/* ************************************************************************ * Copyright (c) 2018 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. * * ************************************************************************ */ #pragma once #ifndef TESTING_CSRMM_HPP #define TESTING_CSRMM_HPP #include "hipsparse.hpp" #include "hipsparse_test_unique_ptr.hpp" #include "unit.hpp" #include "utility.hpp" #include #include using namespace hipsparse; using namespace hipsparse_test; template void testing_csrmm_bad_arg(void) { #ifdef __HIP_PLATFORM_NVCC__ // do not test for bad args return; #endif int N = 100; int M = 100; int K = 100; int ldb = 100; int ldc = 100; int nnz = 100; int safe_size = 100; T alpha = 0.6; T beta = 0.2; hipsparseOperation_t transA = HIPSPARSE_OPERATION_NON_TRANSPOSE; hipsparseOperation_t transB = HIPSPARSE_OPERATION_NON_TRANSPOSE; hipsparseStatus_t status; std::unique_ptr unique_ptr_handle(new handle_struct); hipsparseHandle_t handle = unique_ptr_handle->handle; std::unique_ptr unique_ptr_descr(new descr_struct); hipsparseMatDescr_t descr = unique_ptr_descr->descr; auto dptr_managed = hipsparse_unique_ptr{device_malloc(sizeof(int) * safe_size), device_free}; auto dcol_managed = hipsparse_unique_ptr{device_malloc(sizeof(int) * safe_size), device_free}; auto dval_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * safe_size), device_free}; auto dB_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * safe_size), device_free}; auto dC_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * safe_size), device_free}; int* dptr = (int*)dptr_managed.get(); int* dcol = (int*)dcol_managed.get(); T* dval = (T*)dval_managed.get(); T* dB = (T*)dB_managed.get(); T* dC = (T*)dC_managed.get(); if(!dval || !dptr || !dcol || !dB || !dC) { PRINT_IF_HIP_ERROR(hipErrorOutOfMemory); return; } // testing for(nullptr == dptr) { int* dptr_null = nullptr; status = hipsparseXcsrmm2(handle, transA, transB, M, N, K, nnz, &alpha, descr, dval, dptr_null, dcol, dB, ldb, &beta, dC, ldc); verify_hipsparse_status_invalid_pointer(status, "Error: dptr is nullptr"); } // testing for(nullptr == dcol) { int* dcol_null = nullptr; status = hipsparseXcsrmm2(handle, transA, transB, M, N, K, nnz, &alpha, descr, dval, dptr, dcol_null, dB, ldb, &beta, dC, ldc); verify_hipsparse_status_invalid_pointer(status, "Error: dcol is nullptr"); } // testing for(nullptr == dval) { T* dval_null = nullptr; status = hipsparseXcsrmm2(handle, transA, transB, M, N, K, nnz, &alpha, descr, dval_null, dptr, dcol, dB, ldb, &beta, dC, ldc); verify_hipsparse_status_invalid_pointer(status, "Error: dval is nullptr"); } // testing for(nullptr == dB) { T* dB_null = nullptr; status = hipsparseXcsrmm2(handle, transA, transB, M, N, K, nnz, &alpha, descr, dval, dptr, dcol, dB_null, ldb, &beta, dC, ldc); verify_hipsparse_status_invalid_pointer(status, "Error: dB is nullptr"); } // testing for(nullptr == dC) { T* dC_null = nullptr; status = hipsparseXcsrmm2(handle, transA, transB, M, N, K, nnz, &alpha, descr, dval, dptr, dcol, dB, ldb, &beta, dC_null, ldc); verify_hipsparse_status_invalid_pointer(status, "Error: dC is nullptr"); } // testing for(nullptr == d_alpha) { T* d_alpha_null = nullptr; status = hipsparseXcsrmm2(handle, transA, transB, M, N, K, nnz, d_alpha_null, descr, dval, dptr, dcol, dB, ldb, &beta, dC, ldc); verify_hipsparse_status_invalid_pointer(status, "Error: alpha is nullptr"); } // testing