa,
                    &transb,
                    &mm,
                    &nn,
                    &kk,
                    alphap,
                    ap, &lda,
                    bp, &ldb,
                    betap,
                    cp, &ldc );
        }
#endif

#if NBLAS >= 2
        {
            f77_char side   = 'L';
            f77_char uplo   = 'L';
            f77_int  mm     = bli_obj_length( c );
            f77_int  nn     = bli_obj_width( c );
            f77_int  lda    = bli_obj_col_stride( a );
            f77_int  ldb    = bli_obj_col_stride( b );
            f77_int  ldc    = bli_obj_col_stride( c );
            double*  alphap = bli_obj_buffer( alpha );
            double*  ap     = bli_obj_buffer( a );
            double*  bp     = bli_obj_buffer( b );
            double*  betap  = bli_obj_buffer( beta );
            double*  cp     = bli_obj_buffer( c );

            dsymm_( &side,
                    &uplo,
                    &mm,
                    &nn,
                    alphap,
                    ap, &lda,
                    bp, &ldb,
                    betap,
                    cp, &ldc );
        }
#endif

#if NBLAS >= 3
        {
            f77_char uplo   = 'L';
            f77_char trans  = 'N';
            f77_int  mm     = bli_obj_length( c );
            f77_int  kk     = bli_obj_width( a );
            f77_int  lda    = bli_obj_col_stride( a );
            f77_int  ldc    = bli_obj_col_stride( c );
            double*  alphap = bli_obj_buffer( alpha );
            double*  ap     = bli_obj_buffer( a );
            double*  betap  = bli_obj_buffer( beta );
            double*  cp     = bli_obj_buffer( c );

            dsyrk_( &uplo,
                    &trans,
                    &mm,
                    &kk,
                    alphap,
                    ap, &lda,
                    betap,
                    cp, &ldc );
        }
#endif

#if NBLAS >= 4
        {
            f77_char uplo   = 'L';
            f77_char trans  = 'N';
            f77_int  mm     = bli_obj_length( c );
            f77_int  kk     = bli_obj_width( a );
            f77_int  lda    = bli_obj_col_stride( a );
            f77_int  ldb    = bli_obj_col_stride( b );
            f77_int  ldc    = bli_obj_col_stride( c );
            double*  alphap = bli_obj_buffer( alpha );
            double*  ap     = bli_obj_buffer( a );
            double*  bp     = bli_obj_buffer( b );
            double*  betap  = bli_obj_buffer( beta );
            double*  cp     = bli_obj_buffer( c );

            dsyr2k_( &uplo,
                     &trans,
                     &mm,
                     &kk,
                     alphap,
                     ap, &lda,
                     bp, &ldb,
                     betap,
                     cp, &ldc );
        }
#endif

#if NBLAS >= 5
        {
            f77_char side   = 'L';
            f77_char uplo   = 'L';
            f77_char trans  = 'N';
            f77_char diag   = 'N';
            f77_int  mm     = bli_obj_length( c );
            f77_int  nn     = bli_obj_width( c );
            f77_int  lda    = bli_obj_col_stride( a );
            f77_int  ldc    = bli_obj_col_stride( c );
            double*  alphap = bli_obj_buffer( alpha );
            double*  ap     = bli_obj_buffer( a );
            double*  cp     = bli_obj_buffer( c );

            dtrmm_( &side,
                    &uplo,
                    &trans,
                    &diag,
                    &mm,
                    &nn,
                    alphap,
                    ap, &lda,
                    cp, &ldc );
        }
#endif

#if NBLAS >= 6
        {
            f77_char side   = 'L';
            f77_char uplo   = 'L';
            f77_char trans  = 'N';
            f77_char diag   = 'N';
            f77_int  mm     = bli_obj_length( c );
            f77_int  nn     = bli_obj_width( c );
            f77_int  lda    = bli_obj_col_stride( a );
            f77_int  ldc    = bli_obj_col_stride( c );
            double*  alphap = bli_obj_buffer( alpha );
            double*  ap     = bli_obj_buffer( a );
            double*  cp     = bli_obj_buffer( c );

            dtrsm_( &side,
                    &uplo,
                    &trans,
                    &diag,
                    &mm,
                    &nn,
                    alphap,
                    ap, &lda,
                    cp, &ldc );
        }
#endif

