/* ************************************************************************ * Copyright 2016 Advanced Micro Devices, Inc. * * ************************************************************************ */ #include #include #include #include #include "cblas_interface.h" #include "flops.h" #include "hipblas.hpp" #include "norm.h" #include "unit.h" #include "utility.h" using namespace std; /* ============================================================================================ */ template hipblasStatus_t testing_symv(Arguments argus) { int N = argus.N; int lda = argus.lda; int incx = argus.incx; int incy = argus.incy; int A_size = lda * N; int X_size = N * incx; int Y_size = N * incy; hipblasStatus_t status = HIPBLAS_STATUS_SUCCESS; // argument sanity check, quick return if input parameters are invalid before allocating invalid // memory if(N < 0) { status = HIPBLAS_STATUS_INVALID_VALUE; return status; } else if(lda < 0) { status = HIPBLAS_STATUS_INVALID_VALUE; return status; } else if(incx < 0) { status = HIPBLAS_STATUS_INVALID_VALUE; return status; } // Naming: dK is in GPU (device) memory. hK is in CPU (host) memory vector hA(A_size); vector hx(X_size); vector hy(Y_size); vector hz(Y_size); T *dA, *dx, *dy; double gpu_time_used, cpu_time_used; double hipblasGflops, cblas_gflops; double rocblas_error; T alpha = (T)argus.alpha; T beta = (T)argus.beta; hipblasHandle_t handle; char char_fill = argus.uplo_option; hipblasFillMode_t uplo = char2hipblasFillMode_t(char_fill); hipblasCreate(&handle); // allocate memory on device CHECK_HIP_ERROR(hipMalloc(&dA, A_size * sizeof(T))); CHECK_HIP_ERROR(hipMalloc(&dx, X_size * sizeof(T))); CHECK_HIP_ERROR(hipMalloc(&dy, Y_size * sizeof(T))); // Initial Data on CPU srand(1); hipblas_init_symmetric(hA, N, lda); hipblas_init(hx, 1, N, incx); hipblas_init(hy, 1, N, incy); // copy vector is easy in STL; hz = hy: save a copy in hz which will be output of CPU BLAS hz = hy; // copy data from CPU to device hipMemcpy(dA, hA.data(), sizeof(T) * lda * N, hipMemcpyHostToDevice); hipMemcpy(dx, hx.data(), sizeof(T) * N * incx, hipMemcpyHostToDevice); hipMemcpy(dy, hy.data(), sizeof(T) * N * incy, hipMemcpyHostToDevice); /* ===================================================================== ROCBLAS =================================================================== */ for(int iter = 0; iter < 1; iter++) { status = hipblasSymv(handle, uplo, N, (T*)&alpha, dA, lda, dx, incx, (T*)&beta, dy, incy); if(status != HIPBLAS_STATUS_SUCCESS) { CHECK_HIP_ERROR(hipFree(dA)); CHECK_HIP_ERROR(hipFree(dx)); CHECK_HIP_ERROR(hipFree(dy)); hipblasDestroy(handle); return status; } } // copy output from device to CPU hipMemcpy(hy.data(), dy, sizeof(T) * N * incy, hipMemcpyDeviceToHost); if(argus.unit_check) { /* ===================================================================== CPU BLAS =================================================================== */ cblas_symv(uplo, N, alpha, hA.data(), lda, hx.data(), incx, beta, hz.data(), incy); // enable unit check, notice unit check is not invasive, but norm check is, // unit check and norm check can not be interchanged their order if(argus.unit_check) { unit_check_general(1, N, incy, hz.data(), hy.data()); } for(int i = 0; i < 32; i++) { printf("CPU[%d]=%f, GPU[%d]=%f\n", i, hz[i], i, hy[i]); } } CHECK_HIP_ERROR(hipFree(dA)); CHECK_HIP_ERROR(hipFree(dx)); CHECK_HIP_ERROR(hipFree(dy)); hipblasDestroy(handle); return HIPBLAS_STATUS_SUCCESS; }