/* ************************************************************************ * Copyright 2020-2021 Advanced Micro Devices, Inc. * ************************************************************************ */ #pragma once #include "bytes.hpp" #include "cblas_interface.hpp" #include "flops.hpp" #include "near.hpp" #include "norm.hpp" #include "rocblas.hpp" #include "rocblas_datatype2string.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" // // herkx_strided_batched when TWOK = false // template void testing_her2k_strided_batched_bad_arg(const Arguments& arg) { auto rocblas_herXX_strided_batched_fn = arg.fortran ? (TWOK ? rocblas_her2k_strided_batched, true> : rocblas_herkx_strided_batched, true>) : (TWOK ? rocblas_her2k_strided_batched, false> : rocblas_herkx_strided_batched, false>); rocblas_local_handle handle{arg}; const rocblas_fill uplo = rocblas_fill_upper; const rocblas_operation transA = rocblas_operation_none; const rocblas_int N = 100; const rocblas_int K = 100; const rocblas_int lda = 100; const rocblas_int ldb = 100; const rocblas_int ldc = 100; const T alpha = 1.0; using U = real_t; const U beta = 1.0; rocblas_stride strideA = 1; rocblas_stride strideB = 1; rocblas_stride strideC = 1; rocblas_int batch_count = 2; const size_t safe_size = 100; // allocate memory on device device_vector dA(safe_size); device_vector dB(safe_size); device_vector dC(safe_size); CHECK_DEVICE_ALLOCATION(dA.memcheck()); CHECK_DEVICE_ALLOCATION(dB.memcheck()); CHECK_DEVICE_ALLOCATION(dC.memcheck()); EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(nullptr, uplo, transA, N, K, &alpha, dA, lda, strideA, dB, ldb, strideB, &beta, dC, ldc, strideC, batch_count), rocblas_status_invalid_handle); EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(handle, rocblas_fill_full, transA, N, K, &alpha, dA, lda, strideA, dB, ldb, strideB, &beta, dC, ldc, strideC, batch_count), rocblas_status_invalid_value); EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(handle, uplo, rocblas_operation_transpose, N, K, &alpha, dA, lda, strideA, dB, ldb, strideB, &beta, dC, ldc, strideC, batch_count), rocblas_status_invalid_value); EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, nullptr, dA, lda, strideA, dB, ldb, strideB, &beta, dC, ldc, strideC, batch_count), rocblas_status_invalid_pointer); EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, &alpha, nullptr, lda, strideA, dB, ldb, strideB, &beta, dC, ldc, strideC, batch_count), rocblas_status_invalid_pointer); EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, &alpha, dA, lda, strideA, nullptr, ldb, strideB, &beta, dC, ldc, strideC, batch_count), rocblas_status_invalid_pointer); EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, &alpha, dA, lda, strideA, dB, ldb, strideB, nullptr, dC, ldc, strideC, batch_count), rocblas_status_invalid_pointer); EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, &alpha, dA, lda, strideA, dB, ldb, strideB, &beta, nullptr, ldc, strideC, batch_count), rocblas_status_invalid_pointer); // quick return with invalid pointers EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(handle, uplo, transA, 0, K, nullptr, nullptr, lda, strideA, nullptr, ldb, strideB, nullptr, nullptr, ldc, strideC, batch_count), rocblas_status_success); } template void testing_her2k_strided_batched(const Arguments& arg) { auto rocblas_herXX_strided_batched_fn = arg.fortran ? (TWOK ? rocblas_her2k_strided_batched, true> : rocblas_herkx_strided_batched, true>) : (TWOK ? rocblas_her2k_strided_batched, false> : rocblas_herkx_strided_batched, false>); auto herXX_gflop_count_fn = TWOK ? her2k_gflop_count : herkx_gflop_count; auto herXX_ref_fn = TWOK ? cblas_her2k : cblas_herkx; rocblas_local_handle handle{arg}; rocblas_fill uplo = char2rocblas_fill(arg.uplo); rocblas_operation transA = char2rocblas_operation(arg.transA); rocblas_int N = arg.N; rocblas_int K = arg.K; rocblas_int lda = arg.lda; rocblas_int ldb = arg.ldb; rocblas_int ldc = arg.ldc; T alpha = arg.get_alpha(); using U = real_t; U beta = arg.get_beta(); rocblas_stride strideA = arg.stride_a; rocblas_stride strideB = arg.stride_b; rocblas_stride strideC = arg.stride_c; rocblas_int batch_count = arg.batch_count; double gpu_time_used, cpu_time_used; double rocblas_error = 0.0; // Note: K==0 is not an early exit, since C still needs to be multiplied by beta bool invalid_size = batch_count < 0 || N < 0 || K < 0 || ldc < N || (transA == rocblas_operation_none && (lda < N || ldb < N)) || (transA != rocblas_operation_none && (lda < K || ldb < K)); if(N == 0 || batch_count == 0 || invalid_size) { // ensure invalid sizes checked before pointer check