/* ************************************************************************ * Copyright 2018-2021 Advanced Micro Devices, Inc. * ************************************************************************ */ #pragma once #include "bytes.hpp" #include "cblas_interface.hpp" #include "flops.hpp" #include "norm.hpp" #include "rocblas.hpp" #include "rocblas_init.hpp" #include "rocblas_math.hpp" #include "rocblas_random.hpp" #include "rocblas_test.hpp" #include "rocblas_vector.hpp" #include "type_dispatch.hpp" #include "unit.hpp" #include "utility.hpp" /* ============================================================================================ */ template void testing_axpy_strided_batched_ex_bad_arg(const Arguments& arg) { auto rocblas_axpy_strided_batched_ex_fn = arg.fortran ? rocblas_axpy_strided_batched_ex_fortran : rocblas_axpy_strided_batched_ex; rocblas_datatype alpha_type = rocblas_type2datatype(); rocblas_datatype x_type = rocblas_type2datatype(); rocblas_datatype y_type = rocblas_type2datatype(); rocblas_datatype execution_type = rocblas_type2datatype(); rocblas_local_handle handle{arg}; rocblas_int N = 100, incx = 1, incy = 1, batch_count = 2; rocblas_stride stridex = arg.stride_x, stridey = arg.stride_y; Ta alpha(0.6); device_strided_batch_vector dx(10, 1, 10, 2); device_strided_batch_vector dy(10, 1, 10, 2); CHECK_DEVICE_ALLOCATION(dx.memcheck()); CHECK_DEVICE_ALLOCATION(dy.memcheck()); #ifdef GOOGLE_TEST rocblas_status status; status = rocblas_axpy_strided_batched_ex_fn(handle, N, &alpha, alpha_type, nullptr, x_type, incx, stridex, dy, y_type, incy, stridey, batch_count, execution_type); EXPECT_TRUE(status == rocblas_status_invalid_pointer || status == rocblas_status_not_implemented); status = rocblas_axpy_strided_batched_ex_fn(handle, N, &alpha, alpha_type, dx, x_type, incx, stridex, nullptr, y_type, incy, stridey, batch_count, execution_type); EXPECT_TRUE(status == rocblas_status_invalid_pointer || status == rocblas_status_not_implemented); status = rocblas_axpy_strided_batched_ex_fn(handle, N, nullptr, alpha_type, dx, x_type, incx, stridex, dy, y_type, incy, stridey, batch_count, execution_type); EXPECT_TRUE(status == rocblas_status_invalid_pointer || status == rocblas_status_not_implemented); #endif EXPECT_ROCBLAS_STATUS(rocblas_axpy_strided_batched_ex_fn(nullptr, N, &alpha, alpha_type, dx, x_type, incx, stridex, dy, y_type, incy, stridey, batch_count, execution_type), rocblas_status_invalid_handle); } template void testing_axpy_strided_batched_ex(const Arguments& arg) { auto rocblas_axpy_strided_batched_ex_fn = arg.fortran ? rocblas_axpy_strided_batched_ex_fortran : rocblas_axpy_strided_batched_ex; rocblas_datatype alpha_type = arg.a_type; rocblas_datatype x_type = arg.b_type; rocblas_datatype y_type = arg.c_type; rocblas_datatype execution_type = arg.compute_type; rocblas_int N = arg.N, incx = arg.incx, incy = arg.incy, batch_count = arg.batch_count; rocblas_stride stridex = arg.stride_x, stridey = arg.stride_y; if(!stridex) stridex = N; if(!stridey) stridey = N; Ta h_alpha = arg.get_alpha(); Tex h_alpha_ex = (Tex)h_alpha; rocblas_local_handle handle{arg}; // argument sanity check before allocating invalid memory if(N <= 0 || batch_count <= 0) { CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_host)); EXPECT_ROCBLAS_STATUS(rocblas_axpy_strided_batched_ex_fn(handle, N, nullptr, alpha_type, nullptr, x_type, incx, stridex, nullptr, y_type, incy, stridey, batch_count, execution_type), rocblas_status_success); return; } rocblas_int abs_incx = std::abs(incx); rocblas_int abs_incy = std::abs(incy); size_t size_x = abs_incx ? N * abs_incx : N; size_t size_y = abs_incy ? N * abs_incy : N; // // Host memory. // host_strided_batch_vector hx(N, incx ? incx : 1, stridex, batch_count); host_strided_batch_vector hy(N, incy ? incy : 1, stridey, batch_count), hy1(N, incy ? incy : 1, stridey, batch_count), hy2(N, incy ? incy : 1, stridey, batch_count); host_strided_batch_vector hx_ex(N, incx ? incx : 1, stridex, batch_count); host_strided_batch_vector