for(nullptr == d_beta) { T* d_beta_null = nullptr; status = hipsparseXcsrmm2(handle, transA, transB, M, N, K, nnz, &alpha, descr, dval, dptr, dcol, dB, ldb, d_beta_null, dC, ldc); verify_hipsparse_status_invalid_pointer(status, "Error: beta is nullptr"); } // testing for(nullptr == descr) { hipsparseMatDescr_t descr_null = nullptr; status = hipsparseXcsrmm2(handle, transA, transB, M, N, K, nnz, &alpha, descr_null, dval, dptr, dcol, dB, ldb, &beta, dC, ldc); verify_hipsparse_status_invalid_pointer(status, "Error: descr is nullptr"); } // testing for(nullptr == handle) { hipsparseHandle_t handle_null = nullptr; status = hipsparseXcsrmm2(handle_null, transA, transB, M, N, K, nnz, &alpha, descr, dval, dptr, dcol, dB, ldb, &beta, dC, ldc); verify_hipsparse_status_invalid_handle(status); } } template hipsparseStatus_t testing_csrmm(Arguments argus) { int safe_size = 100; int M = argus.M; int N = argus.N; int K = argus.K; int ldb = argus.ldb; int ldc = argus.ldc; T h_alpha = argus.alpha; T h_beta = argus.beta; hipsparseOperation_t transA = argus.transA; hipsparseOperation_t transB = argus.transB; hipsparseIndexBase_t idx_base = argus.idx_base; std::string binfile = ""; std::string filename = ""; hipsparseStatus_t status; // When in testing mode, M == N == -99 indicates that we are testing with a real // matrix from cise.ufl.edu if(M == -99 && K == -99 && argus.timing == 0) { binfile = argus.filename; M = K = safe_size; } if(argus.timing == 1) { filename = argus.filename; } std::unique_ptr test_handle(new handle_struct); hipsparseHandle_t handle = test_handle->handle; std::unique_ptr test_descr(new descr_struct); hipsparseMatDescr_t descr = test_descr->descr; // Set matrix index base CHECK_HIPSPARSE_ERROR(hipsparseSetMatIndexBase(descr, idx_base)); // Determine number of non-zero elements double scale = 0.02; if(M > 1000 || K > 1000) { scale = 2.0 / std::max(M, K); } int nnz = M * scale * K; // Argument sanity check before allocating invalid memory if(M <= 0 || N <= 0 || K <= 0 || nnz <= 0) { #ifdef __HIP_PLATFORM_NVCC__ // Do not test args in cusparse return HIPSPARSE_STATUS_SUCCESS; #endif auto dptr_managed = hipsparse_unique_ptr{device_malloc(sizeof(int) * safe_size), device_free}; auto dcol_managed = hipsparse_unique_ptr{device_malloc(sizeof(int) * safe_size), device_free}; auto dval_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * safe_size), device_free}; auto dB_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * safe_size), device_free}; auto dC_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * safe_size), device_free}; int* dptr = (int*)dptr_managed.get(); int* dcol = (int*)dcol_managed.get(); T* dval = (T*)dval_managed.get(); T* dB = (T*)dB_managed.get(); T* dC = (T*)dC_managed.get(); if(!dval || !dptr || !dcol || !dB || !dC) { verify_hipsparse_status_success(HIPSPARSE_STATUS_ALLOC_FAILED, "!dptr || !dcol || !dval || !dB || !dC"); return HIPSPARSE_STATUS_ALLOC_FAILED; } CHECK_HIPSPARSE_ERROR(hipsparseSetPointerMode(handle, HIPSPARSE_POINTER_MODE_HOST)); status = hipsparseXcsrmm2(handle, transA, transB, M, N, K, nnz, &h_alpha, descr, dval, dptr, dcol, dB, ldb, &h_beta, dC, ldc); if(M < 0 || N < 0 || K < 0 || nnz < 0) { verify_hipsparse_status_invalid_size(status, "Error: M < 0 || N < 0 || K < 0 || nnz < 0"); } else { verify_hipsparse_status_success(status, "M >= 0 && N >= 0 && K >= 0 && nnz >= 0"); } return HIPSPARSE_STATUS_SUCCESS; } // Initialize