/* ************************************************************************ * Copyright 2018-2019 Advanced Micro Devices, Inc. * ************************************************************************ */ #include "cblas_interface.hpp" #include "near.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 "unit.hpp" #include "utility.hpp" template void testing_nrm2_bad_arg_template(const Arguments& arg) { rocblas_int N = 100; rocblas_int incx = 1; static const size_t safe_size = 100; rocblas_local_handle handle; device_vector dx(safe_size); device_vector d_rocblas_result(1); if(!dx || !d_rocblas_result) { CHECK_HIP_ERROR(hipErrorOutOfMemory); return; } CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_device)); EXPECT_ROCBLAS_STATUS((rocblas_nrm2(handle, N, nullptr, incx, d_rocblas_result)), rocblas_status_invalid_pointer); EXPECT_ROCBLAS_STATUS((rocblas_nrm2(handle, N, dx, incx, nullptr)), rocblas_status_invalid_pointer); EXPECT_ROCBLAS_STATUS((rocblas_nrm2(nullptr, N, dx, incx, d_rocblas_result)), rocblas_status_invalid_handle); } template void testing_nrm2_template(const Arguments& arg) { rocblas_int N = arg.N; rocblas_int incx = arg.incx; T2 rocblas_result_1; T2 rocblas_result_2; T2 cpu_result; double rocblas_error_1; double rocblas_error_2; rocblas_local_handle handle; // check to prevent undefined memory allocation error if(N <= 0 || incx <= 0) { static const size_t safe_size = 100; // arbitrarily set to zero device_vector dx(safe_size); device_vector d_rocblas_result(1); if(!dx || !d_rocblas_result) { CHECK_HIP_ERROR(hipErrorOutOfMemory); return; } CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_device)); CHECK_ROCBLAS_ERROR((rocblas_nrm2(handle, N, dx, incx, d_rocblas_result))); return; } size_t size_x = N * size_t(incx); // allocate memory on device device_vector dx(size_x); device_vector d_rocblas_result_2(1); if(!dx || !d_rocblas_result_2) { CHECK_HIP_ERROR(hipErrorOutOfMemory); return; } // Naming: dx is in GPU (device) memory. hx is in CPU (host) memory, plz follow this practice host_vector hx(size_x); // Initial Data on CPU rocblas_seedrand(); rocblas_init(hx, 1, N, incx); // copy data from CPU to device, does not work for incx != 1 CHECK_HIP_ERROR(hipMemcpy(dx, hx, sizeof(T1) * N * incx, hipMemcpyHostToDevice)); double gpu_time_used, cpu_time_used; if(arg.unit_check || arg.norm_check) { // GPU BLAS, rocblas_pointer_mode_host CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_host)); CHECK_ROCBLAS_ERROR((rocblas_nrm2(handle, N, dx, incx, &rocblas_result_1))); // GPU BLAS, rocblas_pointer_mode_device CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_device)); CHECK_ROCBLAS_ERROR((rocblas_nrm2(handle, N, dx, incx, d_rocblas_result_2))); CHECK_HIP_ERROR( hipMemcpy(&rocblas_result_2, d_rocblas_result_2, sizeof(T2), hipMemcpyDeviceToHost)); // CPU BLAS cpu_time_used = get_time_us(); cblas_nrm2(N, hx, incx, &cpu_result); cpu_time_used = get_time_us() - cpu_time_used; // allowable error is sqrt of precision. This is based on nrm2 calculating the // square root of a sum. It is assumed that the sum will have accuracy =approx= // precision, so nrm2 will have accuracy =approx= sqrt(precision) T2 abs_error = pow(10.0, -(std::numeric_limits::digits10 / 2.0)) * cpu_result; T2 tolerance = 2.0; // accounts for rounding in reduction sum. depends on n. // If test fails, try decreasing n or increasing tolerance. abs_error *= tolerance; if(arg.unit_check) { near_check_general(1, 1, 1, &cpu_result, &rocblas_result_1, abs_error); near_check_general(1, 1, 1, &cpu_result, &rocblas_result_2, abs_error); } if(arg.norm_check) { printf("cpu=%e, gpu_host_ptr=%e, gpu_dev_ptr=%e\n", cpu_result, rocblas_result_1, rocblas_result_2); rocblas_error_1 = std::abs((cpu_result - rocblas_result_1) / cpu_result); rocblas_error_2 = std::abs((cpu_result - rocblas_result_2) / cpu_result); } } if(arg.timing) { int number_cold_calls = 2; int number_hot_calls = 100; CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_host)); for(int iter = 0; iter < number_cold_calls; iter++) { rocblas_nrm2(handle, N, dx, incx, &rocblas_result_2); } gpu_time_used = get_time_us(); // in microseconds for(int iter = 0; iter < number_hot_calls; iter++) { rocblas_nrm2(handle, N, dx, incx, &rocblas_result_2); } gpu_time_used = (get_time_us() - gpu_time_used) / number_hot_calls; std::cout << "N,incx,rocblas(us)"; if(arg.norm_check) std::cout << ",CPU(us),error_host_ptr,error_dev_ptr"; std::cout << std::endl; std::cout << N << "," << incx << "," << gpu_time_used; if(arg.norm_check) std::cout << "," << cpu_time_used << "," << rocblas_error_1 << "," << rocblas_error_2; std::cout << std::endl; } } template void testing_nrm2_bad_arg(const Arguments& arg) { testing_nrm2_bad_arg_template(arg); } template <> void testing_nrm2_bad_arg(const Arguments& arg) { testing_nrm2_bad_arg_template(arg); } template <> void testing_nrm2_bad_arg(const Arguments& arg) { testing_nrm2_bad_arg_template(arg); } template void testing_nrm2(const Arguments& arg) { testing_nrm2_template(arg); } template <> void testing_nrm2(const Arguments& arg) { testing_nrm2_template(arg); } template <> void testing_nrm2(const Arguments& arg) { testing_nrm2_template(arg); }