/* Parallel Sparse BLAS GPU plugin */ /* (C) Copyright 2013 */ /* Salvatore Filippone */ /* Alessandro Fanfarillo */ /* 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. */ /* 3. The name of the PSBLAS group or the names of its contributors may */ /* not be used to endorse or promote products derived from this */ /* software without specific written permission. */ /* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS */ /* ``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 PSBLAS GROUP OR ITS 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. */ #include #include "dnsdev.h" #if defined(HAVE_SPGPU) #define PASS_RS 0 #define IMIN(a,b) ((a)<(b) ? (a) : (b)) DnsDeviceParams getDnsDeviceParams(unsigned int rows, unsigned int columns, unsigned int elementType, unsigned int firstIndex) { DnsDeviceParams params; if (elementType == SPGPU_TYPE_DOUBLE) { params.pitch = ((rows + ELL_PITCH_ALIGN_D - 1)/ELL_PITCH_ALIGN_D)*ELL_PITCH_ALIGN_D; } else { params.pitch = ((rows + ELL_PITCH_ALIGN_S - 1)/ELL_PITCH_ALIGN_S)*ELL_PITCH_ALIGN_S; } //For complex? params.elementType = elementType; params.rows = rows; params.columns = columns; params.firstIndex = firstIndex; return params; } //new int allocDnsDevice(void ** remoteMatrix, DnsDeviceParams* params) { struct DnsDevice *tmp = (struct DnsDevice *)malloc(sizeof(struct DnsDevice)); *remoteMatrix = (void *)tmp; tmp->rows = params->rows; tmp->columns = params->columns; tmp->cMPitch = params->pitch; tmp->pitch= tmp->cMPitch; tmp->allocsize = (int)tmp->columns * tmp->pitch; tmp->baseIndex = params->firstIndex; //fprintf(stderr,"allocDnsDevice: %d %d %d \n",tmp->pitch, params->maxRowSize, params->avgRowSize); if (params->elementType == SPGPU_TYPE_FLOAT) allocRemoteBuffer((void **)&(tmp->cM), tmp->allocsize*sizeof(float)); else if (params->elementType == SPGPU_TYPE_DOUBLE) allocRemoteBuffer((void **)&(tmp->cM), tmp->allocsize*sizeof(double)); else if (params->elementType == SPGPU_TYPE_COMPLEX_FLOAT) allocRemoteBuffer((void **)&(tmp->cM), tmp->allocsize*sizeof(cuFloatComplex)); else if (params->elementType == SPGPU_TYPE_COMPLEX_DOUBLE) allocRemoteBuffer((void **)&(tmp->cM), tmp->allocsize*sizeof(cuDoubleComplex)); else return SPGPU_UNSUPPORTED; // Unsupported params //fprintf(stderr,"From allocDnsDevice: %d %d %d %p %p %p\n",tmp->maxRowSize, // tmp->avgRowSize,tmp->allocsize,tmp->rS,tmp->rP,tmp->cM); return SPGPU_SUCCESS; } void freeDnsDevice(void* remoteMatrix) { struct DnsDevice *devMat = (struct DnsDevice *) remoteMatrix; //fprintf(stderr,"freeDnsDevice\n"); if (devMat != NULL) { freeRemoteBuffer(devMat->cM); free(remoteMatrix); } } //new int FallocDnsDevice(void** deviceMat, unsigned int rows, unsigned int columns, unsigned int elementType, unsigned int firstIndex) { int i; #ifdef HAVE_SPGPU DnsDeviceParams p; p = getDnsDeviceParams(rows, columns, elementType, firstIndex); i = allocDnsDevice(deviceMat, &p); if (i != 0) { fprintf(stderr,"From routine : %s : %d \n","FallocDnsDevice",i); } return(i); #else return SPGPU_UNSUPPORTED; #endif } int spmvDnsDeviceFloat(char transa, int m, int n, int k, float *alpha, void *deviceMat, void* deviceX, float *beta, void* deviceY) { struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; struct MultiVectDevice *x = (struct MultiVectDevice *) deviceX; struct MultiVectDevice *y = (struct MultiVectDevice *) deviceY; int status; #ifdef HAVE_SPGPU cublasHandle_t handle=psb_cudaGetCublasHandle(); cublasOperation_t trans=((transa == 'N')? CUBLAS_OP_N:((transa=='T')? CUBLAS_OP_T:CUBLAS_OP_C)); /* Note: the