hy_ex(N, incy ? incy : 1, stridey, batch_count); host_vector halpha(1); CHECK_HIP_ERROR(hx.memcheck()); CHECK_HIP_ERROR(hy.memcheck()); CHECK_HIP_ERROR(hy1.memcheck()); CHECK_HIP_ERROR(hy2.memcheck()); CHECK_HIP_ERROR(halpha.memcheck()); device_strided_batch_vector dx(N, incx ? incx : 1, stridex, batch_count); device_strided_batch_vector dy(N, incy ? incy : 1, stridey, batch_count); device_vector dalpha(1); CHECK_DEVICE_ALLOCATION(dx.memcheck()); CHECK_DEVICE_ALLOCATION(dy.memcheck()); CHECK_DEVICE_ALLOCATION(dalpha.memcheck()); halpha[0] = h_alpha; // // Initialize host memory. // if(rocblas_isnan(arg.alpha)) { rocblas_init_nan(hx, true); rocblas_init_nan(hy, false); } else { rocblas_init(hx, true); rocblas_init(hy, false); } for(rocblas_int b = 0; b < batch_count; b++) { for(int i = 0; i < size_y; i++) hy_ex[b][i] = (Tex)hy[b][i]; for(size_t i = 0; i < size_x; i++) hx_ex[b][i] = (Tex)hx[b][i]; } // // Device memory. // double gpu_time_used, cpu_time_used; double rocblas_error_1 = 0.0; double rocblas_error_2 = 0.0; if(arg.unit_check || arg.norm_check) { // // Transfer host to device // CHECK_HIP_ERROR(dx.transfer_from(hx)); // // Call routine with pointer mode on host. // { // // Pointer mode. // CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_host)); // // Transfer host to device // CHECK_HIP_ERROR(dy.transfer_from(hy)); // // Call routine. // CHECK_ROCBLAS_ERROR(rocblas_axpy_strided_batched_ex_fn(handle, N, halpha, alpha_type, dx, x_type, incx, stridex, dy, y_type, incy, stridey, batch_count, execution_type)); CHECK_HIP_ERROR(hy1.transfer_from(dy)); // // Pointer mode. // CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_device)); // // Transfer host to device // CHECK_HIP_ERROR(dy.transfer_from(hy)); CHECK_HIP_ERROR(dalpha.transfer_from(halpha)); // // Call routine. // CHECK_ROCBLAS_ERROR(rocblas_axpy_strided_batched_ex_fn(handle, N, dalpha, alpha_type, dx, x_type, incx, stridex, dy, y_type, incy, stridey, batch_count, execution_type)); // // Transfer from device to host. // CHECK_HIP_ERROR(hy2.transfer_from(dy)); // // CPU BLAS // { cpu_time_used = get_time_us_no_sync(); // // Compute the host solution. // for(rocblas_int batch_index = 0; batch_index < batch_count; ++batch_index) { cblas_axpy( N, h_alpha_ex, hx_ex[batch_index], incx, hy_ex[batch_index], incy); } cpu_time_used = get_time_us_no_sync() - cpu_time_used; for(rocblas_int b = 0; b < batch_count; b++) { for(size_t i = 0; i < size_y; i++) hy[b][i] = hy_ex[b][i]; } } // // Compare with with the solution. // if(arg.unit_check) { unit_check_general(1, N, abs_incy, stridey, hy, hy1, batch_count); unit_check_general(1, N, abs_incy, stridey, hy, hy2, batch_count); } if(arg.norm_check) { rocblas_error_1 = norm_check_general('I', 1, N, abs_incy, stridey, hy, hy1, batch_count); rocblas_error_2 = norm_check_general('I', 1, N, abs_incy, stridey, hy, hy2, batch_count); } } } if(arg.timing) { int number_cold_calls = arg.cold_iters; int number_hot_calls = arg.iters; CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_host)); // // Transfer from host to device. // CHECK_HIP_ERROR(dy.transfer_from(hy)); // // Cold. // for(int iter = 0; iter < number_cold_calls; iter++) { rocblas_axpy_strided_batched_ex_fn(handle, N, &h_alpha, alpha_type, dx, x_type, incx, stridex, dy, y_type, incy, stridey, batch_count, execution_type); } // // Transfer from host to device. // CHECK_HIP_ERROR(dy.transfer_from(hy)); hipStream_t stream; CHECK_ROCBLAS_ERROR(rocblas_get_stream(handle, &stream)); gpu_time_used = get_time_us_sync(stream); // in microseconds for(int iter = 0; iter < number_hot_calls; iter++) { rocblas_axpy_strided_batched_ex_fn(handle, N, &h_alpha, alpha_type, dx, x_type, incx, stridex, dy, y_type, incy, stridey, batch_count, execution_type); } gpu_time_used = get_time_us_sync(stream) - gpu_time_used; ArgumentModel{} .log_args(rocblas_cout, arg, gpu_time_used, axpy_gflop_count(N), axpy_gbyte_count(N), cpu_time_used, rocblas_error_1, rocblas_error_2); } }