Alien-XGBoost
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xgboost/cub/experimental/spmv_compare.cu view on Meta::CPAN
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<LOAD_LDG>(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<LOAD_DEFAULT>(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<ValueT, OffsetT>& 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<ValueT, 1234, int> 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<ValueT, OffsetT>, TexItr) = NonZeroIoKernel<BLOCK_THREADS, ITEMS_PER_THREAD>;
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<BLOCK_THREADS, ITEMS_PER_THREAD><<<blocks, BLOCK_THREADS, smem>>>(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<BLOCK_THREADS, ITEMS_PER_THREAD><<<blocks, BLOCK_THREADS, smem>>>(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<float, OffsetT>& 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<double, OffsetT>& 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<float, OffsetT>& 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<double, OffsetT>& 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<ValueT, OffsetT>& 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 <typename ValueT, typename OffsetT>
void DisplayPerf(
float device_giga_bandwidth,
double avg_millis,
CsrMatrix<ValueT, OffsetT>& 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<ValueT, OffsetT>& 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<ValueT, OffsetT> 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<ValueT, OffsetT> 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<ValueT, OffsetT> 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=<device-id>] "
"[--quiet] "
"[--v] "
"[--i=<timing iterations>] "
"[--fp64] "
"[--rcm] "
"[--alpha=<alpha scalar (default: 1.0)>] "
"[--beta=<beta scalar (default: 0.0)>] "
"\n\t"
"--mtx=<matrix market file> "
"\n\t"
"--dense=<cols>"
"\n\t"
"--grid2d=<width>"
"\n\t"
"--grid3d=<width>"
"\n\t"
"--wheel=<spokes>"
"\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<double, int>(rcm_relabel, alpha, beta, mtx_filename, grid2d, grid3d, wheel, dense, timing_iterations, args);
}
else
{
RunTests<float, int>(rcm_relabel, alpha, beta, mtx_filename, grid2d, grid3d, wheel, dense, timing_iterations, args);
}
CubDebugExit(cudaDeviceSynchronize());
printf("\n");
return 0;
}
( run in 0.457 second using v1.01-cache-2.11-cpan-71847e10f99 )