#if NBLAS >= 7
        {
            f77_char  transa = 'N';
            f77_char  transb = 'N';
            f77_int   mm     = bli_obj_length( c );
            f77_int   kk     = bli_obj_width_after_trans( a );
            f77_int   nn     = bli_obj_width( c );
            f77_int   lda    = bli_obj_col_stride( a );
            f77_int   ldb    = bli_obj_col_stride( b );
            f77_int   ldc    = bli_obj_col_stride( c );
            dcomplex* alphap = bli_obj_buffer( alpha );
            dcomplex* ap     = bli_obj_buffer( a );
            dcomplex* bp     = bli_obj_buffer( b );
            dcomplex* betap  = bli_obj_buffer( beta );
            dcomplex* cp     = bli_obj_buffer( c );

            zgemm_( &transa,
                    &transb,
                    &mm,
                    &nn,
                    &kk,
                    alphap,
                    ap, &lda,
                    bp, &ldb,
                    betap,
                    cp, &ldc );
        }
#endif

#if NBLAS >= 8
        {
            f77_char  side   = 'L';
            f77_char  uplo   = 'L';
            f77_int   mm     = bli_obj_length( c );
            f77_int   nn     = bli_obj_width( c );
            f77_int   lda    = bli_obj_col_stride( a );
            f77_int   ldb    = bli_obj_col_stride( b );
            f77_int   ldc    = bli_obj_col_stride( c );
            dcomplex* alphap = bli_obj_buffer( alpha );
            dcomplex* ap     = bli_obj_buffer( a );
            dcomplex* bp     = bli_obj_buffer( b );
            dcomplex* betap  = bli_obj_buffer( beta );
            dcomplex* cp     = bli_obj_buffer( c );

            zhemm_( &side,
                    &uplo,
                    &mm,
                    &nn,
                    alphap,
                    ap, &lda,
                    bp, &ldb,
                    betap,
                    cp, &ldc );
        }
#endif

#if NBLAS >= 9
        {
            f77_char  uplo   = 'L';
            f77_char  trans  = 'N';
            f77_int   mm     = bli_obj_length( c );
            f77_int   kk     = bli_obj_width( a );
            f77_int   lda    = bli_obj_col_stride( a );
            f77_int   ldc    = bli_obj_col_stride( c );
            double*   alphap = bli_obj_buffer( alpha );
            dcomplex* ap     = bli_obj_buffer( a );
            double*   betap  = bli_obj_buffer( beta );
            dcomplex* cp     = bli_obj_buffer( c );

            zherk_( &uplo,
                    &trans,
                    &mm,
                    &kk,
                    alphap,
                    ap, &lda,
                    betap,
                    cp, &ldc );
        }
#endif

#if NBLAS >= 10
        {
            f77_char  uplo   = 'L';
            f77_char  trans  = 'N';
            f77_int   mm     = bli_obj_length( c );
            f77_int   kk     = bli_obj_width( a );
            f77_int   lda    = bli_obj_col_stride( a );
            f77_int   ldb    = bli_obj_col_stride( b );
            f77_int   ldc    = bli_obj_col_stride( c );
            dcomplex* alphap = bli_obj_buffer( alpha );
            dcomplex* ap     = bli_obj_buffer( a );
            dcomplex* bp     = bli_obj_buffer( b );
            double*   betap  = bli_obj_buffer( beta );
            dcomplex* cp     = bli_obj_buffer( c );

            zher2k_( &uplo,
                     &trans,
                     &mm,
                     &kk,
                     alphap,
                     ap, &lda,
                     bp, &ldb,
                     betap,
                     cp, &ldc );
        }
#endif

#if NBLAS >= 11
        {
            f77_char  side   = 'L';
            f77_char  uplo   = 'L';
            f77_char  trans  = 'N';
            f77_char  diag   = 'N';
            f77_int   mm     = bli_obj_length( c );
            f77_int   nn     = bli_obj_width( c );
            f77_int   lda    = bli_obj_col_stride( a );
            f77_int   ldc    = bli_obj_col_stride( c );
            dcomplex* alphap = bli_obj_buffer( alpha );
            dcomplex* ap     = bli_obj_buffer( a );
            dcomplex* cp     = bli_obj_buffer( c );

            ztrmm_( &side,
                    &uplo,
                    &trans,
                    &diag,
                    &mm,
                    &nn,
                    alphap,
                    ap, &lda,
                    cp, &ldc );
        }
#endif

