/*********************************************************************/ /* Copyright 2009, 2010 The University of Texas at Austin. */ /* All rights reserved. */ /* */ /* Redistribution and use in source and binary forms, with or */ /* without modification, are permitted provided that the following */ /* conditions are met: */ /* */ /* 1. Redistributions of source code must retain the above */ /* copyright notice, this list of conditions and the following */ /* disclaimer. */ /* */ /* 2. Redistributions in binary form must reproduce the above */ /* copyright notice, this list of conditions and the following */ /* disclaimer in the documentation and/or other materials */ /* provided with the distribution. */ /* */ /* THIS SOFTWARE IS PROVIDED BY THE UNIVERSITY OF TEXAS AT */ /* AUSTIN ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, */ /* INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF */ /* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE */ /* DISCLAIMED. IN NO EVENT SHALL THE UNIVERSITY OF TEXAS AT */ /* AUSTIN OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, */ /* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES */ /* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE */ /* GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR */ /* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF */ /* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT */ /* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT */ /* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE */ /* POSSIBILITY OF SUCH DAMAGE. */ /* */ /* The views and conclusions contained in the software and */ /* documentation are those of the authors and should not be */ /* interpreted as representing official policies, either expressed */ /* or implied, of The University of Texas at Austin. */ /*********************************************************************/ #include #include #include "common.h" #ifdef FUNCTION_PROFILE #include "functable.h" #endif #ifndef COMPLEX #ifdef XDOUBLE #define ERROR_NAME "QSYMM " #elif defined(DOUBLE) #define ERROR_NAME "DSYMM " #else #define ERROR_NAME "SSYMM " #endif #else #ifndef GEMM3M #ifndef HEMM #ifdef XDOUBLE #define ERROR_NAME "XSYMM " #elif defined(DOUBLE) #define ERROR_NAME "ZSYMM " #else #define ERROR_NAME "CSYMM " #endif #else #ifdef XDOUBLE #define ERROR_NAME "XHEMM " #elif defined(DOUBLE) #define ERROR_NAME "ZHEMM " #else #define ERROR_NAME "CHEMM " #endif #endif #else #ifndef HEMM #ifdef XDOUBLE #define ERROR_NAME "XSYMM3M " #elif defined(DOUBLE) #define ERROR_NAME "ZSYMM3M " #else #define ERROR_NAME "CSYMM3M " #endif #else #ifdef XDOUBLE #define ERROR_NAME "XHEMM3M " #elif defined(DOUBLE) #define ERROR_NAME "ZHEMM3M " #else #define ERROR_NAME "CHEMM3M " #endif #endif #endif #endif static int (*symm[])(blas_arg_t *, BLASLONG *, BLASLONG *, FLOAT *, FLOAT *, BLASLONG) = { #ifndef GEMM3M #ifndef HEMM SYMM_LU, SYMM_LL, SYMM_RU, SYMM_RL, #if