/** Perform Hermitian rank-2k update. \f$ C = \alpha A B^T + \alpha B A^T \beta C \f$ (trans == MagmaNoTrans), or \n \f$ C = \alpha A^T B + \alpha B^T A \beta C \f$ (trans == MagmaTrans), \n where \f$ C \f$ is Hermitian. @param[in] uplo Whether the upper or lower triangle of C is referenced. @param[in] trans Operation to perform on A and B. @param[in] n Number of rows and columns of C. n >= 0. @param[in] k Number of columns of A and B (for MagmaNoTrans) or rows of A and B (for MagmaTrans). k >= 0. @param[in] alpha Scalar \f$ \alpha \f$ @param[in] dA COMPLEX_16 array on GPU device. If trans == MagmaNoTrans, the n-by-k matrix A of dimension (ldda,k), ldda >= max(1,n); \n otherwise, the k-by-n matrix A of dimension (ldda,n), ldda >= max(1,k). @param[in] ldda Leading dimension of dA. @param[in] dB COMPLEX_16 array on GPU device. If trans == MagmaNoTrans, the n-by-k matrix B of dimension (lddb,k), lddb >= max(1,n); \n otherwise, the k-by-n matrix B of dimension (lddb,n), lddb >= max(1,k). @param[in] lddb Leading dimension of dB. @param[in] beta Scalar \f$ \beta \f$ @param[in,out] dC COMPLEX_16 array on GPU device. The n-by-n Hermitian matrix C of dimension (lddc,n), lddc >= max(1,n). @param[in] lddc Leading dimension of dC. @ingroup magma_zblas3 */ extern "C" void magma_zher2k( magma_uplo_t uplo, magma_trans_t trans, magma_int_t n, magma_int_t k, magmaDoubleComplex alpha, magmaDoubleComplex_const_ptr dA, magma_int_t ldda, magmaDoubleComplex_const_ptr dB, magma_int_t lddb, double beta, magmaDoubleComplex_ptr dC, magma_int_t lddc ) { cublasZher2k( cublas_uplo_const( uplo ), cublas_trans_const( trans ), n, k, alpha, dA, ldda, dB, lddb, beta, dC, lddc ); }
/* //////////////////////////////////////////////////////////////////////////// -- Testing zher2k */ int main( int argc, char** argv) { TESTING_INIT(); real_Double_t gflops, cublas_perf, cublas_time, cpu_perf, cpu_time; double cublas_error, Cnorm, work[1]; magma_int_t N, K; magma_int_t Ak, An, Bk, Bn; magma_int_t sizeA, sizeB, sizeC; magma_int_t lda, ldb, ldc, ldda, lddb, lddc; magma_int_t ione = 1; magma_int_t ISEED[4] = {0,0,0,1}; magmaDoubleComplex *h_A, *h_B, *h_C, *h_Ccublas; magmaDoubleComplex *d_A, *d_B, *d_C; magmaDoubleComplex c_neg_one = MAGMA_Z_NEG_ONE; magmaDoubleComplex alpha = MAGMA_Z_MAKE( 0.29, -0.86 ); double beta = MAGMA_D_MAKE( -0.48, 0.38 ); magma_int_t status = 0; magma_opts opts; parse_opts( argc, argv, &opts ); opts.lapack |= opts.check; // check (-c) implies lapack (-l) double tol = opts.tolerance * lapackf77_dlamch("E"); printf("If running lapack (option --lapack), CUBLAS error is computed\n" "relative to CPU BLAS result.