#if NBLAS >= 12
        {
            f77_char  side   = 'L';
            f77_char  uplo   = 'L';
            f77_char  trans  = 'N';
            f77_char  diag   = 'N';
            f77_int   mm     = bli_obj_length( c );
            f77_int   nn     = bli_obj_width( c );
            f77_int   lda    = bli_obj_col_stride( a );
            f77_int   ldc    = bli_obj_col_stride( c );
            dcomplex* alphap = bli_obj_buffer( alpha );
            dcomplex* ap     = bli_obj_buffer( a );
            dcomplex* cp     = bli_obj_buffer( c );

            ztrsm_( &side,
                    &uplo,
                    &trans,
                    &diag,
                    &mm,
                    &nn,
                    alphap,
                    ap, &lda,
                    cp, &ldc );
        }
#endif


#endif


#ifdef NBLIS
        bli_obj_free( &x );
        bli_obj_free( &y );

        bli_obj_free( &alpha );
        bli_obj_free( &beta );

        bli_obj_free( &a );
        bli_obj_free( &b );
        bli_obj_free( &c );
#endif

#ifdef NBLAS
        free( x.buffer );
        free( y.buffer );

        free( alpha.buffer );
        free( beta.buffer );

        free( a.buffer );
        free( b.buffer );
        free( c.buffer );
#endif
    }

#ifdef NBLIS
    bli_finalize();
#endif

    return 0;
}
Beispiel #12
0
int main( int argc, char** argv )
{
	obj_t a, c;
	obj_t c_save;
	obj_t alpha, beta;
	dim_t m, k;
	dim_t p;
	dim_t p_begin, p_end, p_inc;
	int   m_input, k_input;
	num_t dt_a, dt_c;
	num_t dt_alpha, dt_beta;
	int   r, n_repeats;
	uplo_t uplo;

	double dtime;
	double dtime_save;
	double gflops;

	bli_init();

	n_repeats = 3;

    if( argc < 7 ) 
    {   
        printf("Usage:\n");
        printf("test_foo.x m n k p_begin p_inc p_end:\n");
        exit;
    }   

    int world_size, world_rank, provided;
    MPI_Init_thread( NULL, NULL, MPI_THREAD_FUNNELED, &provided );
    MPI_Comm_size( MPI_COMM_WORLD, &world_size );
    MPI_Comm_rank( MPI_COMM_WORLD, &world_rank );

    m_input = strtol( argv[1], NULL, 10 );
    k_input = strtol( argv[3], NULL, 10 );
    p_begin = strtol( argv[4], NULL, 10 );
    p_inc   = strtol( argv[5], NULL, 10 );
    p_end   = strtol( argv[6], NULL, 10 );

	dt_a = BLIS_DOUBLE;
	dt_c = BLIS_DOUBLE;
	dt_alpha = BLIS_DOUBLE;
	dt_beta = BLIS_DOUBLE;

	uplo = BLIS_LOWER;

    for ( p = p_begin + world_rank * p_inc; p <= p_end; p += p_inc * world_size )
	{

		if ( m_input < 0 ) m = p * ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( k_input < 0 ) k = p * ( dim_t )abs(k_input);
		else               k =     ( dim_t )    k_input;


		bli_obj_create( dt_alpha, 1, 1, 0, 0, &alpha );
		bli_obj_create( dt_beta,  1, 1, 0, 0, &beta );

		bli_obj_create( dt_a, m, k, 0, 0, &a );
		bli_obj_create( dt_c, m, m, 0, 0, &c );
		bli_obj_create( dt_c, m, m, 0, 0, &c_save );

		bli_randm( &a );
		bli_randm( &c );

		bli_obj_set_struc( BLIS_HERMITIAN, &c );
		bli_obj_set_uplo( uplo, &c );


		bli_setsc(  (2.0/1.0), 0.0, &alpha );
		bli_setsc(  (1.0/1.0), 0.0, &beta );


		bli_copym( &c, &c_save );
	
		dtime_save = 1.0e9;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &c_save, &c );


			dtime = bli_clock();

