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All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of the NVIDIA CORPORATION nor the * names of its contributors may be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL NVIDIA CORPORATION BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIAeBILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * ******************************************************************************/ //--------------------------------------------------------------------- // SpMV comparison tool //--------------------------------------------------------------------- #include #include #include #include #include #include #include #include "sparse_matrix.h" // Ensure printing of CUDA runtime errors to console #define CUB_STDERR #include #include #include #include using namespace cub; //--------------------------------------------------------------------- // Globals, constants, and type declarations //--------------------------------------------------------------------- bool g_quiet = false; // Whether to display stats in CSV format bool g_verbose = false; // Whether to display output to console bool g_verbose2 = false; // Whether to display input to console CachingDeviceAllocator g_allocator(true); // Caching allocator for device memory //--------------------------------------------------------------------- // SpMV verification //--------------------------------------------------------------------- // Compute reference SpMV y = Ax template < typename ValueT, typename OffsetT> void SpmvGold( CsrMatrix& a, ValueT* vector_x, ValueT* vector_y_in, ValueT* vector_y_out, ValueT alpha, ValueT beta) { for (OffsetT row = 0; row < a.num_rows; ++row) { ValueT partial = beta * vector_y_in[row]; for ( OffsetT offset = a.row_offsets[row]; offset < a.row_offsets[row + 1]; ++offset) { partial += alpha * a.values[offset] * vector_x[a.column_indices[offset]]; } vector_y_out[row] = partial; } } //--------------------------------------------------------------------- // GPU I/O proxy //--------------------------------------------------------------------- /** * Read every matrix nonzero value, read every corresponding vector value */ template < int BLOCK_THREADS, int ITEMS_PER_THREAD, typename ValueT, typename OffsetT, typename VectorItr> __launch_bounds__ (int(BLOCK_THREADS)) __global__ void NonZeroIoKernel( SpmvParams params, VectorItr d_vector_x) { enum { TILE_ITEMS = BLOCK_THREADS * ITEMS_PER_THREAD, }; ValueT nonzero = 0.0; int tile_idx = blockIdx.x; OffsetT block_offset = tile_idx * TILE_ITEMS; OffsetT column_indices[ITEMS_PER_THREAD]; ValueT values[ITEMS_PER_THREAD]; #pragma unroll for (int ITEM = 0; ITEM < ITEMS_PER_THREAD; ++ITEM) { OffsetT nonzero_idx = block_offset + (ITEM * BLOCK_THREADS) + threadIdx.x; OffsetT* ci = params.d_column_indices + nonzero_idx; ValueT*a = params.d_values + nonzero_idx; column_indices[ITEM] = (nonzero_idx < params.num_nonzeros) ? *ci : 0; values[ITEM] = (nonzero_idx < params.num_nonzeros) ? *a : 0.0; } __syncthreads(); // Read vector #pragma unroll for (int ITEM = 0; ITEM < ITEMS_PER_THREAD; ++ITEM) { ValueT vector_value = ThreadLoad(params.d_vector_x + column_indices[ITEM]); nonzero += vector_value * values[ITEM]; } __syncthreads(); if (block_offset < params.num_rows) { #pragma unroll for (int ITEM = 0; ITEM < ITEMS_PER_THREAD; ++ITEM) { OffsetT row_idx = block_offset + (ITEM * BLOCK_THREADS) + threadIdx.x; if (row_idx < params.num_rows) { OffsetT row_end_offset = ThreadLoad(params.d_row_end_offsets + row_idx); if ((row_end_offset >= 0) && (nonzero == nonzero)) params.d_vector_y[row_idx] = nonzero; } } } } /** * Run GPU I/O proxy */ template < typename ValueT, typename OffsetT> float TestGpuCsrIoProxy( SpmvParams& params, int timing_iterations) { enum { BLOCK_THREADS = 128, ITEMS_PER_THREAD = 7, TILE_SIZE = BLOCK_THREADS * ITEMS_PER_THREAD, }; // size_t smem = 1024 * 16; size_t smem = 1024 * 0; unsigned int nonzero_blocks = (params.num_nonzeros + TILE_SIZE - 1) / TILE_SIZE; unsigned int row_blocks = (params.num_rows + TILE_SIZE - 1) / TILE_SIZE; unsigned int blocks = std::max(nonzero_blocks, row_blocks); typedef TexRefInputIterator TexItr; TexItr x_itr; CubDebugExit(x_itr.BindTexture(params.d_vector_x)); // Get device ordinal int device_ordinal; CubDebugExit(cudaGetDevice(&device_ordinal)); // Get device SM version int sm_version; CubDebugExit(SmVersion(sm_version, device_ordinal)); void (*kernel)(SpmvParams, TexItr) = NonZeroIoKernel; int spmv_sm_occupancy; CubDebugExit(MaxSmOccupancy(spmv_sm_occupancy, kernel, BLOCK_THREADS, smem)); if (!g_quiet) printf("NonZeroIoKernel<%d,%d><<<%d, %d>>>, sm occupancy %d\n", BLOCK_THREADS, ITEMS_PER_THREAD, blocks, BLOCK_THREADS, spmv_sm_occupancy); // Warmup NonZeroIoKernel<<>>(params, x_itr); // Check for failures CubDebugExit(cudaPeekAtLastError()); CubDebugExit(SyncStream(0)); // Timing GpuTimer timer; float elapsed_millis = 0.0; timer.Start(); for (int it = 0; it < timing_iterations; ++it) { NonZeroIoKernel<<>>(params, x_itr); } timer.Stop(); elapsed_millis += timer.ElapsedMillis(); CubDebugExit(x_itr.UnbindTexture()); return elapsed_millis / timing_iterations; } //--------------------------------------------------------------------- // cuSparse HybMV //--------------------------------------------------------------------- /** * Run cuSparse HYB SpMV (specialized for fp32) */ template < typename OffsetT> float TestCusparseHybmv( float* vector_y_in, float* reference_vector_y_out, SpmvParams& params, int timing_iterations, cusparseHandle_t cusparse) { CpuTimer cpu_timer; cpu_timer.Start(); // Construct Hyb matrix cusparseMatDescr_t mat_desc; cusparseHybMat_t hyb_desc; AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseCreateMatDescr(&mat_desc)); AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseCreateHybMat(&hyb_desc)); cusparseStatus_t status = cusparseScsr2hyb( cusparse, params.num_rows, params.num_cols, mat_desc, params.d_values, params.d_row_end_offsets, params.d_column_indices, hyb_desc, 0, CUSPARSE_HYB_PARTITION_AUTO); AssertEquals(CUSPARSE_STATUS_SUCCESS, status); cudaDeviceSynchronize(); cpu_timer.Stop(); float elapsed_millis = cpu_timer.ElapsedMillis(); printf("HYB setup ms, %.5f, ", elapsed_millis); // Reset input/output vector y CubDebugExit(cudaMemcpy(params.d_vector_y, vector_y_in, sizeof(float) * params.num_rows, cudaMemcpyHostToDevice)); // Warmup AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseShybmv( cusparse, CUSPARSE_OPERATION_NON_TRANSPOSE, ¶ms.alpha, mat_desc, hyb_desc, params.d_vector_x, ¶ms.beta, params.d_vector_y)); if (!g_quiet) { int compare = CompareDeviceResults(reference_vector_y_out, params.d_vector_y, params.num_rows, true, g_verbose); printf("\t%s\n", compare ? "FAIL" : "PASS"); fflush(stdout); } // Timing elapsed_millis = 0.0; GpuTimer timer; timer.Start(); for(int it = 0; it < timing_iterations; ++it) { AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseShybmv( cusparse, CUSPARSE_OPERATION_NON_TRANSPOSE, ¶ms.alpha, mat_desc, hyb_desc, params.d_vector_x, ¶ms.beta, params.d_vector_y)); } timer.Stop(); elapsed_millis += timer.ElapsedMillis(); // Cleanup AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDestroyHybMat(hyb_desc)); AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDestroyMatDescr(mat_desc)); return elapsed_millis / timing_iterations; } /** * Run cuSparse HYB SpMV (specialized for fp64) */ template < typename OffsetT> float TestCusparseHybmv( double* vector_y_in, double* reference_vector_y_out, SpmvParams& params, int timing_iterations, cusparseHandle_t cusparse) { CpuTimer cpu_timer; cpu_timer.Start(); // Construct Hyb matrix cusparseMatDescr_t mat_desc; cusparseHybMat_t hyb_desc; AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseCreateMatDescr(&mat_desc)); AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseCreateHybMat(&hyb_desc)); AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDcsr2hyb( cusparse, params.num_rows, params.num_cols, mat_desc, params.d_values, params.d_row_end_offsets, params.d_column_indices, hyb_desc, 0, CUSPARSE_HYB_PARTITION_AUTO)); cudaDeviceSynchronize(); cpu_timer.Stop(); float elapsed_millis = cpu_timer.ElapsedMillis(); printf("HYB setup ms, %.5f, ", elapsed_millis); // Reset input/output vector y CubDebugExit(cudaMemcpy(params.d_vector_y, vector_y_in, sizeof(float) * params.num_rows, cudaMemcpyHostToDevice)); // Warmup AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDhybmv( cusparse, CUSPARSE_OPERATION_NON_TRANSPOSE, ¶ms.alpha, mat_desc, hyb_desc, params.d_vector_x, ¶ms.beta, params.d_vector_y)); if (!g_quiet) { int compare = CompareDeviceResults(reference_vector_y_out, params.d_vector_y, params.num_rows, true, g_verbose); printf("\t%s\n", compare ? "FAIL" : "PASS"); fflush(stdout); } // Timing elapsed_millis = 0.0; GpuTimer timer; timer.Start(); for(int it = 0; it < timing_iterations; ++it) { AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDhybmv( cusparse, CUSPARSE_OPERATION_NON_TRANSPOSE, ¶ms.alpha, mat_desc, hyb_desc, params.d_vector_x, ¶ms.beta, params.d_vector_y)); } timer.Stop(); elapsed_millis += timer.ElapsedMillis(); // Cleanup AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDestroyHybMat(hyb_desc)); AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDestroyMatDescr(mat_desc)); return elapsed_millis / timing_iterations; } //--------------------------------------------------------------------- // cuSparse CsrMV //--------------------------------------------------------------------- /** * Run cuSparse SpMV (specialized for fp32) */ template < typename OffsetT> float TestCusparseCsrmv( float* vector_y_in, float* reference_vector_y_out, SpmvParams& params, int timing_iterations, cusparseHandle_t cusparse) { cusparseMatDescr_t desc; AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseCreateMatDescr(&desc)); // Reset input/output vector y CubDebugExit(cudaMemcpy(params.d_vector_y, vector_y_in, sizeof(float) * params.num_rows, cudaMemcpyHostToDevice)); // Warmup AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseScsrmv( cusparse, CUSPARSE_OPERATION_NON_TRANSPOSE, params.num_rows, params.num_cols, params.num_nonzeros, ¶ms.alpha, desc, params.d_values, params.d_row_end_offsets, params.d_column_indices, params.d_vector_x, ¶ms.beta, params.d_vector_y)); if (!g_quiet) { int compare = CompareDeviceResults(reference_vector_y_out, params.d_vector_y, params.num_rows, true, g_verbose); printf("\t%s\n", compare ? "FAIL" : "PASS"); fflush(stdout); } // Timing float elapsed_millis = 0.0; GpuTimer timer; timer.Start(); for(int it = 0; it < timing_iterations; ++it) { AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseScsrmv( cusparse, CUSPARSE_OPERATION_NON_TRANSPOSE, params.num_rows, params.num_cols, params.num_nonzeros, ¶ms.alpha, desc, params.d_values, params.d_row_end_offsets, params.d_column_indices, params.d_vector_x, ¶ms.beta, params.d_vector_y)); } timer.Stop(); elapsed_millis += timer.ElapsedMillis(); AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDestroyMatDescr(desc)); return elapsed_millis / timing_iterations; } /** * Run cuSparse SpMV (specialized for fp64) */ template < typename OffsetT> float TestCusparseCsrmv( double* vector_y_in, double* reference_vector_y_out, SpmvParams& params, int timing_iterations, cusparseHandle_t cusparse) { cusparseMatDescr_t desc; AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseCreateMatDescr(&desc)); // Reset input/output vector y CubDebugExit(cudaMemcpy(params.d_vector_y, vector_y_in, sizeof(float) * params.num_rows, cudaMemcpyHostToDevice)); // Warmup AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDcsrmv( cusparse, CUSPARSE_OPERATION_NON_TRANSPOSE, params.num_rows, params.num_cols, params.num_nonzeros, ¶ms.alpha, desc, params.d_values, params.d_row_end_offsets, params.d_column_indices, params.d_vector_x, ¶ms.beta, params.d_vector_y)); if (!g_quiet) { int compare = CompareDeviceResults(reference_vector_y_out, params.d_vector_y, params.num_rows, true, g_verbose); printf("\t%s\n", compare ? "FAIL" : "PASS"); fflush(stdout); } // Timing float elapsed_millis = 0.0; GpuTimer timer; timer.Start(); for(int it = 0; it < timing_iterations; ++it) { AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDcsrmv( cusparse, CUSPARSE_OPERATION_NON_TRANSPOSE, params.num_rows, params.num_cols, params.num_nonzeros, ¶ms.alpha, desc, params.d_values, params.d_row_end_offsets, params.d_column_indices, params.d_vector_x, ¶ms.beta, params.d_vector_y)); } timer.Stop(); elapsed_millis += timer.ElapsedMillis(); AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseDestroyMatDescr(desc)); return elapsed_millis / timing_iterations; } //--------------------------------------------------------------------- // GPU Merge-based SpMV //--------------------------------------------------------------------- /** * Run CUB SpMV */ template < typename ValueT, typename OffsetT> float TestGpuMergeCsrmv( ValueT* vector_y_in, ValueT* reference_vector_y_out, SpmvParams& params, int timing_iterations) { // Allocate temporary storage size_t temp_storage_bytes = 0; void *d_temp_storage = NULL; // Get amount of temporary storage needed CubDebugExit(DeviceSpmv::CsrMV( d_temp_storage, temp_storage_bytes, params.d_values, params.d_row_end_offsets, params.d_column_indices, params.d_vector_x, params.d_vector_y, params.num_rows, params.num_cols, params.num_nonzeros, // params.alpha, params.beta, (cudaStream_t) 