\n\n"); printf("uplo = %s, transA = %s\n", lapack_uplo_const(opts.uplo), lapack_trans_const(opts.transA) ); printf(" N K CUBLAS Gflop/s (ms) CPU Gflop/s (ms) CUBLAS error\n"); printf("==================================================================\n"); for( int itest = 0; itest < opts.ntest; ++itest ) { for( int iter = 0; iter < opts.niter; ++iter ) { N = opts.msize[itest]; K = opts.ksize[itest]; gflops = FLOPS_ZHER2K(K, N) / 1e9; if ( opts.transA == MagmaNoTrans ) { lda = An = N; Ak = K; ldb = Bn = N; Bk = K; } else { lda = An = K; Ak = N; ldb = Bn = K; Bk = N; } ldc = N; ldda = ((lda+31)/32)*32; lddb = ((ldb+31)/32)*32; lddc = ((ldc+31)/32)*32; sizeA = lda*Ak; sizeB = ldb*Ak; sizeC = ldc*N; TESTING_MALLOC_CPU( h_A, magmaDoubleComplex, lda*Ak ); TESTING_MALLOC_CPU( h_B, magmaDoubleComplex, ldb*Bk ); TESTING_MALLOC_CPU( h_C, magmaDoubleComplex, ldc*N ); TESTING_MALLOC_CPU( h_Ccublas, magmaDoubleComplex, ldc*N ); TESTING_MALLOC_DEV( d_A, magmaDoubleComplex, ldda*Ak ); TESTING_MALLOC_DEV( d_B, magmaDoubleComplex, lddb*Bk ); TESTING_MALLOC_DEV( d_C, magmaDoubleComplex, lddc*N ); /* Initialize the matrices */ lapackf77_zlarnv( &ione, ISEED, &sizeA, h_A ); lapackf77_zlarnv( &ione, ISEED, &sizeB, h_B ); lapackf77_zlarnv( &ione, ISEED, &sizeC, h_C ); /* ===================================================================== Performs operation using CUBLAS =================================================================== */ magma_zsetmatrix( An, Ak, h_A, lda, d_A, ldda ); magma_zsetmatrix( Bn, Bk, h_B, ldb, d_B, lddb ); magma_zsetmatrix( N, N, h_C, ldc, d_C, lddc ); cublas_time = magma_sync_wtime( NULL ); cublasZher2k( handle, cublas_uplo_const(opts.uplo), cublas_trans_const(opts.transA), N, K, &alpha, d_A, ldda, d_B, lddb, &beta, d_C, lddc ); cublas_time = magma_sync_wtime( NULL ) - cublas_time; cublas_perf = gflops / cublas_time; magma_zgetmatrix( N, N, d_C, lddc, h_Ccublas, ldc ); /* ===================================================================== Performs operation using CPU BLAS =================================================================== */ if ( opts.lapack ) { cpu_time = magma_wtime(); blasf77_zher2k( lapack_uplo_const(opts.uplo), lapack_trans_const(opts.transA), &N, &K, &alpha, h_A, &lda, h_B, &ldb, &beta, h_C, &ldc ); cpu_time = magma_wtime() - cpu_time; cpu_perf = gflops / cpu_time; } /* ===================================================================== Check the result =================================================================== */ if ( opts.lapack ) { // compute relative error for both magma & cublas, relative to lapack, // |C_magma - C_lapack| / |C_lapack| Cnorm = lapackf77_zlange( "M", &N, &N, h_C, &ldc, work ); blasf77_zaxpy( &sizeC, &c_neg_one, h_C, &ione, h_Ccublas, &ione ); cublas_error = lapackf77_zlange( "M", &N, &N, h_Ccublas, &ldc, work ) / Cnorm; printf("%5d %5d %7.2f (%7.2f) %7.2f (%7.2f) %8.2e %s\n", (int) N, (int) K, cublas_perf, 1000.*cublas_time, cpu_perf, 1000.*cpu_time, cublas_error, (cublas_error < tol ? "ok" : "failed")); status += ! (cublas_error < tol); } else { printf("%5d %5d %7.2f (%7.2f) --- ( --- ) --- ---\n", (int) N, (int) K, cublas_perf, 1000.*cublas_time); } TESTING_FREE_CPU( h_A ); TESTING_FREE_CPU( h_B ); TESTING_FREE_CPU( h_C ); TESTING_FREE_CPU( h_Ccublas ); TESTING_FREE_DEV( d_A ); TESTING_FREE_DEV( d_B ); TESTING_FREE_DEV( d_C ); fflush( stdout ); } if ( opts.niter > 1 ) { printf( "\n" ); } } TESTING_FINALIZE(); return status; }
