int gpu_index = 0; #ifdef GPU #include "cuda.h" #include "utils.h" #include "blas.h" #include "assert.h" #include #include void cuda_set_device(int n) { gpu_index = n; cudaError_t status = cudaSetDevice(n); check_error(status); } int cuda_get_device() { int n = 0; cudaError_t status = cudaGetDevice(&n); check_error(status); return n; } void check_error(cudaError_t status) { //cudaDeviceSynchronize(); cudaError_t status2 = cudaGetLastError(); if (status != cudaSuccess) { const char *s = cudaGetErrorString(status); char buffer[256]; printf("CUDA Error: %s\n", s); assert(0); snprintf(buffer, 256, "CUDA Error: %s", s); error(buffer); } if (status2 != cudaSuccess) { const char *s = cudaGetErrorString(status); char buffer[256]; printf("CUDA Error Prev: %s\n", s); assert(0); snprintf(buffer, 256, "CUDA Error Prev: %s", s); error(buffer); } } dim3 cuda_gridsize(size_t n){ size_t k = (n-1) / BLOCK + 1; size_t x = k; size_t y = 1; if(x > 65535){ x = ceil(sqrt(k)); y = (n-1)/(x*BLOCK) + 1; } dim3 d = {x, y, 1}; //printf("%ld %ld %ld %ld\n", n, x, y, x*y*BLOCK); return d; } static cudaStream_t streamsArray[16]; // cudaStreamSynchronize( get_cuda_stream() ); static int streamInit[16] = { 0 }; cudaStream_t get_cuda_stream() { int i = cuda_get_device(); if (!streamInit[i]) { cudaStreamCreate(&streamsArray[i]); streamInit[i] = 1; } return streamsArray[i]; } #ifdef CUDNN cudnnHandle_t cudnn_handle() { static int init[16] = {0}; static cudnnHandle_t handle[16]; int i = cuda_get_device(); if(!init[i]) { cudnnCreate(&handle[i]); init[i] = 1; cudnnStatus_t status = cudnnSetStream(handle[i], get_cuda_stream()); } return handle[i]; } #endif cublasHandle_t blas_handle() { static int init[16] = {0}; static cublasHandle_t handle[16]; int i = cuda_get_device(); if(!init[i]) { cublasCreate(&handle[i]); cublasStatus_t status = cublasSetStream(handle[i], get_cuda_stream()); init[i] = 1; } return handle[i]; } float *cuda_make_array(float *x, size_t n) { float *x_gpu; size_t size = sizeof(float)*n; cudaError_t status = cudaMalloc((void **)&x_gpu, size); check_error(status); if(x){ //status = cudaMemcpy(x_gpu, x, size, cudaMemcpyHostToDevice); status = cudaMemcpyAsync(x_gpu, x, size, cudaMemcpyHostToDevice, get_cuda_stream()); check_error(status); } if(!x_gpu) error("Cuda malloc failed\n"); return x_gpu; } void cuda_random(float *x_gpu, size_t n) { static curandGenerator_t gen[16]; static int init[16] = {0}; int i = cuda_get_device(); if(!init[i]){ curandCreateGenerator(&gen[i], CURAND_RNG_PSEUDO_DEFAULT); curandSetPseudoRandomGeneratorSeed(gen[i], time(0)); init[i] = 1; } curandGenerateUniform(gen[i], x_gpu, n); check_error(cudaPeekAtLastError()); } float cuda_compare(float *x_gpu, float *x, size_t n, char *s) { float *tmp = calloc(n, sizeof(float)); cuda_pull_array(x_gpu, tmp, n); //int i; //for(i = 0; i < n; ++i) printf("%f %f\n", tmp[i], x[i]); axpy_cpu(n, -1, x, 1, tmp, 1); float err = dot_cpu(n, tmp, 1, tmp, 1); printf("Error %s: %f\n", s, sqrt(err/n)); free(tmp); return err; } int *cuda_make_int_array(size_t n) { int *x_gpu; size_t size = sizeof(int)*n; cudaError_t status = cudaMalloc((void **)&x_gpu, size); check_error(status); return x_gpu; } void cuda_free(float *x_gpu) { //cudaStreamSynchronize(get_cuda_stream()); cudaError_t status = cudaFree(x_gpu); check_error(status); } void cuda_push_array(float *x_gpu, float *x, size_t n) { size_t size = sizeof(float)*n; //cudaError_t status = cudaMemcpy(x_gpu, x, size, cudaMemcpyHostToDevice); cudaError_t status = cudaMemcpyAsync(x_gpu, x, size, cudaMemcpyHostToDevice, get_cuda_stream()); check_error(status); } void cuda_pull_array(float *x_gpu, float *x, size_t n) { size_t size = sizeof(float)*n; //cudaError_t status = cudaMemcpy(x, x_gpu, size, cudaMemcpyDeviceToHost); cudaError_t status = cudaMemcpyAsync(x, x_gpu, size, cudaMemcpyDeviceToHost, get_cuda_stream()); check_error(status); cudaStreamSynchronize(get_cuda_stream()); } #else // GPU #include "cuda.h" void cuda_set_device(int n) {} #endif // GPU