/* ************************************************************************ * Copyright 2016-2021 Advanced Micro Devices, Inc. * * ************************************************************************ */ #include #include #include #include "testing_common.hpp" using namespace std; /* ============================================================================================ */ template hipblasStatus_t testing_axpy_batched_ex_template(const Arguments& argus) { bool FORTRAN = argus.fortran; auto hipblasAxpyBatchedExFn = FORTRAN ? hipblasAxpyBatchedExFortran : hipblasAxpyBatchedEx; int N = argus.N; int incx = argus.incx; int incy = argus.incy; int batch_count = argus.batch_count; hipblasDatatype_t alphaType = argus.a_type; hipblasDatatype_t xType = argus.b_type; hipblasDatatype_t yType = argus.c_type; hipblasDatatype_t executionType = argus.compute_type; hipblasLocalHandle handle(argus); // argument sanity check, quick return if input parameters are invalid before allocating invalid // memory if(N <= 0 || batch_count <= 0) { CHECK_HIPBLAS_ERROR(hipblasAxpyBatchedExFn(handle, N, nullptr, alphaType, nullptr, xType, incx, nullptr, yType, incy, batch_count, executionType)); return HIPBLAS_STATUS_SUCCESS; } int abs_incy = incy < 0 ? -incy : incy; Ta h_alpha = argus.get_alpha(); // Naming: dX is in GPU (device) memory. hK is in CPU (host) memory, plz follow this practice host_batch_vector hx(N, incx, batch_count); host_batch_vector hy_host(N, incy, batch_count); host_batch_vector hy_device(N, incy, batch_count); host_batch_vector hy_cpu(N, incy, batch_count); device_batch_vector dx(N, incx, batch_count); device_batch_vector dy(N, incy, batch_count); device_vector d_alpha(1); CHECK_HIP_ERROR(dx.memcheck()); CHECK_HIP_ERROR(dy.memcheck()); double gpu_time_used, hipblas_error_host, hipblas_error_device; // Initial Data on CPU hipblas_init(hx, true); hipblas_init(hy_host); hy_device.copy_from(hy_host); hy_cpu.copy_from(hy_host); CHECK_HIP_ERROR(dx.transfer_from(hx)); CHECK_HIP_ERROR(dy.transfer_from(hy_host)); CHECK_HIP_ERROR(hipMemcpy(d_alpha, &h_alpha, sizeof(Ta), hipMemcpyHostToDevice)); /* ===================================================================== HIPBLAS =================================================================== */ CHECK_HIPBLAS_ERROR(hipblasSetPointerMode(handle, HIPBLAS_POINTER_MODE_HOST)); CHECK_HIPBLAS_ERROR(hipblasAxpyBatchedExFn(handle, N, &h_alpha, alphaType, dx.ptr_on_device(), xType, incx, dy.ptr_on_device(), yType, incy, batch_count, executionType)); CHECK_HIP_ERROR(hy_host.transfer_from(dy)); CHECK_HIP_ERROR(dy.transfer_from(hy_device)); CHECK_HIPBLAS_ERROR(hipblasSetPointerMode(handle, HIPBLAS_POINTER_MODE_DEVICE)); CHECK_HIPBLAS_ERROR(hipblasAxpyBatchedExFn(handle, N, d_alpha, alphaType, dx.ptr_on_device(), xType, incx, dy.ptr_on_device(), yType, incy, batch_count, executionType)); CHECK_HIP_ERROR(hy_device.transfer_from(dy)); if(argus.unit_check || argus.norm_check) { /* ===================================================================== CPU BLAS =================================================================== */ for(int b = 0; b < batch_count; b++) { cblas_axpy(N, h_alpha, hx[b], incx, hy_cpu[b], 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, batch_count, abs_incy, hy_cpu, hy_host); unit_check_general(1, N, batch_count, abs_incy, hy_cpu, hy_device); } if(argus.norm_check) { hipblas_error_host = norm_check_general('F', 1, N, abs_incy, hy_cpu, hy_host, batch_count); hipblas_error_device = norm_check_general('F', 1, N, abs_incy, hy_cpu, hy_device, batch_count); } } // end of if unit check if(argus.timing) { hipStream_t stream; CHECK_HIPBLAS_ERROR(hipblasGetStream(handle, &stream)); CHECK_HIPBLAS_ERROR(hipblasSetPointerMode(handle, HIPBLAS_POINTER_MODE_DEVICE)); int runs = argus.cold_iters + argus.iters; for(int iter = 0; iter < runs; iter++) { if(iter == argus.cold_iters) gpu_time_used = get_time_us_sync(stream); CHECK_HIPBLAS_ERROR(hipblasAxpyBatchedExFn(handle, N, d_alpha, alphaType, dx.ptr_on_device(), xType, incx, dy.ptr_on_device(), yType, incy, batch_count, executionType)); } gpu_time_used = get_time_us_sync(stream) - gpu_time_used; ArgumentModel{}.log_args(std::cout, argus, gpu_time_used, axpy_gflop_count(N), axpy_gbyte_count(N), hipblas_error_host, hipblas_error_device); } return HIPBLAS_STATUS_SUCCESS; } hipblasStatus_t testing_axpy_batched_ex(Arguments argus) { hipblasDatatype_t alphaType = argus.a_type; hipblasDatatype_t xType = argus.b_type; hipblasDatatype_t yType = argus.c_type; hipblasDatatype_t executionType = argus.compute_type; hipblasStatus_t status = HIPBLAS_STATUS_SUCCESS; if(alphaType == HIPBLAS_R_16F && xType == HIPBLAS_R_16F && yType == HIPBLAS_R_16F && executionType == HIPBLAS_R_16F) { status = testing_axpy_batched_ex_template(argus); } else if(alphaType == HIPBLAS_R_16F && xType == HIPBLAS_R_16F && yType == HIPBLAS_R_16F && executionType == HIPBLAS_R_32F) { // Not testing accumulation here status = testing_axpy_batched_ex_template(argus); } else if(alphaType == HIPBLAS_R_32F && xType == HIPBLAS_R_16F && yType == HIPBLAS_R_16F && executionType == HIPBLAS_R_32F) { // Not testing accumulation here status = testing_axpy_batched_ex_template(argus); } else if(alphaType == HIPBLAS_R_32F && xType == HIPBLAS_R_32F && yType == HIPBLAS_R_32F && executionType == HIPBLAS_R_32F) { status = testing_axpy_batched_ex_template(argus); } else if(alphaType == HIPBLAS_R_64F && xType == HIPBLAS_R_64F && yType == HIPBLAS_R_64F && executionType == HIPBLAS_R_64F) { status = testing_axpy_batched_ex_template(argus); } else if(alphaType == HIPBLAS_C_32F && xType == HIPBLAS_C_32F && yType == HIPBLAS_C_32F && executionType == HIPBLAS_C_32F) { status = testing_axpy_batched_ex_template(argus); } else if(alphaType == HIPBLAS_C_64F && xType == HIPBLAS_C_64F && yType == HIPBLAS_C_64F && executionType == HIPBLAS_C_64F) { status = testing_axpy_batched_ex_template(argus); } else { status = HIPBLAS_STATUS_NOT_SUPPORTED; } return status; }