int main( int argc, char** argv ) { TESTING_INIT(); real_Double_t gflops, t1, t2; magmaDoubleComplex c_neg_one = MAGMA_Z_NEG_ONE; magma_int_t ione = 1; magma_trans_t trans[] = { MagmaNoTrans, MagmaConjTrans, MagmaTrans }; magma_uplo_t uplo [] = { MagmaLower, MagmaUpper }; magma_diag_t diag [] = { MagmaUnit, MagmaNonUnit }; magma_side_t side [] = { MagmaLeft, MagmaRight }; magmaDoubleComplex *A, *B, *C, *C2, *LU; magmaDoubleComplex *dA, *dB, *dC1, *dC2; magmaDoubleComplex alpha = MAGMA_Z_MAKE( 0.5, 0.1 ); magmaDoubleComplex beta = MAGMA_Z_MAKE( 0.7, 0.2 ); double dalpha = 0.6; double dbeta = 0.8; double work[1], error, total_error; magma_int_t ISEED[4] = {0,0,0,1}; magma_int_t m, n, k, size, maxn, ld, info; magma_int_t *piv; magma_int_t err; magma_opts opts; parse_opts( argc, argv, &opts ); printf( "Compares magma wrapper function to cublas function; all diffs should be exactly 0.\n\n" ); total_error = 0.; for( int itest = 0; itest < opts.ntest; ++itest ) { m = opts.msize[itest]; n = opts.nsize[itest]; k = opts.ksize[itest]; printf("=========================================================================\n"); printf( "m=%d, n=%d, k=%d\n", (int) m, (int) n, (int) k ); // allocate matrices // over-allocate so they can be any combination of {m,n,k} x {m,n,k}. maxn = max( max( m, n ), k ); ld = max( 1, maxn ); size = ld*maxn; err = magma_malloc_cpu( (void**) &piv, maxn*sizeof(magma_int_t) ); assert( err == 0 ); err = magma_zmalloc_pinned( &A, size ); assert( err == 0 ); err = magma_zmalloc_pinned( &B, size ); assert( err == 0 ); err = magma_zmalloc_pinned( &C, size ); assert( err == 0 ); err = magma_zmalloc_pinned( &C2, size ); assert( err == 0 ); err = magma_zmalloc_pinned( &LU, size ); assert( err == 0 ); err = magma_zmalloc( &dA, size ); assert( err == 0 ); err = magma_zmalloc( &dB, size ); assert( err == 0 ); err = magma_zmalloc( &dC1, size ); assert( err == 0 ); err = magma_zmalloc( &dC2, size ); assert( err == 0 ); // initialize matrices size = maxn*maxn; lapackf77_zlarnv( &ione, ISEED, &size, A ); lapackf77_zlarnv( &ione, ISEED, &size, B ); lapackf77_zlarnv( &ione, ISEED, &size, C ); printf( "========== Level 1 BLAS ==========\n" ); // ----- test ZSWAP // swap columns 2 and 3 of dA, then copy to C2 and compare with A if ( n >= 3 ) { magma_zsetmatrix( m, n, A, ld, dA, ld ); magma_zsetmatrix( m, n, A, ld, dB, ld ); magma_zswap( m, dA(0,1), 1, dA(0,2), 1 ); magma_zswap( m, dB(0,1), 1, dB(0,2), 1 ); // check results, storing diff between magma and cuda calls in C2 cublasZaxpy( handle, ld*n, &c_neg_one, dA, 1, dB, 1 ); magma_zgetmatrix( m, n, dB, ld, C2, ld ); error = lapackf77_zlange( "F", &m, &k, C2, &ld, work ); total_error += error; printf( "zswap diff %.2g\n", error ); } else { printf( "zswap skipped for n < 3\n" ); } // ----- test IZAMAX // get argmax of column of A magma_zsetmatrix( m, k, A, ld, dA, ld ); error = 0; for( int j = 0; j < k; ++j ) { magma_int_t i1 = magma_izamax( m, dA(0,j), 1 ); int i2; // NOT magma_int_t, for cublas cublasIzamax( handle, m, dA(0,j), 1, &i2 ); // todo need sync here? assert( i1 == i2 ); error += abs( i1 - i2 ); } total_error += error; gflops = (double)m * k / 1e9; printf( "izamax diff %.2g\n", error ); printf( "\n" ); printf( "========== Level 2 BLAS ==========\n" ); // ----- test ZGEMV // c = alpha*A*b + beta*c, with A m*n; b,c m or n-vectors // try no-trans/trans for( int ia = 0; ia < 3; ++ia ) { magma_zsetmatrix( m, n, A, ld, dA, ld ); magma_zsetvector( maxn, B, 1, dB, 1 ); magma_zsetvector( maxn, C, 1, dC1, 1 ); magma_zsetvector( maxn, C, 1, dC2, 1 ); t1 = magma_sync_wtime( 0 ); magma_zgemv( trans[ia], m, n, alpha, dA, ld, dB, 1, beta, dC1, 1 ); t1 = magma_sync_wtime( 0 ) - t1; t2 = magma_sync_wtime( 0 ); cublasZgemv( handle, cublas_trans_const(trans[ia]), m, n, &alpha, dA, ld, dB, 1, &beta, dC2, 1 ); t2 = magma_sync_wtime( 0 ) - t2; // check results, storing diff between magma and cuda call in C2 size = (trans[ia] == MagmaNoTrans ? m : n); cublasZaxpy( handle, size, &c_neg_one, dC1, 1, dC2, 1 ); magma_zgetvector( size, dC2, 1, C2, 1 ); error = lapackf77_zlange( "F", &size, &ione, C2, &ld, work ); total_error += error; gflops = FLOPS_ZGEMV( m, n ) / 1e9; printf( "zgemv( %c ) diff %.2g, Gflop/s %7.2f, %7.2f\n", lapacke_trans_const(trans[ia]), error, gflops/t1, gflops/t2 ); } printf( "\n" ); // ----- test ZHEMV // c = alpha*A*b + beta*c, with A m*m symmetric; b,c m-vectors // try upper/lower for( int iu = 0; iu < 2; ++iu ) { magma_zsetmatrix( m, m, A, ld, dA, ld ); magma_zsetvector( m, B, 1, dB, 1 ); magma_zsetvector( m, C, 1, dC1, 1 ); magma_zsetvector( m, C, 1, dC2, 1 ); t1 = magma_sync_wtime( 0 ); magma_zhemv( uplo[iu], m, alpha, dA, ld, dB, 1, beta, dC1, 1 ); t1 = magma_sync_wtime( 0 ) - t1; t2 = magma_sync_wtime( 0 ); cublasZhemv( handle, cublas_uplo_const(uplo[iu]), m, &alpha, dA, ld, dB, 1, &beta, dC2, 1 ); t2 = magma_sync_wtime( 0 ) - t2; // check results, storing diff between magma and cuda call in C2 cublasZaxpy( handle, m, &c_neg_one, dC1, 1, dC2, 1 ); magma_zgetvector( m, dC2, 1, C2, 1 ); error = lapackf77_zlange( "F", &m, &ione, C2, &ld, work ); total_error += error; gflops = FLOPS_ZHEMV( m ) / 1e9; printf( "zhemv( %c ) diff %.2g, Gflop/s %7.2f, %7.2f\n", lapacke_uplo_const(uplo[iu]), error, gflops/t1, gflops/t2 ); } printf( "\n" ); // ----- test ZTRSV // solve A*c = c, with A m*m triangular; c m-vector // try upper/lower, no-trans/trans, unit/non-unit diag // Factor A into LU to get well-conditioned triangles, else solve yields garbage. // Still can give garbage if solves aren't consistent with LU factors, // e.g., using unit diag for U, so copy lower triangle to upper triangle. // Also used for trsm later. lapackf77_zlacpy( "Full", &maxn, &maxn, A, &ld, LU, &ld ); lapackf77_zgetrf( &maxn, &maxn, LU, &ld, piv, &info ); for( int j = 0; j < maxn; ++j ) { for( int i = 0; i < j; ++i ) { *LU(i,j) = *LU(j,i); } } for( int iu = 0; iu < 2; ++iu ) { for( int it = 0; it < 3; ++it ) { for( int id = 0; id < 2; ++id ) { magma_zsetmatrix( m, m, LU, ld, dA, ld ); magma_zsetvector( m, C, 1, dC1, 1 ); magma_zsetvector( m, C, 