random seed srand(12345ULL); // Host structures - CSR matrix A std::vector hcsr_row_ptrA; std::vector hcsr_col_indA; std::vector hcsr_valA; // Initial Data on CPU if(binfile != "") { if(read_bin_matrix( binfile.c_str(), M, K, nnz, hcsr_row_ptrA, hcsr_col_indA, hcsr_valA, idx_base) != 0) { fprintf(stderr, "Cannot open [read] %s\n", binfile.c_str()); return HIPSPARSE_STATUS_INTERNAL_ERROR; } } else if(argus.laplacian) { M = K = gen_2d_laplacian(argus.laplacian, hcsr_row_ptrA, hcsr_col_indA, hcsr_valA, idx_base); nnz = hcsr_row_ptrA[M]; } else { std::vector hcoo_row_indA; if(filename != "") { if(read_mtx_matrix( filename.c_str(), M, K, nnz, hcoo_row_indA, hcsr_col_indA, hcsr_valA, idx_base) != 0) { fprintf(stderr, "Cannot open [read] %s\n", filename.c_str()); return HIPSPARSE_STATUS_INTERNAL_ERROR; } } else { gen_matrix_coo(M, K, nnz, hcoo_row_indA, hcsr_col_indA, hcsr_valA, idx_base); } // Convert COO to CSR hcsr_row_ptrA.resize(M + 1, 0); for(int i = 0; i < nnz; ++i) { ++hcsr_row_ptrA[hcoo_row_indA[i] + 1 - idx_base]; } hcsr_row_ptrA[0] = idx_base; for(int i = 0; i < M; ++i) { hcsr_row_ptrA[i + 1] += hcsr_row_ptrA[i]; } } if(transB == HIPSPARSE_OPERATION_NON_TRANSPOSE) { ldb = (transA == HIPSPARSE_OPERATION_NON_TRANSPOSE) ? K : M; } else { ldb = N; } ldc = (transA == HIPSPARSE_OPERATION_NON_TRANSPOSE) ? M : K; int Anrow = M; int Ancol = K; int Bnrow = ldb; int Bncol = (transB == HIPSPARSE_OPERATION_NON_TRANSPOSE) ? N : K; int Bnnz = Bnrow * Bncol; int Cnrow = ldc; int Cncol = N; int Cnnz = Cnrow * Cncol; // Host structures - Dense matrix B and C std::vector hB(Bnnz); std::vector hC_1(Cnnz); std::vector hC_2(Cnnz); std::vector hC_gold(Cnnz); hipsparseInit(hB, Bnrow, Bncol); hipsparseInit(hC_1, Cnrow, Cncol); // copy vector is easy in STL; hC_gold = hC_1: save a copy in hy_gold which will be output of // CPU hC_gold = hC_1; hC_2 = hC_1; // allocate memory on device auto dcsr_row_ptrA_managed = hipsparse_unique_ptr{device_malloc(sizeof(int) * (M + 1)), device_free}; auto dcsr_col_indA_managed = hipsparse_unique_ptr{device_malloc(sizeof(int) * nnz), device_free}; auto dcsr_valA_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * nnz), device_free}; auto dB_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * Bnnz), device_free}; auto dC_1_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * Cnnz), device_free}; auto dC_2_managed = hipsparse_unique_ptr{device_malloc(sizeof(T) * Cnnz), device_free}; auto d_alpha_managed = hipsparse_unique_ptr{device_malloc(sizeof(T)), device_free}; auto d_beta_managed = hipsparse_unique_ptr{device_malloc(sizeof(T)), device_free}; int* dcsr_row_ptrA = (int*)dcsr_row_ptrA_managed.get(); int* dcsr_col_indA = (int*)dcsr_col_indA_managed.get(); T* dcsr_valA = (T*)dcsr_valA_managed.get(); T* dB = (T*)dB_managed.get(); T* dC_1 = (T*)dC_1_managed.get(); T* dC_2 = (T*)dC_2_managed.get(); T* d_alpha = (T*)d_alpha_managed.get(); T* d_beta = (T*)d_beta_managed.get(); if(!dcsr_valA || !dcsr_row_ptrA || !dcsr_col_indA || !dB || !dC_1 || !d_alpha || !d_beta) { verify_hipsparse_status_success(HIPSPARSE_STATUS_ALLOC_FAILED, "!dcsr_valA || !dcsr_row_ptrA || !dcsr_col_indA || !dB || " "!dC_1 || !d_alpha || !d_beta"); return HIPSPARSE_STATUS_ALLOC_FAILED; } // copy data from CPU to device CHECK_HIP_ERROR(hipMemcpy( dcsr_row_ptrA, hcsr_row_ptrA.data(), sizeof(int) * (M + 