defined(SMP) && !defined(USE_SIMPLE_THREADED_LEVEL3) SYMM_THREAD_LU, SYMM_THREAD_LL, SYMM_THREAD_RU, SYMM_THREAD_RL, #endif #else HEMM_LU, HEMM_LL, HEMM_RU, HEMM_RL, #if defined(SMP) && !defined(USE_SIMPLE_THREADED_LEVEL3) HEMM_THREAD_LU, HEMM_THREAD_LL, HEMM_THREAD_RU, HEMM_THREAD_RL, #endif #endif #else #ifndef HEMM SYMM3M_LU, SYMM3M_LL, SYMM3M_RU, SYMM3M_RL, #if defined(SMP) && !defined(USE_SIMPLE_THREADED_LEVEL3) SYMM3M_THREAD_LU, SYMM3M_THREAD_LL, SYMM3M_THREAD_RU, SYMM3M_THREAD_RL, #endif #else HEMM3M_LU, HEMM3M_LL, HEMM3M_RU, HEMM3M_RL, #if defined(SMP) && !defined(USE_SIMPLE_THREADED_LEVEL3) HEMM3M_THREAD_LU, HEMM3M_THREAD_LL, HEMM3M_THREAD_RU, HEMM3M_THREAD_RL, #endif #endif #endif }; #ifndef CBLAS void NAME(char *SIDE, char *UPLO, blasint *M, blasint *N, FLOAT *alpha, FLOAT *a, blasint *ldA, FLOAT *b, blasint *ldB, FLOAT *beta, FLOAT *c, blasint *ldC){ char side_arg = *SIDE; char uplo_arg = *UPLO; blas_arg_t args; FLOAT *buffer; FLOAT *sa, *sb; #ifdef SMP #ifndef COMPLEX #ifdef XDOUBLE int mode = BLAS_XDOUBLE | BLAS_REAL; #elif defined(DOUBLE) int mode = BLAS_DOUBLE | BLAS_REAL; #else int mode = BLAS_SINGLE | BLAS_REAL; #endif #else #ifdef XDOUBLE int mode = BLAS_XDOUBLE | BLAS_COMPLEX; #elif defined(DOUBLE) int mode = BLAS_DOUBLE | BLAS_COMPLEX; #else int mode = BLAS_SINGLE | BLAS_COMPLEX; #endif #endif #endif #if defined(SMP) && !defined(NO_AFFINITY) int nodes; #endif blasint info; int side; int uplo; PRINT_DEBUG_NAME; args.alpha = (void *)alpha; args.beta = (void *)beta; TOUPPER(side_arg); TOUPPER(uplo_arg); side = -1; uplo = -1; if (side_arg == 'L') side = 0; if (side_arg == 'R') side = 1; if (uplo_arg == 'U') uplo = 0; if (uplo_arg == 'L') uplo = 1; args.m = *M; args.n = *N; args.c = (void *)c; args.ldc = *ldC; info = 0; if (args.ldc < MAX(1, args.m)) info = 12; if (!side) { args.a = (void *)a; args.b = (void *)b; args.lda = *ldA; args.ldb = *ldB; if (args.ldb < MAX(1, args.m)) info = 9; if (args.lda < MAX(1, args.m)) info = 7; } else { args.a = (void *)b; args.b = (void *)a; args.lda = *ldB; args.ldb = *ldA; if (args.lda < MAX(1, args.m)) info = 9; if (args.ldb < MAX(1, args.n)) info = 7; } if (args.n < 0) info = 4; if (args.m < 0) info = 3; if (uplo < 0) info = 2; if (side < 0) info = 1; if (info != 0) { BLASFUNC(xerbla)(ERROR_NAME, &info, sizeof(ERROR_NAME)); return; } #else void CNAME(enum CBLAS_ORDER order, enum CBLAS_SIDE Side, enum CBLAS_UPLO Uplo, blasint m, blasint n, #ifndef COMPLEX FLOAT alpha, #else FLOAT *alpha, #endif FLOAT *a, blasint lda, FLOAT *b, blasint ldb, #ifndef COMPLEX FLOAT beta, #else FLOAT *beta, #endif FLOAT *c, blasint ldc) { blas_arg_t args; int side, uplo; blasint info; FLOAT *buffer; FLOAT *sa, *sb; #ifdef SMP #ifndef COMPLEX #ifdef XDOUBLE int mode = BLAS_XDOUBLE | BLAS_REAL; #elif defined(DOUBLE) int mode = BLAS_DOUBLE | BLAS_REAL; #else int mode = BLAS_SINGLE | BLAS_REAL; #endif #else #ifdef XDOUBLE int mode = BLAS_XDOUBLE | BLAS_COMPLEX; #elif defined(DOUBLE) int