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/*
-- MAGMA (version 2.9.0) --
Univ. of Tennessee, Knoxville
Univ. of California, Berkeley
Univ. of Colorado, Denver
@date January 2025
@generated from testing/testing_zgetrf_mgpu.cpp, normal z -> c, Wed Jan 22 14:40:30 2025
@author Mark Gates
*/
// includes, system
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <math.h>
// includes, project
#include "flops.h"
#include "magma_v2.h"
#include "magma_lapack.h"
#include "testings.h"
// Initialize matrix to random.
// This ensures the same ISEED is always used,
// so we can re-generate the identical matrix.
void init_matrix(
magma_opts &opts,
magma_int_t m, magma_int_t n,
magmaFloatComplex *A, magma_int_t lda )
{
magma_int_t iseed_save[4];
for (magma_int_t i = 0; i < 4; ++i) {
iseed_save[i] = opts.iseed[i];
}
magma_generate_matrix( opts, m, n, A, lda );
// restore iseed
for (magma_int_t i = 0; i < 4; ++i) {
opts.iseed[i] = iseed_save[i];
}
}
// On input, A and ipiv is LU factorization of A. On output, A is overwritten.
// Requires m == n.
// Uses init_matrix() to re-generate original A as needed.
// Generates random RHS b and solves Ax=b.
// Returns residual, |Ax - b| / (n |A| |x|).
float get_residual(
magma_opts &opts,
magma_int_t m, magma_int_t n,
magmaFloatComplex *A, magma_int_t lda,
magma_int_t *ipiv )
{
if ( m != n ) {
printf( "\nERROR: residual check defined only for square matrices\n" );
return -1;
}
const magmaFloatComplex c_one = MAGMA_C_ONE;
const magmaFloatComplex c_neg_one = MAGMA_C_NEG_ONE;
const magma_int_t ione = 1;
// this seed should be DIFFERENT than used in init_matrix
// (else x is column of A, so residual can be exactly zero)
magma_int_t ISEED[4] = {0,0,0,1};
magma_int_t info = 0;
magmaFloatComplex *x, *b;
// initialize RHS
TESTING_CHECK( magma_cmalloc_cpu( &x, n ));
TESTING_CHECK( magma_cmalloc_cpu( &b, n ));
lapackf77_clarnv( &ione, ISEED, &n, b );
blasf77_ccopy( &n, b, &ione, x, &ione );
// solve Ax = b
lapackf77_cgetrs( "Notrans", &n, &ione, A, &lda, ipiv, x, &n, &info );
if (info != 0) {
printf("lapackf77_cgetrs returned error %lld: %s.\n",
(long long) info, magma_strerror( info ));
}
// reset to original A
init_matrix( opts, m, n, A, lda );
// compute r = Ax - b, saved in b
blasf77_cgemv( "Notrans", &m, &n, &c_one, A, &lda, x, &ione, &c_neg_one, b, &ione );
// compute residual |Ax - b| / (n*|A|*|x|)
float norm_x, norm_A, norm_r, work[1];
norm_A = lapackf77_clange( "F", &m, &n, A, &lda, work );
norm_r = lapackf77_clange( "F", &n, &ione, b, &n, work );
norm_x = lapackf77_clange( "F", &n, &ione, x, &n, work );
//printf( "r=\n" ); magma_cprint( 1, n, b, 1 );
magma_free_cpu( x );
magma_free_cpu( b );
//printf( "r=%.2e, A=%.2e, x=%.2e, n=%lld\n", norm_r, norm_A, norm_x, (long long) n );
return norm_r / (n * norm_A * norm_x);
}
// On input, LU and ipiv is LU factorization of A. On output, LU is overwritten.
// Works for any m, n.
// Uses init_matrix() to re-generate original A as needed.