1, dC2, 1 ); t1 = magma_sync_wtime( 0 ); magma_ztrsv( uplo[iu], trans[it], diag[id], m, dA, ld, dC1, 1 ); t1 = magma_sync_wtime( 0 ) - t1; t2 = magma_sync_wtime( 0 ); cublasZtrsv( handle, cublas_uplo_const(uplo[iu]), cublas_trans_const(trans[it]), cublas_diag_const(diag[id]), m, dA, ld, dC2, 1 ); t2 = magma_sync_wtime( 0 ) - t2; // check results, storing diff between magma and cuda call in C2 cublasZaxpy( handle, m, &c_neg_one, dC1, 1, dC2, 1 ); magma_zgetvector( m, dC2, 1, C2, 1 ); error = lapackf77_zlange( "F", &m, &ione, C2, &ld, work ); total_error += error; gflops = FLOPS_ZTRSM( MagmaLeft, m, 1 ) / 1e9; printf( "ztrsv( %c, %c, %c ) diff %.2g, Gflop/s %7.2f, %7.2f\n", lapacke_uplo_const(uplo[iu]), lapacke_trans_const(trans[it]), lapacke_diag_const(diag[id]), error, gflops/t1, gflops/t2 ); }}} printf( "\n" ); printf( "========== Level 3 BLAS ==========\n" ); // ----- test ZGEMM // C = alpha*A*B + beta*C, with A m*k or k*m; B k*n or n*k; C m*n // try combinations of no-trans/trans for( int ia = 0; ia < 3; ++ia ) { for( int ib = 0; ib < 3; ++ib ) { bool nta = (trans[ia] == MagmaNoTrans); bool ntb = (trans[ib] == MagmaNoTrans); magma_zsetmatrix( (nta ? m : k), (nta ? m : k), A, ld, dA, ld ); magma_zsetmatrix( (ntb ? k : n), (ntb ? n : k), B, ld, dB, ld ); magma_zsetmatrix( m, n, C, ld, dC1, ld ); magma_zsetmatrix( m, n, C, ld, dC2, ld ); t1 = magma_sync_wtime( 0 ); magma_zgemm( trans[ia], trans[ib], m, n, k, alpha, dA, ld, dB, ld, beta, dC1, ld ); t1 = magma_sync_wtime( 0 ) - t1; t2 = magma_sync_wtime( 0 ); cublasZgemm( handle, cublas_trans_const(trans[ia]), cublas_trans_const(trans[ib]), m, n, k, &alpha, dA, ld, dB, ld, &beta, dC2, ld ); t2 = magma_sync_wtime( 0 ) - t2; // check results, storing diff between magma and cuda call in C2 cublasZaxpy( handle, ld*n, &c_neg_one, dC1, 1, dC2, 1 ); magma_zgetmatrix( m, n, dC2, ld, C2, ld ); error = lapackf77_zlange( "F", &m, &n, C2, &ld, work ); total_error += error; gflops = FLOPS_ZGEMM( m, n, k ) / 1e9; printf( "zgemm( %c, %c ) diff %.2g, Gflop/s %7.2f, %7.2f\n", lapacke_trans_const(trans[ia]), lapacke_trans_const(trans[ib]), error, gflops/t1, gflops/t2 ); }} printf( "\n" ); // ----- test ZHEMM // C = alpha*A*B + beta*C (left) with A m*m symmetric; B,C m*n; or // C = alpha*B*A + beta*C (right) with A n*n symmetric; B,C m*n // try left/right, upper/lower for( int is = 0; is < 2; ++is ) { for( int iu = 0; iu < 2; ++iu ) { magma_zsetmatrix( m, m, A, ld, dA, ld ); magma_zsetmatrix( m, n, B, ld, dB, ld ); magma_zsetmatrix( m, n, C, ld, dC1, ld ); magma_zsetmatrix( m, n, C, ld, dC2, ld ); t1 = magma_sync_wtime( 0 ); magma_zhemm( side[is], uplo[iu], m, n, alpha, dA, ld, dB, ld, beta, dC1, ld ); t1 = magma_sync_wtime( 0 ) - t1; t2 = magma_sync_wtime( 0 ); cublasZhemm( handle, cublas_side_const(side[is]), cublas_uplo_const(uplo[iu]), m, n, &alpha, dA, ld, dB, ld, &beta, dC2, ld ); t2 = magma_sync_wtime( 0 ) - t2; // check results, storing diff between magma and cuda call in C2 cublasZaxpy( handle, ld*n, &c_neg_one, dC1, 1, dC2, 1 ); magma_zgetmatrix( m, n, dC2, ld, C2, ld ); error = lapackf77_zlange( "F", &m, &n, C2, &ld, work ); total_error += error; gflops = FLOPS_ZHEMM( side[is], m, n ) / 1e9; printf( "zhemm( %c, %c ) diff %.2g, Gflop/s %7.2f, %7.2f\n", lapacke_side_const(side[is]), lapacke_uplo_const(uplo[iu]), error, gflops/t1, gflops/t2 ); }} printf( "\n" ); // ----- test ZHERK // C = alpha*A*A^H + beta*C (no-trans) with A m*k and C m*m symmetric; or // C = alpha*A^H*A + beta*C (trans) with A k*m and C m*m symmetric // try upper/lower, no-trans/trans for( int iu = 0; iu < 2; ++iu ) { for( int it = 0; it < 3; ++it ) { magma_zsetmatrix( n, k, A, ld, dA, ld ); magma_zsetmatrix( n, n, C, ld, dC1, ld ); magma_zsetmatrix( n, n, C, ld, dC2, ld ); t1 = magma_sync_wtime( 0 ); magma_zherk( uplo[iu], trans[it], n, k, dalpha, dA, ld, dbeta, dC1, ld ); t1 = magma_sync_wtime( 0 ) - t1; t2 = magma_sync_wtime( 0 ); cublasZherk( handle, cublas_uplo_const(uplo[iu]), cublas_trans_const(trans[it]), n, k, &dalpha, dA, ld, &dbeta, dC2, ld ); t2 = magma_sync_wtime( 0 ) - t2; // check results, storing diff between magma and cuda call in C2 cublasZaxpy( handle, ld*n, &c_neg_one, dC1, 1, dC2, 1 ); magma_zgetmatrix( n, n, dC2, ld, C2, ld ); error = lapackf77_zlange( "F", &n, &n, C2, &ld, work ); total_error += error; gflops = FLOPS_ZHERK( k, n ) / 1e9; printf( "zherk( %c, %c ) diff %.2g, Gflop/s %7.2f, %7.2f\n", lapacke_uplo_const(uplo[iu]), lapacke_trans_const(trans[it]), error, gflops/t1, gflops/t2 ); }} printf( "\n" ); // ----- test ZHER2K // C = alpha*A*B^H + ^alpha*B*A^H + beta*C (no-trans) with A,B n*k; C n*n symmetric; or // C = alpha*A^H*B + ^alpha*B^H*A + beta*C (trans) with A,B k*n; C n*n symmetric // try upper/lower, no-trans/trans for( int iu = 0; iu < 2; ++iu ) { for( int it = 0; it < 3; ++it ) { bool nt = (trans[it] == MagmaNoTrans); magma_zsetmatrix( (nt ? n : k), (nt ? n : k), A, ld, dA, ld ); magma_zsetmatrix( n, n, C, ld, dC1, ld ); magma_zsetmatrix( n, n, C, ld, dC2, ld ); t1 = magma_sync_wtime( 0 ); magma_zher2k( uplo[iu], trans[it], n, k, alpha, dA, ld, dB, ld, dbeta, dC1, ld ); t1 = magma_sync_wtime( 0 ) - t1; t2 = magma_sync_wtime( 0 ); cublasZher2k( handle, cublas_uplo_const(uplo[iu]), cublas_trans_const(trans[it]), n, k, &alpha, dA, ld, dB, ld, &dbeta, dC2, ld ); t2 = magma_sync_wtime( 0 ) - t2; // check results, storing diff between magma and cuda call in C2 cublasZaxpy( handle, ld*n, &c_neg_one, dC1, 1, dC2, 1 ); magma_zgetmatrix( n, n, dC2, ld, C2, ld ); error = lapackf77_zlange( "F", &n, &n, C2, &ld, work ); total_error += error; gflops = FLOPS_ZHER2K( k, n ) / 1e9; printf( "zher2k( %c, %c ) diff %.2g, Gflop/s %7.2f, %7.2f\n", lapacke_uplo_const(uplo[iu]), lapacke_trans_const(trans[it]), error, gflops/t1, gflops/t2 ); }} printf( "\n" ); // ----- test ZTRMM // C = alpha*A*C (left) with A m*m triangular; C m*n; or // C = alpha*C*A (right) with A n*n triangular; C m*n // try left/right, upper/lower, no-trans/trans, unit/non-unit for( int is = 0; is < 2; ++is ) { for( int iu = 0; iu < 2; ++iu ) { for( int it = 0; it < 3; ++it ) { for( int id = 0; id < 2; ++id ) { bool left = (side[is] == MagmaLeft); magma_zsetmatrix( (left ? m : n), (left ? m : n), A, ld, dA, ld ); magma_zsetmatrix( m, n, C, ld, dC1, ld ); magma_zsetmatrix( m, n, C, ld, dC2, ld ); t1 = magma_sync_wtime( 0 ); magma_ztrmm( side[is], uplo[iu], trans[it], diag[id], m, n, alpha, dA, ld, dC1, ld ); t1 = magma_sync_wtime( 0 ) - t1; // note cublas does trmm out-of-place (i.e., adds output matrix C), // but allows C=B to do in-place. t2 = magma_sync_wtime( 0 ); cublasZtrmm( handle, cublas_side_const(side[is]), cublas_uplo_const(uplo[iu]), cublas_trans_const(trans[it]), cublas_diag_const(diag[id]), m, n, &alpha, dA, ld, dC2, ld, dC2, ld ); t2 = magma_sync_wtime( 0 ) - t2; // check results, storing diff between magma and cuda call in C2 cublasZaxpy( handle, ld*n, &c_neg_one, dC1, 1, dC2, 1 ); magma_zgetmatrix( m, n, dC2, ld, C2, ld ); error = lapackf77_zlange( "F", &n, &n, C2, &ld, work ); total_error += error; gflops = FLOPS_ZTRMM( side[is], m, n ) / 1e9; printf( "ztrmm( %c, %c ) diff %.2g, Gflop/s %7.2f, %7.2f\n", lapacke_uplo_const(uplo[iu]), lapacke_trans_const(trans[it]), error, gflops/t1, gflops/t2 ); }}}} printf( "\n" ); // ----- test ZTRSM // solve A*X = alpha*B (left) with A m*m triangular; B m*n; or // solve X*A = alpha*B (right) with A n*n triangular; B m*n // try left/right, upper/lower, no-trans/trans, unit/non-unit for( int is = 0; is < 2; ++is ) { for( int iu = 0; iu < 2; ++iu ) { for( int it = 0; it < 3; ++it ) { for( int id = 0; id < 2; ++id ) { bool left = (side[is] == MagmaLeft); magma_zsetmatrix( (left ? m : n), (left ? m : n), LU, ld, dA, ld ); magma_zsetmatrix( m, n, C, ld, dC1, ld ); magma_zsetmatrix( m, n, C, ld, dC2, ld ); t1 = magma_sync_wtime( 0 ); magma_ztrsm( side[is], uplo[iu], trans[it], diag[id], m, n, alpha, dA, ld, dC1, ld ); t1 = magma_sync_wtime( 0 ) - t1; t2 = magma_sync_wtime( 0 ); cublasZtrsm( handle, cublas_side_const(side[is]), cublas_uplo_const(uplo[iu]), cublas_trans_const(trans[it]), cublas_diag_const(diag[id]), m, n, &alpha, dA, ld, dC2, ld ); t2 = magma_sync_wtime( 0 ) - t2; // check results, storing diff between magma and cuda call in C2 cublasZaxpy( handle, ld*n, &c_neg_one, dC1, 1, dC2, 1 ); magma_zgetmatrix( m, n, dC2, ld, C2, ld ); error = lapackf77_zlange( "F", &n, &n, C2, &ld, work ); total_error += error; gflops = FLOPS_ZTRSM( side[is], m, n ) / 1e9; printf( "ztrsm( %c, %c ) diff %.2g, Gflop/s %7.2f, %7.2f\n", lapacke_uplo_const(uplo[iu]), lapacke_trans_const(trans[it]), error, gflops/t1, gflops/t2 ); }}}} printf( "\n" ); // cleanup magma_free_cpu( piv ); magma_free_pinned( A ); magma_free_pinned( B ); magma_free_pinned( C ); magma_free_pinned( C2 ); magma_free_pinned( LU ); magma_free( dA ); magma_free( dB ); magma_free( dC1 ); magma_free( dC2 ); fflush( stdout ); } if ( total_error != 0. ) { printf( "total error %.2g -- ought to be 0 -- some test failed (see above).\n", total_error ); } else { printf( "all tests passed\n" ); } TESTING_FINALIZE(); int status = (total_error != 0.); return status; }