M,N,K choices according to TRANS have already been handled in the caller */ if (n == 1) { status = cublasSgemv(handle, trans, m,k, alpha, devMat->cM,devMat->pitch, x->v_,1, beta, y->v_,1); } else { status = cublasSgemm(handle, trans, CUBLAS_OP_N, m,n,k, alpha, devMat->cM,devMat->pitch, x->v_,x->pitch_, beta, y->v_,y->pitch_); } if (status == CUBLAS_STATUS_SUCCESS) return SPGPU_SUCCESS; else return SPGPU_UNSUPPORTED; #else return SPGPU_UNSUPPORTED; #endif } int spmvDnsDeviceDouble(char transa, int m, int n, int k, double *alpha, void *deviceMat, void* deviceX, double *beta, void* deviceY) { struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; struct MultiVectDevice *x = (struct MultiVectDevice *) deviceX; struct MultiVectDevice *y = (struct MultiVectDevice *) deviceY; int status; #ifdef HAVE_SPGPU cublasHandle_t handle=psb_cudaGetCublasHandle(); cublasOperation_t trans=((transa == 'N')? CUBLAS_OP_N:((transa=='T')? CUBLAS_OP_T:CUBLAS_OP_C)); /* Note: the M,N,K choices according to TRANS have already been handled in the caller */ if (n == 1) { status = cublasDgemv(handle, trans, m,k, alpha, devMat->cM,devMat->pitch, x->v_,1, beta, y->v_,1); } else { status = cublasDgemm(handle, trans, CUBLAS_OP_N, m,n,k, alpha, devMat->cM,devMat->pitch, x->v_,x->pitch_, beta, y->v_,y->pitch_); } if (status == CUBLAS_STATUS_SUCCESS) return SPGPU_SUCCESS; else return SPGPU_UNSUPPORTED; #else return SPGPU_UNSUPPORTED; #endif } int spmvDnsDeviceFloatComplex(char transa, int m, int n, int k, float complex *alpha, void *deviceMat, void* deviceX, float complex *beta, void* deviceY) { struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; struct MultiVectDevice *x = (struct MultiVectDevice *) deviceX; struct MultiVectDevice *y = (struct MultiVectDevice *) deviceY; int status; #ifdef HAVE_SPGPU cublasHandle_t handle=psb_cudaGetCublasHandle(); cublasOperation_t trans=((transa == 'N')? CUBLAS_OP_N:((transa=='T')? CUBLAS_OP_T:CUBLAS_OP_C)); /* Note: the M,N,K choices according to TRANS have already been handled in the caller */ if (n == 1) { status = cublasCgemv(handle, trans, m,k, alpha, devMat->cM,devMat->pitch, x->v_,1, beta, y->v_,1); } else { status = cublasCgemm(handle, trans, CUBLAS_OP_N, m,n,k, alpha, devMat->cM,devMat->pitch, x->v_,x->pitch_, beta, y->v_,y->pitch_); } if (status == CUBLAS_STATUS_SUCCESS) return SPGPU_SUCCESS; else return SPGPU_UNSUPPORTED; #else return SPGPU_UNSUPPORTED; #endif } int spmvDnsDeviceDoubleComplex(char transa, int m, int n, int k, double complex *alpha, void *deviceMat, void* deviceX, double complex *beta, void* deviceY) { struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; struct MultiVectDevice *x = (struct MultiVectDevice *) deviceX; struct MultiVectDevice *y = (struct MultiVectDevice *) deviceY; int status; #ifdef HAVE_SPGPU cublasHandle_t handle=psb_cudaGetCublasHandle(); cublasOperation_t trans=((transa == 'N')? CUBLAS_OP_N:((transa=='T')? CUBLAS_OP_T:CUBLAS_OP_C)); /* Note: the M,N,K choices according to TRANS have already been handled in the caller */ if (n == 1) { status = cublasZgemv(handle, trans, m,k, alpha, devMat->cM,devMat->pitch, x->v_,1, beta, y->v_,1); } else { status = cublasZgemm(handle, trans, CUBLAS_OP_N, m,n,k, alpha, devMat->cM,devMat->pitch, x->v_,x->pitch_, beta, y->v_,y->pitch_); } if (status == CUBLAS_STATUS_SUCCESS) return SPGPU_SUCCESS; else return SPGPU_UNSUPPORTED; #else return SPGPU_UNSUPPORTED; #endif } int writeDnsDeviceFloat(void* deviceMat, float* val, int lda, int nc) { int i; #ifdef HAVE_SPGPU struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; int pitch=devMat->pitch; i = cublasSetMatrix(lda,nc,sizeof(float), (void*) val,lda, (void *)devMat->cM, pitch); if (i != 0) { fprintf(stderr,"From routine : %s : %d \n","writeDnsDeviceFloat",i); } return SPGPU_SUCCESS; #else return SPGPU_UNSUPPORTED; #endif } int writeDnsDeviceDouble(void* deviceMat, double* val, int lda, int nc) { int i; #ifdef HAVE_SPGPU struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; int pitch=devMat->pitch; i = cublasSetMatrix(lda,nc,sizeof(double), (void*) val,lda, (void *)devMat->cM, pitch); if (i != 0) { fprintf(stderr,"From routine : %s : %d \n","writeDnsDeviceDouble",i); } return SPGPU_SUCCESS; #else return SPGPU_UNSUPPORTED; #endif } int writeDnsDeviceFloatComplex(void* deviceMat, float complex* val, int lda, int nc) { int i; #ifdef HAVE_SPGPU struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; int pitch=devMat->pitch; i = cublasSetMatrix(lda,nc,sizeof(cuFloatComplex), (void*) val,lda, (void *)devMat->cM, pitch); if (i != 0) { fprintf(stderr,"From routine : %s : %d \n","writeDnsDeviceFloatComplex",i); } return SPGPU_SUCCESS; #else return SPGPU_UNSUPPORTED; #endif } int writeDnsDeviceDoubleComplex(void* deviceMat, double complex* val, int lda, int nc) { int i; #ifdef HAVE_SPGPU struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; int pitch=devMat->pitch; i = cublasSetMatrix(lda,nc,sizeof(cuDoubleComplex), (void*) val,lda, (void *)devMat->cM, pitch); if (i != 0) { fprintf(stderr,"From routine : %s : %d \n","writeDnsDeviceDoubleComplex",i); } return SPGPU_SUCCESS; #else return SPGPU_UNSUPPORTED; #endif } int readDnsDeviceFloat(void* deviceMat, float* val, int lda, int nc) { int i; #ifdef HAVE_SPGPU struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; int pitch=devMat->pitch; i = cublasGetMatrix(lda,nc,sizeof(float), (void*) val,lda, (void *)devMat->cM, pitch); if (i != 0) { fprintf(stderr,"From routine : %s : %d \n","readDnsDeviceFloat",i); } return SPGPU_SUCCESS; #else return SPGPU_UNSUPPORTED; #endif } int readDnsDeviceDouble(void* deviceMat, double* val, int lda, int nc) { int i; #ifdef HAVE_SPGPU struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; int pitch=devMat->pitch; i = cublasGetMatrix(lda,nc,sizeof(double), (void*) val,lda, (void *)devMat->cM, pitch); if (i != 0) { fprintf(stderr,"From routine : %s : %d \n","readDnsDeviceDouble",i); } return SPGPU_SUCCESS; #else return SPGPU_UNSUPPORTED; #endif } int readDnsDeviceFloatComplex(void* deviceMat, float complex* val, int lda, int nc) { int i; #ifdef HAVE_SPGPU struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; int pitch=devMat->pitch; i = cublasGetMatrix(lda,nc,sizeof(cuFloatComplex), (void*) val,lda, (void *)devMat->cM, pitch); if (i != 0) { fprintf(stderr,"From routine : %s : %d \n","readDnsDeviceFloatComplex",i); } return SPGPU_SUCCESS; #else return SPGPU_UNSUPPORTED; #endif } int readDnsDeviceDoubleComplex(void* deviceMat, double complex* val, int lda, int nc) { int i; #ifdef HAVE_SPGPU struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; int pitch=devMat->pitch; i = cublasGetMatrix(lda,nc,sizeof(cuDoubleComplex), (void*) val,lda, (void *)devMat->cM, pitch); if (i != 0) { fprintf(stderr,"From routine : %s : %d \n","readDnsDeviceDoubleComplex",i); } return SPGPU_SUCCESS; #else return SPGPU_UNSUPPORTED; #endif } int getDnsDevicePitch(void* deviceMat) { int i; struct DnsDevice *devMat = (struct DnsDevice *) deviceMat; #ifdef HAVE_SPGPU i = devMat->pitch; return(i); #else return SPGPU_UNSUPPORTED; #endif } #endif