mode = BLAS_DOUBLE | BLAS_COMPLEX; #else int mode = BLAS_SINGLE | BLAS_COMPLEX; #endif #endif #endif #if defined(SMP) && !defined(NO_AFFINITY) int nodes; #endif PRINT_DEBUG_CNAME; #ifndef COMPLEX args.alpha = (void *)α args.beta = (void *)β #else args.alpha = (void *)alpha; args.beta = (void *)beta; #endif args.c = (void *)c; args.ldc = ldc; side = -1; uplo = -1; info = 0; if (order == CblasColMajor) { if (Side == CblasLeft) side = 0; if (Side == CblasRight) side = 1; if (Uplo == CblasUpper) uplo = 0; if (Uplo == CblasLower) uplo = 1; info = -1; args.m = m; args.n = n; if (args.ldc < MAX(1, args.m)) info = 12; if (!side) { args.a = (void *)a; args.b = (void *)b; args.lda = lda; args.ldb = ldb; if (args.ldb < MAX(1, args.m)) info = 9; if (args.lda < MAX(1, args.m)) info = 7; } else { args.a = (void *)b; args.b = (void *)a; args.lda = ldb; args.ldb = lda; if (args.lda < MAX(1, args.m)) info = 9; if (args.ldb < MAX(1, args.n)) info = 7; } if (args.n < 0) info = 4; if (args.m < 0) info = 3; if (uplo < 0) info = 2; if (side < 0) info = 1; } if (order == CblasRowMajor) { if (Side == CblasLeft) side = 1; if (Side == CblasRight) side = 0; if (Uplo == CblasUpper) uplo = 1; if (Uplo == CblasLower) uplo = 0; info = -1; args.m = n; args.n = m; if (args.ldc < MAX(1, args.m)) info = 12; if (!side) { args.a = (void *)a; args.b = (void *)b; args.lda = lda; args.ldb = ldb; if (args.ldb < MAX(1, args.m)) info = 9; if (args.lda < MAX(1, args.m)) info = 7; } else { args.a = (void *)b; args.b = (void *)a; args.lda = ldb; args.ldb = lda; if (args.lda < MAX(1, args.m)) info = 9; if (args.ldb < MAX(1, args.n)) info = 7; } if (args.n < 0) info = 4; if (args.m < 0) info = 3; if (uplo < 0) info = 2; if (side < 0) info = 1; } if (info >= 0) { BLASFUNC(xerbla)(ERROR_NAME, &info, sizeof(ERROR_NAME)); return; } #endif if (args.m == 0 || args.n == 0) return; IDEBUG_START; FUNCTION_PROFILE_START(); buffer = (FLOAT *)blas_memory_alloc(0); sa = (FLOAT *)((BLASLONG)buffer + GEMM_OFFSET_A); sb = (FLOAT *)(((BLASLONG)sa + ((GEMM_P * GEMM_Q * COMPSIZE * SIZE + GEMM_ALIGN) & ~GEMM_ALIGN)) + GEMM_OFFSET_B); #ifdef SMP args.common = NULL; args.nthreads = num_cpu_avail(3); if (args.nthreads == 1) { #endif (symm[(side << 1) | uplo ])(&args, NULL, NULL, sa, sb, 0); #ifdef SMP } else { #ifndef NO_AFFINITY nodes = get_num_nodes(); if (nodes > 1) { args.nthreads /= nodes; gemm_thread_mn(mode, &args, NULL, NULL, symm[4 | (side << 1) | uplo ], sa, sb, nodes); } else { #endif #ifndef USE_SIMPLE_THREADED_LEVEL3 (symm[4 | (side << 1) | uplo ])(&args, NULL, NULL, sa, sb, 0); #else GEMM_THREAD(mode, &args, NULL, NULL, symm[(side << 1) | uplo ], sa, sb, args.nthreads); #endif #ifndef NO_AFFINITY } #endif } #endif blas_memory_free(buffer); FUNCTION_PROFILE_END(COMPSIZE * COMPSIZE, (!side)? args.m * (args.m / 2 + args.n) : args.n * (args.m + args.n / 2), (!side)? 2 * args.m * args.m * args.n : 2 * args.m * args.n * args.n); IDEBUG_END; return; }