0, false)); // Allocate CubDebugExit(g_allocator.DeviceAllocate(&d_temp_storage, temp_storage_bytes)); // Reset input/output vector y CubDebugExit(cudaMemcpy(params.d_vector_y, vector_y_in, sizeof(ValueT) * params.num_rows, cudaMemcpyHostToDevice)); // Warmup CubDebugExit(DeviceSpmv::CsrMV( d_temp_storage, temp_storage_bytes, params.d_values, params.d_row_end_offsets, params.d_column_indices, params.d_vector_x, params.d_vector_y, params.num_rows, params.num_cols, params.num_nonzeros, // params.alpha, params.beta, (cudaStream_t) 0, !g_quiet)); if (!g_quiet) { int compare = CompareDeviceResults(reference_vector_y_out, params.d_vector_y, params.num_rows, true, g_verbose); printf("\t%s\n", compare ? "FAIL" : "PASS"); fflush(stdout); } // Timing GpuTimer timer; float elapsed_millis = 0.0; timer.Start(); for(int it = 0; it < timing_iterations; ++it) { CubDebugExit(DeviceSpmv::CsrMV( d_temp_storage, temp_storage_bytes, params.d_values, params.d_row_end_offsets, params.d_column_indices, params.d_vector_x, params.d_vector_y, params.num_rows, params.num_cols, params.num_nonzeros, // params.alpha, params.beta, (cudaStream_t) 0, false)); } timer.Stop(); elapsed_millis += timer.ElapsedMillis(); return elapsed_millis / timing_iterations; } //--------------------------------------------------------------------- // Test generation //--------------------------------------------------------------------- /** * Display perf */ template void DisplayPerf( float device_giga_bandwidth, double avg_millis, CsrMatrix& csr_matrix) { double nz_throughput, effective_bandwidth; size_t total_bytes = (csr_matrix.num_nonzeros * (sizeof(ValueT) * 2 + sizeof(OffsetT))) + (csr_matrix.num_rows) * (sizeof(OffsetT) + sizeof(ValueT)); nz_throughput = double(csr_matrix.num_nonzeros) / avg_millis / 1.0e6; effective_bandwidth = double(total_bytes) / avg_millis / 1.0e6; if (!g_quiet) printf("fp%d: %.4f avg ms, %.5f gflops, %.3lf effective GB/s (%.2f%% peak)\n", sizeof(ValueT) * 8, avg_millis, 2 * nz_throughput, effective_bandwidth, effective_bandwidth / device_giga_bandwidth * 100); else printf("%.5f, %.6f, %.3lf, %.2f%%, ", avg_millis, 2 * nz_throughput, effective_bandwidth, effective_bandwidth / device_giga_bandwidth * 100); fflush(stdout); } /** * Run tests */ template < typename ValueT, typename OffsetT> void RunTest( bool rcm_relabel, ValueT alpha, ValueT beta, CooMatrix& coo_matrix, int timing_iterations, CommandLineArgs& args) { // Adaptive timing iterations: run 16 billion nonzeros through if (timing_iterations == -1) timing_iterations = std::min(50000ull, std::max(100ull, ((16ull << 30) / coo_matrix.num_nonzeros))); if (!g_quiet) printf("\t%d timing iterations\n", timing_iterations); // Convert to CSR CsrMatrix csr_matrix; csr_matrix.FromCoo(coo_matrix); if (!args.CheckCmdLineFlag("csrmv")) coo_matrix.Clear(); // Relabel if (rcm_relabel) { if (!g_quiet) { csr_matrix.Stats().Display(); printf("\n"); csr_matrix.DisplayHistogram(); printf("\n"); if (g_verbose2) csr_matrix.Display(); printf("\n"); } RcmRelabel(csr_matrix, !g_quiet); if (!g_quiet) printf("\n"); } // Display matrix info csr_matrix.Stats().Display(!g_quiet); if (!g_quiet) { printf("\n"); csr_matrix.DisplayHistogram(); printf("\n"); if (g_verbose2) csr_matrix.Display(); printf("\n"); } fflush(stdout); // Allocate input and output vectors ValueT* vector_x = new ValueT[csr_matrix.num_cols]; ValueT* vector_y_in = new ValueT[csr_matrix.num_rows]; ValueT* vector_y_out = new ValueT[csr_matrix.num_rows]; for (int col = 0; col < csr_matrix.num_cols; ++col) vector_x[col] = 1.0; for (int row = 0; row < csr_matrix.num_rows; ++row) vector_y_in[row] = 1.0; // Compute reference answer SpmvGold(csr_matrix, vector_x, vector_y_in, vector_y_out, alpha, beta); float avg_millis; if (g_quiet) { printf("%s, %s, ", args.deviceProp.name, (sizeof(ValueT) > 4) ? "fp64" : "fp32"); fflush(stdout); } // Get GPU device bandwidth (GB/s) float device_giga_bandwidth = args.device_giga_bandwidth; // Allocate and initialize GPU problem SpmvParams params; CubDebugExit(g_allocator.DeviceAllocate((void **) ¶ms.d_values, sizeof(ValueT) * csr_matrix.num_nonzeros)); CubDebugExit(g_allocator.DeviceAllocate((void **) ¶ms.d_row_end_offsets, sizeof(OffsetT) * (csr_matrix.num_rows + 1))); CubDebugExit(g_allocator.DeviceAllocate((void **) ¶ms.d_column_indices, sizeof(OffsetT) * csr_matrix.num_nonzeros)); CubDebugExit(g_allocator.DeviceAllocate((void **) ¶ms.d_vector_x, sizeof(ValueT) * csr_matrix.num_cols)); CubDebugExit(g_allocator.DeviceAllocate((void **) ¶ms.d_vector_y, sizeof(ValueT) * csr_matrix.num_rows)); params.num_rows = csr_matrix.num_rows; params.num_cols = csr_matrix.num_cols; params.num_nonzeros = csr_matrix.num_nonzeros; params.alpha = alpha; params.beta = beta; CubDebugExit(cudaMemcpy(params.d_values, csr_matrix.values, sizeof(ValueT) * csr_matrix.num_nonzeros, cudaMemcpyHostToDevice)); CubDebugExit(cudaMemcpy(params.d_row_end_offsets, csr_matrix.row_offsets, sizeof(OffsetT) * (csr_matrix.num_rows + 1), cudaMemcpyHostToDevice)); CubDebugExit(cudaMemcpy(params.d_column_indices, csr_matrix.column_indices, sizeof(OffsetT) * csr_matrix.num_nonzeros, cudaMemcpyHostToDevice)); CubDebugExit(cudaMemcpy(params.d_vector_x, vector_x, sizeof(ValueT) * csr_matrix.num_cols, cudaMemcpyHostToDevice)); if (!g_quiet) printf("\n\n"); printf("GPU CSR I/O Prox, "); fflush(stdout); avg_millis = TestGpuCsrIoProxy(params, timing_iterations); DisplayPerf(device_giga_bandwidth, avg_millis, csr_matrix); if (args.CheckCmdLineFlag("csrmv")) { if (!g_quiet) printf("\n\n"); printf("CUB, "); fflush(stdout); avg_millis = TestGpuMergeCsrmv(vector_y_in, vector_y_out, params, timing_iterations); DisplayPerf(device_giga_bandwidth, avg_millis, csr_matrix); } // Initialize cuSparse cusparseHandle_t cusparse; AssertEquals(CUSPARSE_STATUS_SUCCESS, cusparseCreate(&cusparse)); if (args.CheckCmdLineFlag("csrmv")) { if (!g_quiet) printf("\n\n"); printf("Cusparse CsrMV, "); fflush(stdout); avg_millis = TestCusparseCsrmv(vector_y_in, vector_y_out, params, timing_iterations, cusparse); DisplayPerf(device_giga_bandwidth, avg_millis, csr_matrix); } if (args.CheckCmdLineFlag("hybmv")) { if (!g_quiet) printf("\n\n"); printf("Cusparse HybMV, "); fflush(stdout); avg_millis = TestCusparseHybmv(vector_y_in, vector_y_out, params, timing_iterations, cusparse); DisplayPerf(device_giga_bandwidth, avg_millis, csr_matrix); } // Cleanup if (params.d_values) CubDebugExit(g_allocator.DeviceFree(params.d_values)); if (params.d_row_end_offsets) CubDebugExit(g_allocator.DeviceFree(params.d_row_end_offsets)); if (params.d_column_indices) CubDebugExit(g_allocator.DeviceFree(params.d_column_indices)); if (params.d_vector_x) CubDebugExit(g_allocator.DeviceFree(params.d_vector_x)); if (params.d_vector_y) CubDebugExit(g_allocator.DeviceFree(params.d_vector_y)); if (vector_x) delete[] vector_x; if (vector_y_in) delete[] vector_y_in; if (vector_y_out) delete[] vector_y_out; } /** * Run tests */ template < typename ValueT, typename OffsetT> void RunTests( bool rcm_relabel, ValueT alpha, ValueT beta, const std::string& mtx_filename, int grid2d, int grid3d, int wheel, int dense, int timing_iterations, CommandLineArgs& args) { // Initialize matrix in COO form CooMatrix coo_matrix; if (!mtx_filename.empty()) { // Parse matrix market file printf("%s, ", mtx_filename.c_str()); fflush(stdout); coo_matrix.InitMarket(mtx_filename, 1.0, !g_quiet); if ((coo_matrix.num_rows == 1) || (coo_matrix.num_cols == 1) || (coo_matrix.num_nonzeros == 1)) { if (!g_quiet) printf("Trivial dataset\n"); exit(0); } } else if (grid2d > 0) { // Generate 2D lattice printf("grid2d_%d, ", grid2d); fflush(stdout); coo_matrix.InitGrid2d(grid2d, false); } else if (grid3d > 0) { // Generate 3D lattice printf("grid3d_%d, ", grid3d); fflush(stdout); coo_matrix.InitGrid3d(grid3d, false); } else if (wheel > 0) { // Generate wheel graph printf("wheel_%d, ", grid2d); fflush(stdout); coo_matrix.InitWheel(wheel); } else if (dense > 0) { // Generate dense graph OffsetT size = 1 << 24; // 16M nnz args.GetCmdLineArgument("size", size); OffsetT rows = size / dense; printf("dense_%d_x_%d, ", rows, dense); fflush(stdout); coo_matrix.InitDense(rows, dense); } else { fprintf(stderr, "No graph type specified.\n"); exit(1); } RunTest( rcm_relabel, alpha, beta, coo_matrix, timing_iterations, args); } /** * Main */ int main(int argc, char **argv) { // Initialize command line CommandLineArgs args(argc, argv); if (args.CheckCmdLineFlag("help")) { printf( "%s " "[--csrmv | --hybmv | --bsrmv ] " "[--device=] " "[--quiet] " "[--v] " "[--i=] " "[--fp64] " "[--rcm] " "[--alpha=] " "[--beta=] " "\n\t" "--mtx= " "\n\t" "--dense=" "\n\t" "--grid2d=" "\n\t" "--grid3d=" "\n\t" "--wheel=" "\n", argv[0]); exit(0); } bool fp64; bool rcm_relabel; std::string mtx_filename; int grid2d = -1; int grid3d = -1; int wheel = -1; int dense = -1; int timing_iterations = -1; float alpha = 1.0; float beta = 0.0; g_verbose = args.CheckCmdLineFlag("v"); g_verbose2 = args.CheckCmdLineFlag("v2"); g_quiet = args.CheckCmdLineFlag("quiet"); fp64 = args.CheckCmdLineFlag("fp64"); rcm_relabel = args.CheckCmdLineFlag("rcm"); args.GetCmdLineArgument("i", timing_iterations); args.GetCmdLineArgument("mtx", mtx_filename); args.GetCmdLineArgument("grid2d", grid2d); args.GetCmdLineArgument("grid3d", grid3d); args.GetCmdLineArgument("wheel", wheel); args.GetCmdLineArgument("dense", dense); args.GetCmdLineArgument("alpha", alpha); args.GetCmdLineArgument("beta", beta); // Initialize device CubDebugExit(args.DeviceInit()); // Run test(s) if (fp64) { RunTests(rcm_relabel, alpha, beta, mtx_filename, grid2d, grid3d, wheel, dense, timing_iterations, args); } else { RunTests(rcm_relabel, alpha, beta, mtx_filename, grid2d, grid3d, wheel, dense, timing_iterations, args); } CubDebugExit(cudaDeviceSynchronize()); printf("\n"); return 0; }