#ifdef PRINT
			bli_printm( "a", &a, "%4.1f", "" );
			bli_printm( "c", &c, "%4.1f", "" );
#endif

#ifdef BLIS

			//bli_error_checking_level_set( BLIS_NO_ERROR_CHECKING );

			bli_herk( &alpha,
			          &a,
			          &beta,
			          &c );

#else

			f77_char uploa  = 'L';
			f77_char transa = 'N';
			f77_int  mm     = bli_obj_length( &c );
			f77_int  kk     = bli_obj_width_after_trans( &a );
			f77_int  lda    = bli_obj_col_stride( &a );
			f77_int  ldc    = bli_obj_col_stride( &c );
			double*  alphap = bli_obj_buffer( &alpha );
			double*  ap     = bli_obj_buffer( &a );
			double*  betap  = bli_obj_buffer( &beta );
			double*  cp     = bli_obj_buffer( &c );

			dsyrk_( &uploa,
			        &transa,
			        &mm,
			        &kk,
			        alphap,
			        ap, &lda,
			        betap,
			        cp, &ldc );
#endif

#ifdef PRINT
			bli_printm( "c after", &c, "%4.1f", "" );
			exit(1);
#endif


			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}

		gflops = ( 1.0 * m * k * m ) / ( dtime_save * 1.0e9 );

#ifdef BLIS
		printf( "data_herk_blis" );
#else
		printf( "data_herk_%s", BLAS );
#endif
		printf( "( %2lu, 1:4 ) = [ %4lu %4lu  %10.3e  %6.3f ];\n",
		        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
		        ( unsigned long )m,
		        ( unsigned long )k, dtime_save, gflops );


		bli_obj_free( &alpha );
		bli_obj_free( &beta );

		bli_obj_free( &a );
		bli_obj_free( &c );
		bli_obj_free( &c_save );
	}

	bli_finalize();

	return 0;
}
Beispiel #13
0
int main( int argc, char** argv )
{
	obj_t a, b, c;
	obj_t c_save;
	obj_t alpha, beta;
	dim_t m, n, k;
	dim_t p;
	dim_t p_begin, p_end, p_inc;
	int   m_input, n_input, k_input;
	num_t dt_a, dt_b, dt_c;
	num_t dt_alpha, dt_beta;
	int   r, n_repeats;

	double dtime;
	double dtime_save;
	double gflops;

	bli_init();

	n_repeats = 3;

#ifndef PRINT
	p_begin = 40;
	p_end   = 2000;
	p_inc   = 40;

	m_input = -1;
	n_input = -1;
	k_input = -1;
#else
	p_begin = 16;
	p_end   = 16;
	p_inc   = 1;

	m_input = 8;
	k_input = 16;
	n_input = 16;
#endif

	dt_a = BLIS_DOUBLE;
	dt_b = BLIS_DOUBLE;
	dt_c = BLIS_DOUBLE;
	dt_alpha = BLIS_DOUBLE;
	dt_beta = BLIS_DOUBLE;

	for ( p = p_begin; p <= p_end; p += p_inc )
	{

		if ( m_input < 0 ) m = p * ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( n_input < 0 ) n = p * ( dim_t )abs(n_input);
		else               n =     ( dim_t )    n_input;
		if ( k_input < 0 ) k = p * ( dim_t )abs(k_input);
		else               k =     ( dim_t )    k_input;


		bli_obj_create( dt_alpha, 1, 1, 0, 0, &alpha );
		bli_obj_create( dt_beta,  1, 1, 0, 0, &beta );

		bli_obj_create( dt_a, m, k, 0, 0, &a );
		bli_obj_create( dt_b, k, n, 0, 0, &b );
		bli_obj_create( dt_c, m, n, 0, 0, &c );
		bli_obj_create( dt_c, m, n, 0, 0, &c_save );

		bli_randm( &a );
		bli_randm( &b );
		bli_randm( &c );


		bli_setsc(  (2.0/1.0), 0.0, &alpha );
		bli_setsc( -(1.0/1.0), 0.0, &beta );


		bli_copym( &c, &c_save );
	
		dtime_save = 1.0e9;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &c_save, &c );


			dtime = bli_clock();