// Returns error in factorization, |PA - LU| / (n |A|)
// This allocates 3 more matrices to store A, L, and U.
float get_LU_error(
magma_opts &opts,
magma_int_t M, magma_int_t N,
magmaFloatComplex *LU, magma_int_t lda,
magma_int_t *ipiv)
{
magma_int_t min_mn = min(M,N);
magma_int_t ione = 1;
magma_int_t i, j;
magmaFloatComplex alpha = MAGMA_C_ONE;
magmaFloatComplex beta = MAGMA_C_ZERO;
magmaFloatComplex *A, *L, *U;
float work[1], matnorm, residual;
TESTING_CHECK( magma_cmalloc_cpu( &A, lda*N ));
TESTING_CHECK( magma_cmalloc_cpu( &L, M*min_mn ));
TESTING_CHECK( magma_cmalloc_cpu( &U, min_mn*N ));
memset( L, 0, M*min_mn*sizeof(magmaFloatComplex) );
memset( U, 0, min_mn*N*sizeof(magmaFloatComplex) );
// set to original A
init_matrix( opts, M, N, A, lda );
lapackf77_claswp( &N, A, &lda, &ione, &min_mn, ipiv, &ione);
// copy LU to L and U, and set diagonal to 1
lapackf77_clacpy( MagmaLowerStr, &M, &min_mn, LU, &lda, L, &M );
lapackf77_clacpy( MagmaUpperStr, &min_mn, &N, LU, &lda, U, &min_mn );
for (j=0; j < min_mn; j++)
L[j+j*M] = MAGMA_C_MAKE( 1., 0. );
matnorm = lapackf77_clange("f", &M, &N, A, &lda, work);
blasf77_cgemm("N", "N", &M, &N, &min_mn,
&alpha, L, &M, U, &min_mn, &beta, LU, &lda);
for( j = 0; j < N; j++ ) {
for( i = 0; i < M; i++ ) {
LU[i+j*lda] = MAGMA_C_SUB( LU[i+j*lda], A[i+j*lda] );
}
}
residual = lapackf77_clange("f", &M, &N, LU, &lda, work);
magma_free_cpu( A );
magma_free_cpu( L );
magma_free_cpu( U );
return residual / (matnorm * N);
}
/* ////////////////////////////////////////////////////////////////////////////
-- Testing cgetrf_mgpu
*/
int main( int argc, char** argv )
{
TESTING_CHECK( magma_init() );
magma_print_environment();
real_Double_t gflops, gpu_perf, gpu_time, cpu_perf=0, cpu_time=0;
float error;
magmaFloatComplex *h_A;
magmaFloatComplex_ptr d_lA[ MagmaMaxGPUs ];
magma_int_t *ipiv;
magma_int_t M, N, n2, lda, ldda, n_local, ngpu;
magma_int_t info, min_mn, nb, ldn_local;
int status = 0;
magma_opts opts;
opts.parse_opts( argc, argv );
opts.ngpu = abs( opts.ngpu ); // always uses multi-GPU code
float tol = opts.tolerance * lapackf77_slamch("E");
magma_queue_t queues[MagmaMaxGPUs];
for( int dev = 0; dev < opts.ngpu; ++dev ) {
magma_queue_create( dev, &queues[dev] );
}
printf("%% ngpu %lld\n", (long long) opts.ngpu );
if ( opts.check == 2 ) {
printf("%% M N CPU Gflop/s (sec) GPU Gflop/s (sec) |Ax-b|/(N*|A|*|x|)\n");
}
else {
printf("%% M N CPU Gflop/s (sec) GPU Gflop/s (sec) |PA-LU|/(N*|A|)\n");
}
printf("%%========================================================================\n");
for( int itest = 0; itest < opts.ntest; ++itest ) {
for( int iter = 0; iter < opts.niter; ++iter ) {
M = opts.msize[itest];
N = opts.nsize[itest];
min_mn = min(M, N);
lda = M;
n2 = lda*N;
ldda = magma_roundup( M, opts.align ); // multiple of 32 by default
nb = magma_get_cgetrf_nb( M, N );
gflops = FLOPS_CGETRF( M, N ) / 1e9;
// ngpu must be at least the number of blocks
ngpu = min( opts.ngpu, magma_ceildiv(N,nb) );
if ( ngpu < opts.ngpu ) {
printf( " * too many GPUs for the matrix size, using %lld GPUs\n", (long long) ngpu );
}
// Allocate host memory for the matrix
TESTING_CHECK( magma_imalloc_cpu( &ipiv, min_mn ));
TESTING_CHECK( magma_cmalloc_cpu( &h_A, n2 ));
// Allocate device memory
for( int dev=0; dev < ngpu; dev++ ) {
n_local = ((N/nb)/ngpu)*nb;
if (dev < (N/nb) % ngpu)
n_local += nb;
else if (dev == (N/nb) % ngpu)
n_local += N % nb;
ldn_local = magma_roundup( n_local, opts.align ); // multiple of 32 by default // TODO why?