1), hipMemcpyHostToDevice)); CHECK_HIP_ERROR( hipMemcpy(dcsr_col_indA, hcsr_col_indA.data(), sizeof(int) * nnz, hipMemcpyHostToDevice)); CHECK_HIP_ERROR(hipMemcpy(dcsr_valA, hcsr_valA.data(), sizeof(T) * nnz, hipMemcpyHostToDevice)); CHECK_HIP_ERROR(hipMemcpy(dB, hB.data(), sizeof(T) * Bnnz, hipMemcpyHostToDevice)); CHECK_HIP_ERROR(hipMemcpy(dC_1, hC_1.data(), sizeof(T) * Cnnz, hipMemcpyHostToDevice)); if(argus.unit_check) { CHECK_HIP_ERROR(hipMemcpy(dC_2, hC_2.data(), sizeof(T) * Cnnz, hipMemcpyHostToDevice)); CHECK_HIP_ERROR(hipMemcpy(d_alpha, &h_alpha, sizeof(T), hipMemcpyHostToDevice)); CHECK_HIP_ERROR(hipMemcpy(d_beta, &h_beta, sizeof(T), hipMemcpyHostToDevice)); // ROCSPARSE pointer mode host CHECK_HIPSPARSE_ERROR(hipsparseSetPointerMode(handle, HIPSPARSE_POINTER_MODE_HOST)); CHECK_HIPSPARSE_ERROR(hipsparseXcsrmm2(handle, transA, transB, Anrow, Cncol, Ancol, nnz, &h_alpha, descr, dcsr_valA, dcsr_row_ptrA, dcsr_col_indA, dB, ldb, &h_beta, dC_1, ldc)); // ROCSPARSE pointer mode device CHECK_HIPSPARSE_ERROR(hipsparseSetPointerMode(handle, HIPSPARSE_POINTER_MODE_DEVICE)); CHECK_HIPSPARSE_ERROR(hipsparseXcsrmm2(handle, transA, transB, Anrow, Cncol, Ancol, nnz, d_alpha, descr, dcsr_valA, dcsr_row_ptrA, dcsr_col_indA, dB, ldb, d_beta, dC_2, ldc)); // copy output from device to CPU CHECK_HIP_ERROR(hipMemcpy(hC_1.data(), dC_1, sizeof(T) * Cnnz, hipMemcpyDeviceToHost)); CHECK_HIP_ERROR(hipMemcpy(hC_2.data(), dC_2, sizeof(T) * Cnnz, hipMemcpyDeviceToHost)); // CPU double cpu_time_used = get_time_us(); for(int i = 0; i < Cnrow; ++i) { for(int j = 0; j < Cncol; ++j) { int Cidx = i + j * ldc; T sum = hC_gold[Cidx] * h_beta; for(int k = hcsr_row_ptrA[i] - idx_base; k < hcsr_row_ptrA[i + 1] - idx_base; ++k) { int Bidx = (transB == HIPSPARSE_OPERATION_NON_TRANSPOSE) ? (hcsr_col_indA[k] - idx_base + j * ldb) : (j + (hcsr_col_indA[k] - idx_base) * ldb); sum += h_alpha * hcsr_valA[k] * hB[Bidx]; } hC_gold[Cidx] = sum; } } cpu_time_used = get_time_us() - cpu_time_used; unit_check_near(Cnrow, Cncol, ldc, hC_gold.data(), hC_1.data()); unit_check_near(Cnrow, Cncol, ldc, hC_gold.data(), hC_2.data()); } if(argus.timing) { int number_cold_calls = 2; int number_hot_calls = argus.iters; CHECK_HIPSPARSE_ERROR(hipsparseSetPointerMode(handle, HIPSPARSE_POINTER_MODE_HOST)); for(int iter = 0; iter < number_cold_calls; iter++) { hipsparseXcsrmm2(handle, transA, transB, Anrow, Cncol, Ancol, nnz, &h_alpha, descr, dcsr_valA, dcsr_row_ptrA, dcsr_col_indA, dB, ldb, &h_beta, dC_1, ldc); } double gpu_time_used = get_time_us(); // in microseconds for(int iter = 0; iter < number_hot_calls; iter++) { hipsparseXcsrmm2(handle, transA, transB, Anrow, Cncol, Ancol, nnz, &h_alpha, descr, dcsr_valA, dcsr_row_ptrA, dcsr_col_indA, dB, ldb, &h_beta, dC_1, ldc); } // Convert to miliseconds per call gpu_time_used = (get_time_us() - gpu_time_used) / (number_hot_calls * 1e3); size_t flops = 3.0 * nnz * Bncol; flops = (h_beta != 0.0) ? flops + Cnnz : flops; double gpu_gflops = flops / gpu_time_used / 1e6; size_t memtrans = nnz + Cnnz + Bnnz; memtrans = (h_beta != 0.0) ? memtrans + Cnnz : memtrans; double bandwidth = (memtrans * sizeof(T) + (M + 1 + nnz) * sizeof(int)) / gpu_time_used / 1e6; printf("m\t\tn\t\tk\t\tnnz\t\talpha\tbeta\tGFlops\tGB/s\tmsec\n"); printf("%8d\t%8d\t%8d\t%9d\t%0.2lf\t%0.2lf\t%0.2lf\t%0.2lf\t%0.2lf\n", M, N, K, nnz, h_alpha, h_beta, gpu_gflops, bandwidth, gpu_time_used); } return HIPSPARSE_STATUS_SUCCESS; } #endif // TESTING_CSRMM_HPP