#ifdef PRINT
			bli_printm( "a", &a, "%4.1f", "" );
			bli_printm( "b", &b, "%4.1f", "" );
			bli_printm( "c", &c, "%4.1f", "" );
#endif

#ifdef BLIS
			//bli_error_checking_level_set( BLIS_NO_ERROR_CHECKING );

			bli_gemm( &alpha,
			          &a,
			          &b,
			          &beta,
			          &c );

#else

			f77_char transa = 'N';
			f77_char transb = 'N';
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			double*  alphap = bli_obj_buffer( alpha );
			double*  ap     = bli_obj_buffer( a );
			double*  bp     = bli_obj_buffer( b );
			double*  betap  = bli_obj_buffer( beta );
			double*  cp     = bli_obj_buffer( c );

			dgemm_( &transa,
			        &transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
#endif

#ifdef PRINT
			bli_printm( "c after", &c, "%4.1f", "" );
			exit(1);
#endif


			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}

		gflops = ( 2.0 * m * k * n ) / ( dtime_save * 1.0e9 );

#ifdef BLIS
		printf( "data_gemm_blis" );
#else
		printf( "data_gemm_%s", BLAS );
#endif
		printf( "( %2lu, 1:5 ) = [ %4lu %4lu %4lu  %10.3e  %6.3f ];\n",
		        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
		        ( unsigned long )m,
		        ( unsigned long )k,
		        ( unsigned long )n, dtime_save, gflops );

		bli_obj_free( &alpha );
		bli_obj_free( &beta );

		bli_obj_free( &a );
		bli_obj_free( &b );
		bli_obj_free( &c );
		bli_obj_free( &c_save );
	}

	bli_finalize();

	return 0;
}
Beispiel #14
0
int main( int argc, char** argv )
{
	obj_t a, b, c;
	obj_t c_save;
	obj_t alpha, beta;
	dim_t m, n, k;
	dim_t p;
	dim_t p_begin, p_end, p_inc;
	int   m_input, n_input, k_input;
	num_t dt;
	int   r, n_repeats;
	trans_t  transa;
	trans_t  transb;
	f77_char f77_transa;
	f77_char f77_transb;

	double dtime;
	double dtime_save;
	double gflops;

	bli_init();

	//bli_error_checking_level_set( BLIS_NO_ERROR_CHECKING );

	n_repeats = 3;

#ifndef PRINT
	p_begin = 200;
	p_end   = 2000;
	p_inc   = 200;

	m_input = -1;
	n_input = -1;
	k_input = -1;
#else
	p_begin = 16;
	p_end   = 16;
	p_inc   = 1;

	m_input = 5;
	k_input = 6;
	n_input = 4;
#endif

#if 1
	//dt = BLIS_FLOAT;
	dt = BLIS_DOUBLE;
#else
	//dt = BLIS_SCOMPLEX;
	dt = BLIS_DCOMPLEX;
#endif

	transa = BLIS_NO_TRANSPOSE;
	transb = BLIS_NO_TRANSPOSE;

	bli_param_map_blis_to_netlib_trans( transa, &f77_transa );
	bli_param_map_blis_to_netlib_trans( transb, &f77_transb );


	for ( p = p_begin; p <= p_end; p += p_inc )
	{
		if ( m_input < 0 ) m = p * ( dim_t )abs(m_input);
		else               m =     ( dim_t )    m_input;
		if ( n_input < 0 ) n = p * ( dim_t )abs(n_input);
		else               n =     ( dim_t )    n_input;
		if ( k_input < 0 ) k = p * ( dim_t )abs(k_input);
		else               k =     ( dim_t )    k_input;

		bli_obj_create( dt, 1, 1, 0, 0, &alpha );
		bli_obj_create( dt, 1, 1, 0, 0, &beta );

		bli_obj_create( dt, m, k, 0, 0, &a );
		bli_obj_create( dt, k, n, 0, 0, &b );
		bli_obj_create( dt, m, n, 0, 0, &c );
		bli_obj_create( dt, m, n, 0, 0, &c_save );