magma_setdevice( dev );
TESTING_CHECK( magma_cmalloc( &d_lA[dev], ldda*ldn_local ));
}
/* =====================================================================
Performs operation using LAPACK
=================================================================== */
if ( opts.lapack ) {
init_matrix( opts, M, N, h_A, lda );
cpu_time = magma_wtime();
lapackf77_cgetrf( &M, &N, h_A, &lda, ipiv, &info );
cpu_time = magma_wtime() - cpu_time;
cpu_perf = gflops / cpu_time;
if (info != 0) {
printf("lapackf77_cgetrf returned error %lld: %s.\n",
(long long) info, magma_strerror( info ));
}
}
/* ====================================================================
Performs operation using MAGMA
=================================================================== */
init_matrix( opts, M, N, h_A, lda );
magma_csetmatrix_1D_col_bcyclic( ngpu, M, N, nb, h_A, lda, d_lA, ldda, queues );
gpu_time = magma_wtime();
magma_cgetrf_mgpu( ngpu, M, N, d_lA, ldda, ipiv, &info );
gpu_time = magma_wtime() - gpu_time;
gpu_perf = gflops / gpu_time;
if (info != 0) {
printf("magma_cgetrf_mgpu returned error %lld: %s.\n",
(long long) info, magma_strerror( info ));
}
magma_cgetmatrix_1D_col_bcyclic( ngpu, M, N, nb, d_lA, ldda, h_A, lda, queues );
/* =====================================================================
Check the factorization
=================================================================== */
if ( opts.lapack ) {
printf("%5lld %5lld %7.2f (%7.2f) %7.2f (%7.2f)",
(long long) M, (long long) N, cpu_perf, cpu_time, gpu_perf, gpu_time );
}
else {
printf("%5lld %5lld --- ( --- ) %7.2f (%7.2f)",
(long long) M, (long long) N, gpu_perf, gpu_time );
}
if ( opts.check == 2 ) {
error = get_residual( opts, M, N, h_A, lda, ipiv );
printf(" %8.2e %s\n", error, (error < tol ? "ok" : "failed"));
status += ! (error < tol);
}
else if ( opts.check ) {
error = get_LU_error( opts, M, N, h_A, lda, ipiv );
printf(" %8.2e %s\n", error, (error < tol ? "ok" : "failed"));
status += ! (error < tol);
}
else {
printf( " ---\n" );
}
magma_free_cpu( ipiv );
magma_free_cpu( h_A );
for( int dev=0; dev < ngpu; dev++ ) {
magma_setdevice( dev );
magma_free( d_lA[dev] );
}
fflush( stdout );
}
if ( opts.niter > 1 ) {
printf( "\n" );
}
}
for( int dev = 0; dev < opts.ngpu; ++dev ) {
magma_queue_destroy( queues[dev] );
}
opts.cleanup();
TESTING_CHECK( magma_finalize() );
return status;
}
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