EXPECT_ROCBLAS_STATUS(rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, nullptr, nullptr, lda, strideA, nullptr, ldb, strideB, nullptr, nullptr, ldc, strideC, batch_count), invalid_size ? rocblas_status_invalid_size : rocblas_status_success); return; } size_t cols = (transA == rocblas_operation_none ? std::max(K, 1) : N); size_t rows = (transA != rocblas_operation_none ? std::max(K, 1) : N); strideA = std::max(strideA, rocblas_stride(lda * cols)); strideB = std::max(strideB, rocblas_stride(ldb * cols)); strideC = std::max(strideC, rocblas_stride(size_t(ldc) * N)); size_t size_A = strideA * batch_count; size_t size_B = strideB * batch_count; size_t size_C = strideC * batch_count; // allocate memory on device device_vector dA(size_A); device_vector dB(size_B); device_vector dC(size_C); device_vector d_alpha(1); device_vector d_beta(1); CHECK_DEVICE_ALLOCATION(dA.memcheck()); CHECK_DEVICE_ALLOCATION(dB.memcheck()); CHECK_DEVICE_ALLOCATION(dC.memcheck()); CHECK_DEVICE_ALLOCATION(d_alpha.memcheck()); CHECK_DEVICE_ALLOCATION(d_beta.memcheck()); // Naming: dX is in GPU (device) memory. hK is in CPU (host) memory host_vector h_alpha(1); host_vector h_beta(1); host_vector hA(size_A); host_vector hB(size_B); host_vector hC_1(size_C); host_vector hC_2(size_C); host_vector hC_gold(size_C); CHECK_HIP_ERROR(h_alpha.memcheck()); CHECK_HIP_ERROR(h_beta.memcheck()); CHECK_HIP_ERROR(hA.memcheck()); CHECK_HIP_ERROR(hB.memcheck()); CHECK_HIP_ERROR(hC_1.memcheck()); CHECK_HIP_ERROR(hC_2.memcheck()); CHECK_HIP_ERROR(hC_gold.memcheck()); // Initial Data on CPU h_alpha[0] = alpha; h_beta[0] = beta; // Initialize data on host memory rocblas_init_matrix(hA, arg, size_A, 1, 1, 0, 1, rocblas_client_alpha_sets_nan, true); if(TWOK) { rocblas_init_matrix(hB, arg, size_B, 1, 1, 0, 1, rocblas_client_never_set_nan, false, true); } else { // require symmetric A*B^H so testing with B = A rocblas_copy_matrix((T*)hA, (T*)hB, rows, cols, lda, ldb, strideA, strideB, batch_count); } rocblas_init_matrix(hC_1, arg, size_C, 1, 1, 0, 1, rocblas_client_beta_sets_nan); hC_2 = hC_1; hC_gold = hC_1; // copy data from CPU to device CHECK_HIP_ERROR(dA.transfer_from(hA)); CHECK_HIP_ERROR(dB.transfer_from(hB)); if(arg.unit_check || arg.norm_check) { // host alpha/beta CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_host)); CHECK_HIP_ERROR(dC.transfer_from(hC_1)); CHECK_ROCBLAS_ERROR(rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, &h_alpha[0], dA, lda, strideA, dB, ldb, strideB, &h_beta[0], dC, ldc, strideC, batch_count)); // copy output from device to CPU CHECK_HIP_ERROR(hC_1.transfer_from(dC)); // device alpha/beta CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_device)); CHECK_HIP_ERROR(dC.transfer_from(hC_2)); CHECK_HIP_ERROR(d_alpha.transfer_from(h_alpha)); CHECK_HIP_ERROR(d_beta.transfer_from(h_beta)); CHECK_ROCBLAS_ERROR(rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, d_alpha, dA, lda, strideA, dB, ldb, strideB, d_beta, dC, ldc, strideC, batch_count)); // CPU BLAS if(arg.timing) { cpu_time_used = get_time_us_no_sync(); } // cpu reference for(int i = 0; i < batch_count; i++) { // herkx: B equals A to ensure a symmetric result herXX_ref_fn(uplo, transA, N, K, &h_alpha[0], hA + i * strideA, lda, hB + i * strideB, ldb, &h_beta[0], hC_gold + i * strideC, ldc); } if(arg.timing) { cpu_time_used = get_time_us_no_sync() - cpu_time_used; } // copy output from device to CPU CHECK_HIP_ERROR(hC_2.transfer_from(dC)); if(arg.unit_check) { const double tol = K * sum_error_tolerance; near_check_general(N, N, ldc, strideC, hC_gold, hC_1, batch_count, tol); near_check_general(N, N, ldc, strideC, hC_gold, hC_2, batch_count, tol); } if(arg.norm_check) { auto err1 = std::abs( norm_check_general('F', N, N, ldc, strideC, hC_gold, hC_1, batch_count)); auto err2 = std::abs( norm_check_general('F', N, N, ldc, strideC, hC_gold, hC_2, batch_count)); rocblas_error = err1 > err2 ? err1 : err2; } } 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)); for(int i = 0; i < number_cold_calls; i++) { rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, h_alpha, dA, lda, strideA, dB, ldb, strideB, h_beta, dC, ldc, strideC, batch_count); } hipStream_t stream; CHECK_ROCBLAS_ERROR(rocblas_get_stream(handle, &stream)); gpu_time_used = get_time_us_sync(stream); // in microseconds for(int i = 0; i < number_hot_calls; i++) { rocblas_herXX_strided_batched_fn(handle, uplo, transA, N, K, h_alpha, dA, lda, strideA, dB, ldb, strideB, h_beta, dC, ldc, strideC, batch_count); } gpu_time_used = get_time_us_sync(stream) - gpu_time_used; Arguments targ(arg); targ.stride_a = strideA; targ.stride_b = strideB; targ.stride_c = strideC; ArgumentModel{} .log_args(rocblas_cout, targ, gpu_time_used, herXX_gflop_count_fn(N, K), ArgumentLogging::NA_value, cpu_time_used, rocblas_error); } }