		bli_randm( &a );
		bli_randm( &b );
		bli_randm( &c );

		bli_obj_set_conjtrans( transa, a );
		bli_obj_set_conjtrans( transb, b );

		bli_setsc(  (0.9/1.0), 0.2, &alpha );
		bli_setsc( -(1.1/1.0), 0.3, &beta );


		bli_copym( &c, &c_save );
	
		dtime_save = DBL_MAX;

		for ( r = 0; r < n_repeats; ++r )
		{
			bli_copym( &c_save, &c );


			dtime = bli_clock();


#ifdef PRINT
			bli_printm( "a", &a, "%4.1f", "" );
			bli_printm( "b", &b, "%4.1f", "" );
			bli_printm( "c", &c, "%4.1f", "" );
#endif

#ifdef BLIS

			bli_gemm( &alpha,
			          &a,
			          &b,
			          &beta,
			          &c );

#else

		if ( bli_is_float( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			float*   alphap = bli_obj_buffer( alpha );
			float*   ap     = bli_obj_buffer( a );
			float*   bp     = bli_obj_buffer( b );
			float*   betap  = bli_obj_buffer( beta );
			float*   cp     = bli_obj_buffer( c );

			sgemm_( &f77_transa,
			        &f77_transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_double( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			double*  alphap = bli_obj_buffer( alpha );
			double*  ap     = bli_obj_buffer( a );
			double*  bp     = bli_obj_buffer( b );
			double*  betap  = bli_obj_buffer( beta );
			double*  cp     = bli_obj_buffer( c );

			dgemm_( &f77_transa,
			        &f77_transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_scomplex( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			scomplex*  alphap = bli_obj_buffer( alpha );
			scomplex*  ap     = bli_obj_buffer( a );
			scomplex*  bp     = bli_obj_buffer( b );
			scomplex*  betap  = bli_obj_buffer( beta );
			scomplex*  cp     = bli_obj_buffer( c );

			cgemm_( &f77_transa,
			        &f77_transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
		else if ( bli_is_dcomplex( dt ) )
		{
			f77_int  mm     = bli_obj_length( c );
			f77_int  kk     = bli_obj_width_after_trans( a );
			f77_int  nn     = bli_obj_width( c );
			f77_int  lda    = bli_obj_col_stride( a );
			f77_int  ldb    = bli_obj_col_stride( b );
			f77_int  ldc    = bli_obj_col_stride( c );
			dcomplex*  alphap = bli_obj_buffer( alpha );
			dcomplex*  ap     = bli_obj_buffer( a );
			dcomplex*  bp     = bli_obj_buffer( b );
			dcomplex*  betap  = bli_obj_buffer( beta );
			dcomplex*  cp     = bli_obj_buffer( c );

			zgemm_( &f77_transa,
			        &f77_transb,
			        &mm,
			        &nn,
			        &kk,
			        alphap,
			        ap, &lda,
			        bp, &ldb,
			        betap,
			        cp, &ldc );
		}
#endif

#ifdef PRINT
			bli_printm( "c after", &c, "%4.1f", "" );
			exit(1);
#endif


			dtime_save = bli_clock_min_diff( dtime_save, dtime );
		}

		gflops = ( 2.0 * m * k * n ) / ( dtime_save * 1.0e9 );

		if ( bli_is_complex( dt ) ) gflops *= 4.0;

#ifdef BLIS
		printf( "data_gemm_blis" );
#else
		printf( "data_gemm_%s", BLAS );
#endif
		printf( "( %2lu, 1:5 ) = [ %4lu %4lu %4lu  %10.3e  %6.3f ];\n",
		        ( unsigned long )(p - p_begin + 1)/p_inc + 1,
		        ( unsigned long )m,
		        ( unsigned long )k,
		        ( unsigned long )n, dtime_save, gflops );

		bli_obj_free( &alpha );
		bli_obj_free( &beta );

		bli_obj_free( &a );
		bli_obj_free( &b );
		bli_obj_free( &c );
		bli_obj_free( &c_save );
	}

	bli_finalize();

	return 0;
}